https://nicolas-barbot.ovh/wiki/api.php?action=feedcontributions&feedformat=atom&user=NicoNicolas Barbot website - User contributions [en]2026-05-01T19:56:16ZUser contributionsMediaWiki 1.36.0https://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=578List of Publications2026-04-30T10:52:37Z<p>Nico: </p>
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==Journal Articles==<br />
*N. Barbot, J. Tuominen, A. Paukkunen, J. Grosinger and P. Nikitin, "Remote Antenna Impedance Estimation Using a UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, Early Access, presented at IEEE RFID 2026 conference.<br />
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*M. Yang and N. Barbot, "A Calibrated IQ Backscatter Modulator and Associated Receiver," in IEEE Journal of Radio Frequency Identification, vol. 10, pp. 208-215, 2026.<br />
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*N. Barbot and M. Reynolds, "A General Receiver for Backscatter Signals: A Step-by-Step Tutorial," in IEEE Microwave Magazine, vol. 27, no. 2, pp. 62-74, Feb. 2026.<br />
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*N. Barbot, I. Prodan and P. Nikitin, "Differential RCS of Multi-Port Tag Antenna With Synchronous Modulated Backscatter," in IEEE Journal of Radio Frequency Identification, vol. 9, pp. 126-134, 2025.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Real-Time Hand Motion-Modulated Chipless RFID With Gesture Recognition Capability," in IEEE Transactions on Microwave Theory and Techniques, vol. 73, no. 1, pp. 383-396, Jan. 2025<br />
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*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, vol. 8, pp. 145-153, 2024.<br />
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*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop". Scientific Report 12, 22032 (2022).<br />
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*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
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*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
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*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023. '''IEEE CRFID James Clerk Maxwell Best Journal Paper Award 2024'''<br />
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*F. Requena, S. Ahoulou, N. Barbot, D. Kaddour, J.-M. Nedelec, T. Baron and E. Perret "Towards Wireless Detection of Surface Modification of Silicon Nanowires by an RF Approach," Nanomaterials, 12(23), 4237, 2022 <br />
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*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
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*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
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*O. Rance, N. Barbot and E. Perret, "Comments on “Development of Cross-Polar Orientation-Insensitive Chipless RFID Tags”," in IEEE Transactions on Antennas and Propagation, vol. 70, no. 5, pp. 3922-3923, May 2022.<br />
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*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
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*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” in IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022. <br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
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*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
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*F.Bonnefoy, M. Bernier, E. Perret, N. Barbot, R. Siragusa, D. Hely, E. Kato, F. Garet "Video-Rate Identification of High-Capacity Low-Cost Tags in the Terahertz Domain," Sensors, 21(11):3692 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
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*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021. doi: 10.1109/TAP.2021.3060126.<br />
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*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
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*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim Jr., N. Barbot, R. Siragusa, E. Perret and F. Popescu "A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches," Sensors. 20(21):6385, 2020.<br />
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*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
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*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
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*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
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*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
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*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
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*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
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*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
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*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
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*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
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*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
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*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
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*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
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*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
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*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
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*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
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==International Conferences==<br />
*N. Barbot and I. Prodan, "UHF RFID Chip Parameter Optimization," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-4.<br />
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*M. Yang and N. Barbot, "A Calibrated IQ Backscatter Modulator," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-5.<br />
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*M. Yang and N. Barbot, "Motion-Modulated Intermodulation Sensors," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-5.<br />
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*A. Gaffet, Q. Liu, M. Defoort and N. Barbot, "13.56 MHz NFC HF Full Passive and Analog Tag with a Chaotic Duffing Resonator to Achieve Secured Authentication," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-7.<br />
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*S. Hemour, P. Reuvers, M. Simons and N. Barbot, "Who Invented the Non Linear Junction Detector?," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-7.<br />
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*X. Gu, T. Micallef, N. Barbot, K. Wu and S. Hemour, "Leveraging Nonlinearity for Joint RF Power Harvesting, Sensing and Communications," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-4.<br />
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*N. Barbot, A. Vena and M. Reynolds, "Performance Comparison of Backscatter Receivers," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-5.<br />
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*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
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*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
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*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
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*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
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*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
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*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
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*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
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*N. Barbot and V. C. V, "Open Testing and Measurement Bench for UHF RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 158-161.<br />
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*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
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*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
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*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
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*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
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*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
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*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF RFID tags: HRFID project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
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*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
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*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
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*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
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*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
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*Z. Ali, N. Barbot and E. Perret, "Gesture Recognition Using Chipless RFID Tag Held in Hand," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 40-43.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Vibration Sensing using Doppler-modulated Chipless RFID Tags," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 129-132.<br />
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*N. Barbot and S. Tedjini, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
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*N. Barbot, D. Allane and S. Tedjini, “Orientation Sensor Based on Harmonic Transponder,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
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*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''.<br />
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*O. Rance, N. Barbot and E. Perret, "Comparison between Cross-polarization and Circular Polarization Interrogation for Robust Chipless RFID Reading," 2021 51st European Microwave Conference (EuMC), London, United Kingdom, 2022, pp. 668-671.<br />
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*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
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*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''.<br />
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*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
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*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
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*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
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*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
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*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
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*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
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*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
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*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
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*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
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*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
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*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
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*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
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*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
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*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
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*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
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*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
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*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
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*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
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*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
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*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
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*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
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*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
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*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
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*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
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*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
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*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
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==National Conferences==<br />
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*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
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*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
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*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
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*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
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*O. Rance, Z. Ali, N. Barbot, E. Perret, "Diffuseur dépolarisant invariant par rotation", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*N. Barbot and E. Perret, "Capteur chipless basé sur la modulation de polarisation", Limoges, France, Jun. 2022.<br />
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*N. Barbot and E. Perret, "Distance de lecture en technologie RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*N. Barbot, O. Rance, and E. Perret, "RCS différentiel de tags modulés", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, "Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Capteur RFID sans puce de température et d’humidité", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
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*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
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*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
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*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
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*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=577List of Publications2026-04-30T10:11:40Z<p>Nico: </p>
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==Journal Articles==<br />
*N. Barbot, J. Tuominen, A. Paukkunen, J. Grosinger and P. Nikitin, "Remote Antenna Impedance Estimation Using a UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, Early Access, presented at IEEE RFID 2026 conference in Santa Fe<br />
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*M. Yang and N. Barbot, "A Calibrated IQ Backscatter Modulator and Associated Receiver," in IEEE Journal of Radio Frequency Identification, vol. 10, pp. 208-215, 2026.<br />
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*N. Barbot and M. Reynolds, "A General Receiver for Backscatter Signals: A Step-by-Step Tutorial," in IEEE Microwave Magazine, vol. 27, no. 2, pp. 62-74, Feb. 2026.<br />
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*N. Barbot, I. Prodan and P. Nikitin, "Differential RCS of Multi-Port Tag Antenna With Synchronous Modulated Backscatter," in IEEE Journal of Radio Frequency Identification, vol. 9, pp. 126-134, 2025.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Real-Time Hand Motion-Modulated Chipless RFID With Gesture Recognition Capability," in IEEE Transactions on Microwave Theory and Techniques, vol. 73, no. 1, pp. 383-396, Jan. 2025<br />
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*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, vol. 8, pp. 145-153, 2024.<br />
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*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop". Scientific Report 12, 22032 (2022).<br />
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*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
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*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
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*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023. '''IEEE CRFID James Clerk Maxwell Best Journal Paper Award 2024'''<br />
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*F. Requena, S. Ahoulou, N. Barbot, D. Kaddour, J.-M. Nedelec, T. Baron and E. Perret "Towards Wireless Detection of Surface Modification of Silicon Nanowires by an RF Approach," Nanomaterials, 12(23), 4237, 2022 <br />
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*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
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*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
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*O. Rance, N. Barbot and E. Perret, "Comments on “Development of Cross-Polar Orientation-Insensitive Chipless RFID Tags”," in IEEE Transactions on Antennas and Propagation, vol. 70, no. 5, pp. 3922-3923, May 2022.<br />
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*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
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*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” in IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022. <br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
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*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
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*F.Bonnefoy, M. Bernier, E. Perret, N. Barbot, R. Siragusa, D. Hely, E. Kato, F. Garet "Video-Rate Identification of High-Capacity Low-Cost Tags in the Terahertz Domain," Sensors, 21(11):3692 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
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*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021. doi: 10.1109/TAP.2021.3060126.<br />
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*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
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*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim Jr., N. Barbot, R. Siragusa, E. Perret and F. Popescu "A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches," Sensors. 20(21):6385, 2020.<br />
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*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
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*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
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*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
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*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
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*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
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*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
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*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
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*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
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*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
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*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
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*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
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*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
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*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
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*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
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*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
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==International Conferences==<br />
*N. Barbot and I. Prodan, "UHF RFID Chip Parameter Optimization," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-4.<br />
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*M. Yang and N. Barbot, "A Calibrated IQ Backscatter Modulator," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-5.<br />
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*M. Yang and N. Barbot, "Motion-Modulated Intermodulation Sensors," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-5.<br />
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*A. Gaffet, Q. Liu, M. Defoort and N. Barbot, "13.56 MHz NFC HF Full Passive and Analog Tag with a Chaotic Duffing Resonator to Achieve Secured Authentication," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-7.<br />
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*S. Hemour, P. Reuvers, M. Simons and N. Barbot, "Who Invented the Non Linear Junction Detector?," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-7.<br />
<br />
*X. Gu, T. Micallef, N. Barbot, K. Wu and S. Hemour, "Leveraging Nonlinearity for Joint RF Power Harvesting, Sensing and Communications," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-4.<br />
<br />
*N. Barbot, A. Vena and M. Reynolds, "Performance Comparison of Backscatter Receivers," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-5.<br />
<br />
*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
<br />
*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
<br />
*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
<br />
*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
<br />
*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
<br />
*N. Barbot and V. C. V, "Open Testing and Measurement Bench for UHF RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 158-161.<br />
<br />
*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
<br />
*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
<br />
*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
<br />
*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF RFID tags: HRFID project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
<br />
*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
<br />
*Z. Ali, N. Barbot and E. Perret, "Gesture Recognition Using Chipless RFID Tag Held in Hand," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 40-43.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Vibration Sensing using Doppler-modulated Chipless RFID Tags," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 129-132.<br />
<br />
*N. Barbot and S. Tedjini, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, D. Allane and S. Tedjini, “Orientation Sensor Based on Harmonic Transponder,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comparison between Cross-polarization and Circular Polarization Interrogation for Robust Chipless RFID Reading," 2021 51st European Microwave Conference (EuMC), London, United Kingdom, 2022, pp. 668-671.<br />
<br />
*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
<br />
*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
<br />
*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
<br />
*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
<br />
*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
<br />
*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
<br />
*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
<br />
*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
<br />
*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
<br />
*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
<br />
*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
<br />
*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
<br />
*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
<br />
==National Conferences==<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
<br />
*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
<br />
*O. Rance, Z. Ali, N. Barbot, E. Perret, "Diffuseur dépolarisant invariant par rotation", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Capteur chipless basé sur la modulation de polarisation", Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Distance de lecture en technologie RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, "RCS différentiel de tags modulés", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, "Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Capteur RFID sans puce de température et d’humidité", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
<br />
*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
<br />
*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=576List of Publications2026-03-30T14:45:51Z<p>Nico: </p>
<hr />
<div>__FORCETOC__<br />
<br />
==Journal Articles==<br />
*M. Yang and N. Barbot, "A Calibrated IQ Backscatter Modulator and Associated Receiver," in IEEE Journal of Radio Frequency Identification, vol. 10, pp. 208-215, 2026.<br />
<br />
*N. Barbot and M. Reynolds, "A General Receiver for Backscatter Signals: A Step-by-Step Tutorial," in IEEE Microwave Magazine, vol. 27, no. 2, pp. 62-74, Feb. 2026.<br />
<br />
*N. Barbot, I. Prodan and P. Nikitin, "Differential RCS of Multi-Port Tag Antenna With Synchronous Modulated Backscatter," in IEEE Journal of Radio Frequency Identification, vol. 9, pp. 126-134, 2025.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Real-Time Hand Motion-Modulated Chipless RFID With Gesture Recognition Capability," in IEEE Transactions on Microwave Theory and Techniques, vol. 73, no. 1, pp. 383-396, Jan. 2025<br />
<br />
*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, vol. 8, pp. 145-153, 2024.<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop". Scientific Report 12, 22032 (2022).<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
<br />
*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023. '''IEEE CRFID James Clerk Maxwell Best Journal Paper Award 2024'''<br />
<br />
*F. Requena, S. Ahoulou, N. Barbot, D. Kaddour, J.-M. Nedelec, T. Baron and E. Perret "Towards Wireless Detection of Surface Modification of Silicon Nanowires by an RF Approach," Nanomaterials, 12(23), 4237, 2022 <br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
<br />
*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comments on “Development of Cross-Polar Orientation-Insensitive Chipless RFID Tags”," in IEEE Transactions on Antennas and Propagation, vol. 70, no. 5, pp. 3922-3923, May 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
<br />
*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” in IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022. <br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
<br />
*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
<br />
*F.Bonnefoy, M. Bernier, E. Perret, N. Barbot, R. Siragusa, D. Hely, E. Kato, F. Garet "Video-Rate Identification of High-Capacity Low-Cost Tags in the Terahertz Domain," Sensors, 21(11):3692 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021. doi: 10.1109/TAP.2021.3060126.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
<br />
*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim Jr., N. Barbot, R. Siragusa, E. Perret and F. Popescu "A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches," Sensors. 20(21):6385, 2020.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
<br />
*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
<br />
*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
<br />
*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
<br />
*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
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==International Conferences==<br />
*N. Barbot and I. Prodan, "UHF RFID Chip Parameter Optimization," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-4.<br />
<br />
*M. Yang and N. Barbot, "A Calibrated IQ Backscatter Modulator," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-5.<br />
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*M. Yang and N. Barbot, "Motion-Modulated Intermodulation Sensors," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-5.<br />
<br />
*A. Gaffet, Q. Liu, M. Defoort and N. Barbot, "13.56 MHz NFC HF Full Passive and Analog Tag with a Chaotic Duffing Resonator to Achieve Secured Authentication," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-7.<br />
<br />
*S. Hemour, P. Reuvers, M. Simons and N. Barbot, "Who Invented the Non Linear Junction Detector?," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-7.<br />
<br />
*X. Gu, T. Micallef, N. Barbot, K. Wu and S. Hemour, "Leveraging Nonlinearity for Joint RF Power Harvesting, Sensing and Communications," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-4.<br />
<br />
*N. Barbot, A. Vena and M. Reynolds, "Performance Comparison of Backscatter Receivers," 2025 IEEE International Conference on RFID Technology and Applications (RFID-TA), Valence, France, 2025, pp. 1-5.<br />
<br />
*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
<br />
*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
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*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
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*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
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*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
<br />
*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
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*N. Barbot and V. C. V, "Open Testing and Measurement Bench for UHF RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 158-161.<br />
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*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
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*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
<br />
*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
<br />
*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
<br />
*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF RFID tags: HRFID project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
<br />
*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
<br />
*Z. Ali, N. Barbot and E. Perret, "Gesture Recognition Using Chipless RFID Tag Held in Hand," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 40-43.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Vibration Sensing using Doppler-modulated Chipless RFID Tags," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 129-132.<br />
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*N. Barbot and S. Tedjini, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, D. Allane and S. Tedjini, “Orientation Sensor Based on Harmonic Transponder,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comparison between Cross-polarization and Circular Polarization Interrogation for Robust Chipless RFID Reading," 2021 51st European Microwave Conference (EuMC), London, United Kingdom, 2022, pp. 668-671.<br />
<br />
*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
<br />
*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
<br />
*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
<br />
*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
<br />
*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
<br />
*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
<br />
*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
<br />
*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
<br />
*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
<br />
*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
<br />
*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
<br />
*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
<br />
*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
<br />
==National Conferences==<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
<br />
*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
<br />
*O. Rance, Z. Ali, N. Barbot, E. Perret, "Diffuseur dépolarisant invariant par rotation", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Capteur chipless basé sur la modulation de polarisation", Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Distance de lecture en technologie RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, "RCS différentiel de tags modulés", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, "Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Capteur RFID sans puce de température et d’humidité", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
<br />
*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
<br />
*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Research_Activities&diff=575Research Activities2026-03-25T21:38:37Z<p>Nico: </p>
<hr />
<div>My research interests include passive (or semi-passive) transponders which can not be modeled as linear time-invariant systems. These transponders have enhanced performance in term of coding capacity and read range compared to classical linear time-invariant systems. These results and can only be achieved by breaking the linearity or the time invariance associated to the transponder.<br />
<br />
<br />
== Introduction ==<br />
<br />
[[File:Color.gif|thumb|right|Fig. 1: Environment under white light]]<br />
<br />
[[File:Color_red.gif|thumb|right|Fig. 2: Environment under red light]]<br />
<br />
Almost all the objects that we can see or characterize are Linear Time Invariant (LTI) systems. It implies that if they are impinged by an electromagnetic wave at a frequency <math>f_0</math> (in input), they also reflect or backscatter an electromagnetic wave at the same frequency <math>f_0</math> (in output).<br />
<br />
These LTI systems can be fully characterized by their impulse response <math>h(t)</math> in the time domain or their transfer function <math>H(f)</math> in the frequency domain. The output signal <math>y(t)</math> can be obtained in the time domain if the input signal <math>x(t)</math> is known as:<br />
<br />
<math><br />
y(t) = x(t) * h(t)<br />
</math><br />
<br />
Expression can equivalently be derived in the frequency domain:<br />
<br />
<math><br />
Y(f) = X(f) \times H(f)<br />
</math><br />
<br />
Classical examples include dynamical systems (electrical circuits, mechanical systems...). <br />
If we consider that the incident waveform is a continuous wave of frequency <math>f_0</math> then its real signal can be expressed as <math>x(t) = \cos 2 \pi f_0 t</math>. The received signal takes in that case, the simple form:<br />
<br />
<math><br />
y(t) = |H(f_0)| \cos (2 \pi f_0 t + Arg(H(f_0)))<br />
</math><br />
<br />
where we can easily see that the backscattered signal of a LTI system can only affect the amplitude <math>|H(f_0)|</math> and/or the phase <math>Arg(H(f_0))</math> of the incident waveform. Note that all the received power is also located at <math>f_0</math> since a LTI system can not generate a frequency which is not in the input signal.<br />
<br />
Let's consider a simple example, where an environment composed of different pens on a white support is illuminated by white light as in Fig. 1. Under these conditions, note that each object is characterized by a different color since they all accept the incident power and they each reflect a tiny part of the input spectrum. However, if we replace the white light by a red light (or any monochromatic color), each object will reflect the CW with an attenuation <math>|H(f_0)|</math> and a phase shift of <math>Arg(H(f_0))</math> but the frequency of the reflected wave will remain at <math>f_0</math> and the color of all object lies in between red (when attenuation is low) and black (when attenuation is high). Results are presented in Fig. 2. Almost all the objects that we see around us (like these pens and this support) are LTI systems.<br />
<br />
This simple observation implies important constraints if we want to identify any LTI object according the their backscattered or reflected signal:<br />
# The coding capacity only depends on the number of the color which can be distinguished. This capacity is only a function of the frequency resolution compared to the total bandwidth used by the reader. The total bandwidth used by the reader depends on the input signal. That is why we can differentiate pen under white light and not under red light.<br />
# The associated read range is only limited by the ratio in between the power backscattered by the object compared to the power reflected by the environment at the same frequency. This condition is harder to see with the picture since, pens can be separated spatially due to the camera lens but remember that an antenna cannot detect the direction of arrival of the received power.<br />
These limitation only appear since both pens and support (white table) are LTI systems and impose strict constraint in term of coding capacity and read range for any system based on LTI transponders.<br />
<br />
== Research Interest ==<br />
<br />
My research interests include all systems which cannot be modeled by a linear time-invariant system. As a direct consequence, these systems cannot be described by an impulse response or a transfer function<br />
and are able to accept the incident power at a given frequency and reflect or backscatter (a part of) this power at an other frequency or in another bandwidth. For example, in Fig. 2, these systems could appear under the red illumination as blue of green objects...<br />
This result can be obtained by only 2 ways, breaking the linearity (i.e., non linear systems) or breaking the time invariance (i.e. linear time variant systems). A third method consist of breaking the invariance on the reader side.<br />
<br />
Note also that breaking the time-invariance with a scatterer has been investigated since 1948 by H. Stockman, <ref>"Communication by Means of Reflected Power," in Proceedings of the IRE, vol. 36, no. 10, pp. 1196-1204, Oct. 1948, doi: 10.1109/JRPROC.1948.226245</ref> and can be obtained, citing the author, by "variable-damping modulation, interference or phase modulation, directional modulation, position modulation, doppler modulation, and polarization modulation". The first case is actually, the operation principle of a UHF RFID tag. Doppler and polarization modulation are described hereafter.<br />
<br />
=== Linear time variant systems ===<br />
<br />
[[File:line_coding.png|300px|thumb|right|Fig. 4: PSD of the signal backscattered by a modulating tag.]]<br />
<br />
These class of transponders include many examples. The more famous ones are classical RFID tags. UHF RFID tags can, when a sufficient power is received by the chip, switch the internal load connected to the antenna in between 2 values, its RCS is also modified and becomes a function of the time. Finally the variations of the backscattered signal generate a modulation which can be detected by the reader. As a direct consequence, the backscattered power spectral density includes components which are not at <math>f_0</math>. If the transmission data rate is much lower than the carrier frequency, narrow band signal approximation holds and PSD is located around <math>f_0</math>. The exact characteristics of the PSD depends on the data encoding used by the tag during the communication. The UHF RFID standard defines two different modulations for the tag which are FM0 and Miller (with different subcarrier sequences). Analytical formula of the PSD for FM0 is known and is equal to the Manchester encoding. For Miller modulation, analytical formula is also known, but without considering the subcarrier sequences. Fig. 5 presents the PSD of the baseband signals corresponding to the different modulations used by the tag. For all modulation we can see that the PSD is spread around <math>f_0</math> and that the system can not be considered as a LTI system.<br />
<br />
<br />
Another example appears when objects are moved or rotated into space. This interesting phenomenon is better illustrated by considering the simple case where a target is impinged by a continuous wave at a frequency <math>f_0</math>, if the radial speed of the target compared to the antenna is not zero, Doppler effect actually modifies the backscattered wave frequency received by the antenna which can be expressed as:<br />
<br />
<math> <br />
f=\left(\frac {c}{c\pm v_s}\right)f_0<br />
</math><br />
<br />
[[File:stem.png|thumb|right|Fig. 5: Spectrum of a rotating dipole impinged by a CW.]]<br />
<br />
Periodical movements of frequency <math>f_r</math>, such as vibrations and rotations, lead to simple analytical expressions where the backscattered spectrum is composed of discrete peaks located at <math>f_0 \pm n f_r</math> <ref> A. Azarfar, N. Barbot, and E. Perret. "Towards chipless RFID technology based on micro-Doppler effect for long range applications." In 2021 IEEE MTT-SInternational Microwave Symposium (IMS), Jun. 2021 Atlanta, GA</ref>. Let's consider a vertical dipole oriented along <math>z</math> located at <math>x=5</math> cm and <math>y=0</math> cm and impinged by a plane wave at 915 MHz propagating along <math>y</math>. If we rotate this dipole along the <math>z</math> axis with a frequency <math>f_r</math>, the phase backscattered electric field in farfield is modulated by a sinus function while the magnitude remains constant (micro-Doppler). This situation can surprisingly easily be simulated in time domain using a frequency solver such as <syntaxhighlight lang="text" inline>nec2</syntaxhighlight>.<br />
<br />
<syntaxhighlight lang="text" line='line' highlight="3"><br />
CE MICRO-DOPPLER<br />
GW 0 50 -0.0165 0.05 0. 0.0165 0.05 0. 0.0005<br />
GM 0 0 0. 0. 0. 0. 0. 0.<br />
GE<br />
EX 1 1 1 0 0 0 0 0 0 0<br />
FR 0 1 0 0 915e6 0<br />
RP 0 1 1 1000 0 0 0 0 1<br />
EN<br />
</syntaxhighlight><br />
<br />
Since at any given time, the system can be assumed as a linear time invariant system, the excitation of the structure by a CW can be fully described by simply determining the received amplitude and phase.<br />
Thus, the received response during the rotation can be estimated by determining the variation of amplitude and phase scattered by the structure, for each angle <math>\theta</math> of the scatterer. The variation of the amplitude and phase also correspond to the variations of the received signal the time domain signal. Thus by changing the <syntaxhighlight lang="text" inline>GM</syntaxhighlight> card, the backscattered signal can be determined for all <math>\theta</math> values. Fourier series of this signal can be computed and lead to a discrete spectrum at <math> k f_r</math> presented in Fig. 4. Analytical form is identical to a frequency modulated signal with an index modulation of <math>\beta = 1.92</math> and can be expressed as a function of the Bessel function of first kind.<br />
<br />
Another example, can be based on the polarization modulation by changing the orientation of the scatterer as a function of time <ref>N. Barbot and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/nl.pdf "Linear time-variant chipless RFID sensor,"] IEEE Journal of Radio Frequency Identification, early access.</ref>. Note that this modulation can only create power at <math>f_0</math> and <math>f_0 \pm f_r</math> which is very different compared to the Doppler modulation. Results can be accurately predicted using the variation polarization scattering matrix as the function of time.<br />
<br />
Finally, note that for every modification of the response of the transponder during the interrogation done by the reader implies a modulation of the backscattered signal in time which generates a non-zero power in the PSD around <math>f_0</math>. However these modifications require an energy source which can be brought by the reader itself (as in UHF RFID) or by an external action (as the displacement or rotation of the tag). In these latter case, transponders can be considered as semi-passive.<br />
<br />
=== Imaging systems ===<br />
<br />
[[File:Myean13.png|thumb|right|Fig. 6: Barcode and modulated reflected signal]]<br />
<br />
Imaging systems are a special kind of linear time variant system where the variations are not produced by the tag but by the reader itself. In this case, the tag remains a LTI systems, but the reading method done by the reader allows to extract the tag response as a function of variation in time which break the invariance propertie. These tags (and the associated reading method) are not limited by the bounds on coding capacity and read range. The simplest example is the barcode and is presented in Fig. 5. Classical barcodes are composed of black stripes and can encode 43 bits of information. Barcodes are read by sweeping the beam produced by a laser diode along the tag and by measuring the variations of the reflected signal in time. Scientists often usually consider that chipless technology is more related to barcodes than UHF technology, however, note that the reflected signal of a barcode is a modulated signal which is, by principle, identical to the backscattered signals of UHF RFID and moving or rotating tags. As such, barcodes and their reading method cannot be considered as LTI systems and are characterized by a non-zero delta RCS and a (possible) much larger read range.<br />
<br />
This spatial diversity allows to use the same color multiple time to encode information (stripes do not have to use a different color and 2 colors are enought) which significantly increases the coding capacity. <br />
2D images and their associated reading method can also be considered as linear time variant systems (which include QR code, or any image obtained with a lens and camera sensor). All these systems operate in the optical domain since spatial resolution is only limited by the small beam divergence of laser diodes (less than 1 mrad) or the sensor matrix size of camera sensors. However, note that when frequency is decreased, antenna directivity is also reduced which significantly limits the performance of this approach in the RF domain. For example in UWB band half power angle is usually higher than 10° which imposes large separation in between stripes (or resonators).<br />
<br />
=== Non linear systems ===<br />
<br />
Transponders based on a non-linear element (such as a Schottky diode) can accept a power at <math>f_0</math> and generate a power at <math>n f_0</math>. Let's consider the simple circuit composed of a generator connected to a load but where a diode in inserted in serial in the circuit. The diode is a simple device which conducts the current mainly in a single direction. The relation which describe the current <math>I</math> flowing through the diode as a function of the voltage across the junction <math>V_D</math> can be expressed as:<br />
<br />
<math><br />
I=I_S\left(e^{\frac {V_D}{nV_T}}-1\right)<br />
</math><br />
<br />
with <math>V_T = kT/q</math>. If we consider a small variation of the junction voltage <math>v</math> around a bias voltage operating point <math>V_b</math>, the current <math>i</math> can be expressed as Taylor series:<br />
<br />
<math><br />
i(v) = i(V_b) + \frac{i^{(1)}}{1!} (v-V_b) + \frac{i^{(2)}(V_b)}{2!} (v-V_D)^2 + \frac{i^{(3)}(V_b)}{3!} (v-V_b)^3+\cdots<br />
</math><br />
<br />
where <math>i^{(n)}</math> is the <math>n^{\text{th}}</math>-derivative of <math>i(v)</math> according to <math>v</math>.<br />
<br />
If an harmonic tension such as <math>v(t)=A\cos \omega_0 t</math> is applied to this diode, its current <math>i(t)</math><br />
can be expressed as:<br />
<br />
<math><br />
\begin{align}<br />
i(V_D,t) &= i(V_D) + [\frac{A^2}{4} i^{(2)}(V_b) + \frac{A^4}{64}i^{(4)}(V_b)+\cdots]\\<br />
&+ [A i^{(1)}(V_D) + \frac{A^3}{8} i^{(3)}(V_b) + \cdots] \cos \omega_0 t\\<br />
&+ [\frac{A^2}{4} i^{(2)}(V_b) + \frac{A^4}{48}i^{(4)}(V_b)+\cdots] \cos 2\omega_0 t\\<br />
&+ [\frac{A^3}{24} i^{(3)}(V_b) + \frac{A^5}{384}i^{(4)}(V_b)+\cdots] \cos 3\omega_0 t\\<br />
&+ \cdots<br />
\end{align}<br />
</math><br />
<br />
where we can see that an infinite sum of harmonics has been created due the non-linear behavior of the diode.<br />
<!-- Note also, that each term can be viewed as coefficient of Fourier series of the decomposition <math>i(V_d, t)</math>. --><br />
<br />
<!-- [[File:Vtime.png|300px|thumb|right|Voltage across R in the time domain]] --><br />
<br />
[[File:Vfrequency.png|300px|thumb|right|Fig. 3: Voltage across R in the frequency domain]]<br />
<br />
This circuit can easily be simulated using <syntaxhighlight lang="text" inline>ngspice</syntaxhighlight> using the transient analysis to clearly see the effect of the non-linearity of a HSMS285x diode.<br />
Amplitude has been set to 1V, frequency at 915 MHz. Simulation has been computed over a duration of 10 periods with 100 samples per period. Fourier series have been computed over the voltage across the load.<br />
<br />
<syntaxhighlight lang="text" line="line"><br />
.title diode<br />
.param A = 1<br />
.param f0 = 915e6<br />
.model hsms285x D (IS=3e-6 RS=25 N=1.06 CJO=0.18pF VJ=0.35 M=0.5 EG=0.69 XTI=2 BV=3.8 IBV=3e-4)<br />
V1 1 0 dc 0 SIN(0 A f0 0NS 0)<br />
Ra 2 1 50<br />
D1 2 3 hsms285x<br />
Rl 3 0 50<br />
.end<br />
<br />
.csparam csf0 = {f0}<br />
.csparam duration = {10.0/f0}<br />
.csparam fsample = {1/(100*f0)}<br />
.control<br />
tran $&fsample $&duration<br />
plot v(3)<br />
fourier $&csf0 v(3)<br />
.endc<br />
</syntaxhighlight><br />
<br />
The simulation clearly shows that the power dissipated into the load contains power at <math>f_0</math> but also at <math>n f_0</math> due to the non-linear behavior of the diode.<br />
Harvesters use the power located at <math>n=0</math> where as harmonic transponders are based on the power located at <math>n > 1</math>.<br />
<br />
For passive harmonic transponders, an antenna accepting the power at <math>f_0</math> have to be added. The backscattered power at <math>n f_0</math> should also be re-radiated by another antenna.<br />
The main difficulty appears from the incident power which is very low (few micro Watt) which need to generate a voltage higher than the threshold of the diode (around 0.3 V). Usually the conversion loss associated to these devices is lower than -20 dB (i.e. only 1% of the incident power is converted to an harmonic frequency). However, read range of these transponders can easily achieve more than 5 m while satisfying regulation standards.<br />
<br />
----<br />
<br />
Finally, all presented systems (time-varing and non-linear transponders) can also be characterized by a non-zero differential RCS (or delta RCS) <math>\sigma_d</math> since they are able to modulate their backscattered power. This delta RCS is the direct generalization of the quantity classically defined for UHF tags. More information can be found [[Differential RCS|here]].<br />
<br />
== Conclusion ==<br />
<br />
I hope you have liked this page. If you have any comment, remarks or questions about these ideas, feel free to send me an email:<br />
<br />
[mailto:nicolas.barbot@lcis.grenoble-inp.fr <syntaxhighlight lang="text" inline>nicolas.barbot@lcis.grenoble-inp.fr</syntaxhighlight>]<br />
<br />
Collaborations often start by simple emails...<br />
<br />
==References==<br />
<br />
<references /></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Research_Activities&diff=574Research Activities2026-03-25T21:37:24Z<p>Nico: </p>
<hr />
<div>My research interests include passive (or semi-passive) transponders which can not be modeled as linear time-invariant systems. These transponders have enhanced performance in term of coding capacity and read range compared to classical linear time-invariant systems. These results and can only be achieved by breaking the linearity or the time invariance associated to the transponder.<br />
<br />
<br />
== Introduction ==<br />
<br />
[[File:Color.gif|thumb|right|Fig. 1: Environment under white light]]<br />
<br />
[[File:Color_red.gif|thumb|right|Fig. 2: Environment under red light]]<br />
<br />
Almost all the objects that we can see or characterize are Linear Time Invariant (LTI) systems. It implies that if they are impinged by an electromagnetic wave at a frequency <math>f_0</math> (in input), they also reflect or backscatter an electromagnetic wave at the same frequency <math>f_0</math> (in output).<br />
<br />
These LTI systems can be fully characterized by their impulse response <math>h(t)</math> in the time domain or their transfer function <math>H(f)</math> in the frequency domain. The output signal <math>y(t)</math> can be obtained in the time domain if the input signal <math>x(t)</math> is known as:<br />
<br />
<math><br />
y(t) = x(t) * h(t)<br />
</math><br />
<br />
Expression can equivalently be derived in the frequency domain:<br />
<br />
<math><br />
Y(f) = X(f) \times H(f)<br />
</math><br />
<br />
Classical examples include dynamical systems (electrical circuits, mechanical systems...). <br />
If we consider that the incident waveform is a continuous wave of frequency <math>f_0</math> then its real signal can be expressed as <math>x(t) = \cos 2 \pi f_0 t</math>. The received signal takes in that case, the simple form:<br />
<br />
<math><br />
y(t) = |H(f_0)| \cos (2 \pi f_0 t + Arg(H(f_0)))<br />
</math><br />
<br />
where we can easily see that the backscattered signal of a LTI system can only affect the amplitude <math>|H(f_0)|</math> and/or the phase <math>Arg(H(f_0))</math> of the incident waveform. Note that all the received power is also located at <math>f_0</math> since a LTI system can not generate a frequency which is not in the input signal.<br />
<br />
Let's consider a simple example, where an environment composed of different pens on a white support is illuminated by white light as in Fig. 1. Under these conditions, note that each object is characterized by a different color since they all accept the incident power and they each reflect a tiny part of the input spectrum. However, if we replace the white light by a red light (or any monochromatic color), each object will reflect the CW with an attenuation <math>|H(f_0)|</math> and a phase shift of <math>Arg(H(f_0))</math> but the frequency of the reflected wave will remain at <math>f_0</math> and the color of all object lies in between red (when attenuation is low) and black (when attenuation is high). Results are presented in Fig. 2. Almost all the objects that we see around us (like these pens and this support) are LTI systems.<br />
<br />
This simple observation implies important constraints if we want to identify any LTI object according the their backscattered or reflected signal:<br />
# The coding capacity only depends on the number of the color which can be distinguished. This capacity is only a function of the frequency resolution compared to the total bandwidth used by the reader. The total bandwidth used by the reader depends on the input signal. That is why we can differentiate pen under white light and not under red light.<br />
# The associated read range is only limited by the ratio in between the power backscattered by the object compared to the power reflected by the environment at the same frequency. This condition is harder to see with the picture since, pens can be separated spatially due to the camera lens but remember that an antenna cannot detect the direction of arrival of the received power.<br />
These limitation only appear since both pens and support (white table) are LTI systems and impose strict constraint in term of coding capacity and read range for any system based on LTI transponders.<br />
<br />
== Research Interest ==<br />
<br />
My research interests include all systems which cannot be modeled by a linear time-invariant system. As a direct consequence, these systems cannot be described by an impulse response or a transfer function<br />
and are able to accept the incident power at a given frequency and reflect or backscatter (a part of) this power at an other frequency or in another bandwidth. For example, in Fig. 2, these systems could appear under the red illumination as blue of green objects...<br />
This result can be obtained by only 2 ways, breaking the linearity (i.e., non linear systems) or breaking the time invariance (i.e. linear time variant systems). A third method consist of breaking the invariance on the reader side.<br />
<br />
Note also that breaking the time-invariance with a scatterer has been investigated since 1948 by H. Stockman, <ref>"Communication by Means of Reflected Power," in Proceedings of the IRE, vol. 36, no. 10, pp. 1196-1204, Oct. 1948, doi: 10.1109/JRPROC.1948.226245</ref> and can be obtained, citing the author, by "variable-damping modulation, interference or phase modulation, directional modulation, position modulation, doppler modulation, and polarization modulation". The first case is actually, the operation principle of a UHF RFID tag. Doppler and polarization modulation are described hereafter.<br />
<br />
=== Linear time variant systems ===<br />
<br />
[[File:line_coding.png|300px|thumb|right|Fig. 4: PSD of the signal backscattered by a modulating tag.]]<br />
<br />
These class of transponders include many examples. The more famous ones are classical RFID tags. UHF RFID tags can, when a sufficient power is received by the chip, switch the internal load connected to the antenna in between 2 values, its RCS is also modified and becomes a function of the time. Finally the variations of the backscattered signal generate a modulation which can be detected by the reader. As a direct consequence, the backscattered power spectral density includes components which are not at <math>f_0</math>. If the transmission data rate is much lower than the carrier frequency, narrow band signal approximation holds and PSD is located around <math>f_0</math>. The exact characteristics of the PSD depends on the data encoding used by the tag during the communication. The UHF RFID standard defines two different modulations for the tag which are FM0 and Miller (with different subcarrier sequences). Analytical formula of the PSD for FM0 is known and is equal to the Manchester encoding. For Miller modulation, analytical formula is also known, but without considering the subcarrier sequences. Fig. 5 presents the PSD of the baseband signals corresponding to the different modulations used by the tag. For all modulation we can see that the PSD is spread around <math>f_0</math> and that the system can not be considered as a LTI system.<br />
<br />
<br />
Another example appears when objects are moved or rotated into space. This interesting phenomenon is better illustrated by considering the simple case where a target is impinged by a continuous wave at a frequency <math>f_0</math>, if the radial speed of the target compared to the antenna is not zero, Doppler effect actually modifies the backscattered wave frequency received by the antenna which can be expressed as:<br />
<br />
<math> <br />
f=\left(\frac {c}{c\pm v_s}\right)f_0<br />
</math><br />
<br />
[[File:stem.png|thumb|right|Fig. 5: Spectrum of a rotating dipole impinged by a CW.]]<br />
<br />
Periodical movements of frequency <math>f_r</math>, such as vibrations and rotations, lead to simple analytical expressions where the backscattered spectrum is composed of discrete peaks located at <math>f_0 \pm n f_r</math> <ref> A. Azarfar, N. Barbot, and E. Perret. "Towards chipless RFID technology based on micro-Doppler effect for long range applications." In 2021 IEEE MTT-SInternational Microwave Symposium (IMS), Jun. 2021 Atlanta, GA</ref>. Let's consider a vertical dipole oriented along <math>z</math> located at <math>x=5</math> cm and <math>y=0</math> cm and impinged by a plane wave at 915 MHz propagating along <math>y</math>. If we rotate this dipole along the <math>z</math> axis with a frequency <math>f_r</math>, the phase backscattered electric field in farfield is modulated by a sinus function while the magnitude remains constant (micro-Doppler). This situation can surprisingly easily be simulated in time domain using a frequency solver such as <syntaxhighlight lang="text" inline>nec2</syntaxhighlight>.<br />
<br />
<syntaxhighlight lang="text" line='line' highlight="3"><br />
CE MICRO-DOPPLER<br />
GW 0 50 -0.0165 0.05 0. 0.0165 0.05 0. 0.0005<br />
GM 0 0 0. 0. 0. 0. 0. 0.<br />
GE<br />
EX 1 1 1 0 0 0 0 0 0 0<br />
FR 0 1 0 0 915e6 0<br />
RP 0 1 1 1000 0 0 0 0 1<br />
EN<br />
</syntaxhighlight><br />
<br />
Since at any given time, the system can be assumed as a linear time invariant system, the excitation of the structure by a CW can be fully described by simply determining the received amplitude and phase.<br />
Thus, the received response during the rotation can be estimated by determining the variation of amplitude and phase scattered by the structure, for each angle <math>\theta</math> of the scatterer. The variation of the amplitude and phase also correspond to the variations of the received signal the time domain signal. Thus by changing the <syntaxhighlight lang="text" inline>GM</syntaxhighlight> card, the backscattered signal can be determined for all <math>\theta</math> values. Fourier series of this signal can be computed and lead to a discrete spectrum at <math>k f_r</math> presented in Fig. 4. Analytical form is identical to a frequency modulated signal with an index modulation of <math>\beta = 1.92</math> and can be expressed as a function of the Bessel function of first kind.<br />
<br />
Another example, can be based on the polarization modulation by changing the orientation of the scatterer as a function of time <ref>N. Barbot and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/nl.pdf "Linear time-variant chipless RFID sensor,"] IEEE Journal of Radio Frequency Identification, early access.</ref>. Note that this modulation can only create power at <math>f_0</math> and <math>f_0 \pm f_r</math> which is very different compared to the Doppler modulation. Results can be accurately predicted using the variation polarization scattering matrix as the function of time.<br />
<br />
Finally, note that for every modification of the response of the transponder during the interrogation done by the reader implies a modulation of the backscattered signal in time which generates a non-zero power in the PSD around <math>f_0</math>. However these modifications require an energy source which can be brought by the reader itself (as in UHF RFID) or by an external action (as the displacement or rotation of the tag). In these latter case, transponders can be considered as semi-passive.<br />
<br />
=== Imaging systems ===<br />
<br />
[[File:Myean13.png|thumb|right|Fig. 6: Barcode and modulated reflected signal]]<br />
<br />
Imaging systems are a special kind of linear time variant system where the variations are not produced by the tag but by the reader itself. In this case, the tag remains a LTI systems, but the reading method done by the reader allows to extract the tag response as a function of variation in time which break the invariance propertie. These tags (and the associated reading method) are not limited by the bounds on coding capacity and read range. The simplest example is the barcode and is presented in Fig. 5. Classical barcodes are composed of black stripes and can encode 43 bits of information. Barcodes are read by sweeping the beam produced by a laser diode along the tag and by measuring the variations of the reflected signal in time. Scientists often usually consider that chipless technology is more related to barcodes than UHF technology, however, note that the reflected signal of a barcode is a modulated signal which is, by principle, identical to the backscattered signals of UHF RFID and moving or rotating tags. As such, barcodes and their reading method cannot be considered as LTI systems and are characterized by a non-zero delta RCS and a (possible) much larger read range.<br />
<br />
This spatial diversity allows to use the same color multiple time to encode information (stripes do not have to use a different color and 2 colors are enought) which significantly increases the coding capacity. <br />
2D images and their associated reading method can also be considered as linear time variant systems (which include QR code, or any image obtained with a lens and camera sensor). All these systems operate in the optical domain since spatial resolution is only limited by the small beam divergence of laser diodes (less than 1 mrad) or the sensor matrix size of camera sensors. However, note that when frequency is decreased, antenna directivity is also reduced which significantly limits the performance of this approach in the RF domain. For example in UWB band half power angle is usually higher than 10° which imposes large separation in between stripes (or resonators).<br />
<br />
=== Non linear systems ===<br />
<br />
Transponders based on a non-linear element (such as a Schottky diode) can accept a power at <math>f_0</math> and generate a power at <math>n f_0</math>. Let's consider the simple circuit composed of a generator connected to a load but where a diode in inserted in serial in the circuit. The diode is a simple device which conducts the current mainly in a single direction. The relation which describe the current <math>I</math> flowing through the diode as a function of the voltage across the junction <math>V_D</math> can be expressed as:<br />
<br />
<math><br />
I=I_S\left(e^{\frac {V_D}{nV_T}}-1\right)<br />
</math><br />
<br />
with <math>V_T = kT/q</math>. If we consider a small variation of the junction voltage <math>v</math> around a bias voltage operating point <math>V_b</math>, the current <math>i</math> can be expressed as Taylor series:<br />
<br />
<math><br />
i(v) = i(V_b) + \frac{i^{(1)}}{1!} (v-V_b) + \frac{i^{(2)}(V_b)}{2!} (v-V_D)^2 + \frac{i^{(3)}(V_b)}{3!} (v-V_b)^3+\cdots<br />
</math><br />
<br />
where <math>i^{(n)}</math> is the <math>n^{\text{th}}</math>-derivative of <math>i(v)</math> according to <math>v</math>.<br />
<br />
If an harmonic tension such as <math>v(t)=A\cos \omega_0 t</math> is applied to this diode, its current <math>i(t)</math><br />
can be expressed as:<br />
<br />
<math><br />
\begin{align}<br />
i(V_D,t) &= i(V_D) + [\frac{A^2}{4} i^{(2)}(V_b) + \frac{A^4}{64}i^{(4)}(V_b)+\cdots]\\<br />
&+ [A i^{(1)}(V_D) + \frac{A^3}{8} i^{(3)}(V_b) + \cdots] \cos \omega_0 t\\<br />
&+ [\frac{A^2}{4} i^{(2)}(V_b) + \frac{A^4}{48}i^{(4)}(V_b)+\cdots] \cos 2\omega_0 t\\<br />
&+ [\frac{A^3}{24} i^{(3)}(V_b) + \frac{A^5}{384}i^{(4)}(V_b)+\cdots] \cos 3\omega_0 t\\<br />
&+ \cdots<br />
\end{align}<br />
</math><br />
<br />
where we can see that an infinite sum of harmonics has been created due the non-linear behavior of the diode.<br />
<!-- Note also, that each term can be viewed as coefficient of Fourier series of the decomposition <math>i(V_d, t)</math>. --><br />
<br />
<!-- [[File:Vtime.png|300px|thumb|right|Voltage across R in the time domain]] --><br />
<br />
[[File:Vfrequency.png|300px|thumb|right|Fig. 3: Voltage across R in the frequency domain]]<br />
<br />
This circuit can easily be simulated using <syntaxhighlight lang="text" inline>ngspice</syntaxhighlight> using the transient analysis to clearly see the effect of the non-linearity of a HSMS285x diode.<br />
Amplitude has been set to 1V, frequency at 915 MHz. Simulation has been computed over a duration of 10 periods with 100 samples per period. Fourier series have been computed over the voltage across the load.<br />
<br />
<syntaxhighlight lang="text" line="line"><br />
.title diode<br />
.param A = 1<br />
.param f0 = 915e6<br />
.model hsms285x D (IS=3e-6 RS=25 N=1.06 CJO=0.18pF VJ=0.35 M=0.5 EG=0.69 XTI=2 BV=3.8 IBV=3e-4)<br />
V1 1 0 dc 0 SIN(0 A f0 0NS 0)<br />
Ra 2 1 50<br />
D1 2 3 hsms285x<br />
Rl 3 0 50<br />
.end<br />
<br />
.csparam csf0 = {f0}<br />
.csparam duration = {10.0/f0}<br />
.csparam fsample = {1/(100*f0)}<br />
.control<br />
tran $&fsample $&duration<br />
plot v(3)<br />
fourier $&csf0 v(3)<br />
.endc<br />
</syntaxhighlight><br />
<br />
The simulation clearly shows that the power dissipated into the load contains power at <math>f_0</math> but also at <math>n f_0</math> due to the non-linear behavior of the diode.<br />
Harvesters use the power located at <math>n=0</math> where as harmonic transponders are based on the power located at <math>n > 1</math>.<br />
<br />
For passive harmonic transponders, an antenna accepting the power at <math>f_0</math> have to be added. The backscattered power at <math>n f_0</math> should also be re-radiated by another antenna.<br />
The main difficulty appears from the incident power which is very low (few micro Watt) which need to generate a voltage higher than the threshold of the diode (around 0.3 V). Usually the conversion loss associated to these devices is lower than -20 dB (i.e. only 1% of the incident power is converted to an harmonic frequency). However, read range of these transponders can easily achieve more than 5 m while satisfying regulation standards.<br />
<br />
----<br />
<br />
Finally, all presented systems (time-varing and non-linear transponders) can also be characterized by a non-zero differential RCS (or delta RCS) <math>\sigma_d</math> since they are able to modulate their backscattered power. This delta RCS is the direct generalization of the quantity classically defined for UHF tags. More information can be found [[Differential RCS|here]].<br />
<br />
== Conclusion ==<br />
<br />
I hope you have liked this page. If you have any comment, remarks or questions about these ideas, feel free to send me an email:<br />
<br />
[mailto:nicolas.barbot@lcis.grenoble-inp.fr <syntaxhighlight lang="text" inline>nicolas.barbot@lcis.grenoble-inp.fr</syntaxhighlight>]<br />
<br />
Collaborations often start by simple emails...<br />
<br />
==References==<br />
<br />
<references /></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Research_Activities&diff=573Research Activities2026-03-25T21:36:35Z<p>Nico: </p>
<hr />
<div>My research interests include passive (or semi-passive) transponders which can not be modeled as linear time-invariant systems. These transponders have enhanced performance in term of coding capacity and read range compared to classical linear time-invariant systems. These results and can only be achieved by breaking the linearity or the time invariance associated to the transponder.<br />
<br />
<br />
== Introduction ==<br />
<br />
[[File:Color.gif|thumb|right|Fig. 1: Environment under white light]]<br />
<br />
[[File:Color_red.gif|thumb|right|Fig. 2: Environment under red light]]<br />
<br />
Almost all the objects that we can see or characterize are Linear Time Invariant (LTI) systems. It implies that if they are impinged by an electromagnetic wave at a frequency <math>f_0</math> (in input), they also reflect or backscatter an electromagnetic wave at the same frequency <math>f_0</math> (in output).<br />
<br />
These LTI systems can be fully characterized by their impulse response <math>h(t)</math> in the time domain or their transfer function <math>H(f)</math> in the frequency domain. The output signal <math>y(t)</math> can be obtained in the time domain if the input signal <math>x(t)</math> is known as:<br />
<br />
<math><br />
y(t) = x(t) * h(t)<br />
</math><br />
<br />
Expression can equivalently be derived in the frequency domain:<br />
<br />
<math><br />
Y(f) = X(f) \times H(f)<br />
</math><br />
<br />
Classical examples include dynamical systems (electrical circuits, mechanical systems...). <br />
If we consider that the incident waveform is a continuous wave of frequency <math>f_0</math> then its real signal can be expressed as <math>x(t) = \cos 2 \pi f_0 t</math>. The received signal takes in that case, the simple form:<br />
<br />
<math><br />
y(t) = |H(f_0)| \cos (2 \pi f_0 t + Arg(H(f_0)))<br />
</math><br />
<br />
where we can easily see that the backscattered signal of a LTI system can only affect the amplitude <math>|H(f_0)|</math> and/or the phase <math>Arg(H(f_0))</math> of the incident waveform. Note that all the received power is also located at <math>f_0</math> since a LTI system can not generate a frequency which is not in the input signal.<br />
<br />
Let's consider a simple example, where an environment composed of different pens on a white support is illuminated by white light as in Fig. 1. Under these conditions, note that each object is characterized by a different color since they all accept the incident power and they each reflect a tiny part of the input spectrum. However, if we replace the white light by a red light (or any monochromatic color), each object will reflect the CW with an attenuation <math>|H(f_0)|</math> and a phase shift of <math>Arg(H(f_0))</math> but the frequency of the reflected wave will remain at <math>f_0</math> and the color of all object lies in between red (when attenuation is low) and black (when attenuation is high). Results are presented in Fig. 2. Almost all the objects that we see around us (like these pens and this support) are LTI systems.<br />
<br />
This simple observation implies important constraints if we want to identify any LTI object according the their backscattered or reflected signal:<br />
# The coding capacity only depends on the number of the color which can be distinguished. This capacity is only a function of the frequency resolution compared to the total bandwidth used by the reader. The total bandwidth used by the reader depends on the input signal. That is why we can differentiate pen under white light and not under red light.<br />
# The associated read range is only limited by the ratio in between the power backscattered by the object compared to the power reflected by the environment at the same frequency. This condition is harder to see with the picture since, pens can be separated spatially due to the camera lens but remember that an antenna cannot detect the direction of arrival of the received power.<br />
These limitation only appear since both pens and support (white table) are LTI systems and impose strict constraint in term of coding capacity and read range for any system based on LTI transponders.<br />
<br />
== Research Interest ==<br />
<br />
My research interests include all systems which cannot be modeled by a linear time-invariant system. As a direct consequence, these systems cannot be described by an impulse response or a transfer function<br />
and are able to accept the incident power at a given frequency and reflect or backscatter (a part of) this power at an other frequency or in another bandwidth. For example, in Fig. 2, these systems could appear under the red illumination as blue of green objects...<br />
This result can be obtained by only 2 ways, breaking the linearity (i.e., non linear systems) or breaking the time invariance (i.e. linear time variant systems). A third method consist of breaking the invariance on the reader side.<br />
<br />
Note also that breaking the time-invariance with a scatterer has been investigated since 1948 by H. Stockman, <ref>"Communication by Means of Reflected Power," in Proceedings of the IRE, vol. 36, no. 10, pp. 1196-1204, Oct. 1948, doi: 10.1109/JRPROC.1948.226245</ref> and can be obtained, citing the author, by "variable-damping modulation, interference or phase modulation, directional modulation, position modulation, doppler modulation, and polarization modulation". The first case is actually, the operation principle of a UHF RFID tag. Doppler and polarization modulation are described hereafter.<br />
<br />
=== Linear time variant systems ===<br />
<br />
[[File:line_coding.png|300px|thumb|right|Fig. 4: PSD of the signal backscattered by a modulating tag.]]<br />
<br />
These class of transponders include many examples. The more famous ones are classical RFID tags. UHF RFID tags can, when a sufficient power is received by the chip, switch the internal load connected to the antenna in between 2 values, its RCS is also modified and becomes a function of the time. Finally the variations of the backscattered signal generate a modulation which can be detected by the reader. As a direct consequence, the backscattered power spectral density includes components which are not at <math>f_0</math>. If the transmission data rate is much lower than the carrier frequency, narrow band signal approximation holds and PSD is located around <math>f_0</math>. The exact characteristics of the PSD depends on the data encoding used by the tag during the communication. The UHF RFID standard defines two different modulations for the tag which are FM0 and Miller (with different subcarrier sequences). Analytical formula of the PSD for FM0 is known and is equal to the Manchester encoding. For Miller modulation, analytical formula is also known, but without considering the subcarrier sequences. Fig. 5 presents the PSD of the baseband signals corresponding to the different modulations used by the tag. For all modulation we can see that the PSD is spread around <math>f_0</math> and that the system can not be considered as a LTI system.<br />
<br />
<br />
Another example appears when objects are moved or rotated into space. This interesting phenomenon is better illustrated by considering the simple case where a target is impinged by a continuous wave at a frequency <math>f_0</math>, if the radial speed of the target compared to the antenna is not zero, Doppler effect actually modifies the backscattered wave frequency received by the antenna which can be expressed as:<br />
<br />
<math> <br />
f=\left(\frac {c}{c\pm v_s}\right)f_0<br />
</math><br />
<br />
[[File:stem.png|thumb|right|Fig. 5: Spectrum of a rotating dipole impinged by a CW.]]<br />
<br />
Periodical movements of frequency <math>f_r</math>, such as vibrations and rotations, lead to simple analytical expressions where the backscattered spectrum is composed of discrete peaks located at <math>f_0 \pm n f_r</math> <ref> A. Azarfar, N. Barbot, and E. Perret. "Towards chipless RFID technology based on micro-Doppler effect for long range applications." In 2021 IEEE MTT-SInternational Microwave Symposium (IMS), Jun. 2021 Atlanta, GA</ref>. Let's consider a vertical dipole oriented along <math>z</math> located at <math>x=5</math> cm and <math>y=0</math> cm and impinged by a plane wave at 915 MHz propagating along <math>y</math>. If we rotate this dipole along the <math>Z</math> axis with a frequency <math>f_r</math>, the phase backscattered electric field in farfield is modulated by a sinus function while the magnitude remains constant (micro-Doppler). This situation can surprisingly easily be simulated in time domain using a frequency solver such as <syntaxhighlight lang="text" inline>nec2</syntaxhighlight>.<br />
<br />
<syntaxhighlight lang="text" line='line' highlight="3"><br />
CE MICRO-DOPPLER<br />
GW 0 50 -0.0165 0.05 0. 0.0165 0.05 0. 0.0005<br />
GM 0 0 0. 0. 0. 0. 0. 0.<br />
GE<br />
EX 1 1 1 0 0 0 0 0 0 0<br />
FR 0 1 0 0 915e6 0<br />
RP 0 1 1 1000 0 0 0 0 1<br />
EN<br />
</syntaxhighlight><br />
<br />
Since at any given time, the system can be assumed as a linear time invariant system, the excitation of the structure by a CW can be fully described by simply determining the received amplitude and phase.<br />
Thus, the received response during the rotation can be estimated by determining the variation of amplitude and phase scattered by the structure, for each angle <math>\theta</math> of the scatterer. The variation of the amplitude and phase also correspond to the variations of the received signal the time domain signal. Thus by changing the <syntaxhighlight lang="text" inline>GM</syntaxhighlight> card, the backscattered signal can be determined for all <math>\theta</math> values. Fourier series of this signal can be computed and lead to a discrete spectrum at <math>k f_r</math> presented in Fig. 4. Analytical form is identical to a frequency modulated signal with an index modulation of <math>\beta = 1.92</math> and can be expressed as a function of the Bessel function of first kind.<br />
<br />
Another example, can be based on the polarization modulation by changing the orientation of the scatterer as a function of time <ref>N. Barbot and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/nl.pdf "Linear time-variant chipless RFID sensor,"] IEEE Journal of Radio Frequency Identification, early access.</ref>. Note that this modulation can only create power at <math>f_0</math> and <math>f_0 \pm f_r</math> which is very different compared to the Doppler modulation. Results can be accurately predicted using the variation polarization scattering matrix as the function of time.<br />
<br />
Finally, note that for every modification of the response of the transponder during the interrogation done by the reader implies a modulation of the backscattered signal in time which generates a non-zero power in the PSD around <math>f_0</math>. However these modifications require an energy source which can be brought by the reader itself (as in UHF RFID) or by an external action (as the displacement or rotation of the tag). In these latter case, transponders can be considered as semi-passive.<br />
<br />
=== Imaging systems ===<br />
<br />
[[File:Myean13.png|thumb|right|Fig. 6: Barcode and modulated reflected signal]]<br />
<br />
Imaging systems are a special kind of linear time variant system where the variations are not produced by the tag but by the reader itself. In this case, the tag remains a LTI systems, but the reading method done by the reader allows to extract the tag response as a function of variation in time which break the invariance propertie. These tags (and the associated reading method) are not limited by the bounds on coding capacity and read range. The simplest example is the barcode and is presented in Fig. 5. Classical barcodes are composed of black stripes and can encode 43 bits of information. Barcodes are read by sweeping the beam produced by a laser diode along the tag and by measuring the variations of the reflected signal in time. Scientists often usually consider that chipless technology is more related to barcodes than UHF technology, however, note that the reflected signal of a barcode is a modulated signal which is, by principle, identical to the backscattered signals of UHF RFID and moving or rotating tags. As such, barcodes and their reading method cannot be considered as LTI systems and are characterized by a non-zero delta RCS and a (possible) much larger read range.<br />
<br />
This spatial diversity allows to use the same color multiple time to encode information (stripes do not have to use a different color and 2 colors are enought) which significantly increases the coding capacity. <br />
2D images and their associated reading method can also be considered as linear time variant systems (which include QR code, or any image obtained with a lens and camera sensor). All these systems operate in the optical domain since spatial resolution is only limited by the small beam divergence of laser diodes (less than 1 mrad) or the sensor matrix size of camera sensors. However, note that when frequency is decreased, antenna directivity is also reduced which significantly limits the performance of this approach in the RF domain. For example in UWB band half power angle is usually higher than 10° which imposes large separation in between stripes (or resonators).<br />
<br />
=== Non linear systems ===<br />
<br />
Transponders based on a non-linear element (such as a Schottky diode) can accept a power at <math>f_0</math> and generate a power at <math>n f_0</math>. Let's consider the simple circuit composed of a generator connected to a load but where a diode in inserted in serial in the circuit. The diode is a simple device which conducts the current mainly in a single direction. The relation which describe the current <math>I</math> flowing through the diode as a function of the voltage across the junction <math>V_D</math> can be expressed as:<br />
<br />
<math><br />
I=I_S\left(e^{\frac {V_D}{nV_T}}-1\right)<br />
</math><br />
<br />
with <math>V_T = kT/q</math>. If we consider a small variation of the junction voltage <math>v</math> around a bias voltage operating point <math>V_b</math>, the current <math>i</math> can be expressed as Taylor series:<br />
<br />
<math><br />
i(v) = i(V_b) + \frac{i^{(1)}}{1!} (v-V_b) + \frac{i^{(2)}(V_b)}{2!} (v-V_D)^2 + \frac{i^{(3)}(V_b)}{3!} (v-V_b)^3+\cdots<br />
</math><br />
<br />
where <math>i^{(n)}</math> is the <math>n^{\text{th}}</math>-derivative of <math>i(v)</math> according to <math>v</math>.<br />
<br />
If an harmonic tension such as <math>v(t)=A\cos \omega_0 t</math> is applied to this diode, its current <math>i(t)</math><br />
can be expressed as:<br />
<br />
<math><br />
\begin{align}<br />
i(V_D,t) &= i(V_D) + [\frac{A^2}{4} i^{(2)}(V_b) + \frac{A^4}{64}i^{(4)}(V_b)+\cdots]\\<br />
&+ [A i^{(1)}(V_D) + \frac{A^3}{8} i^{(3)}(V_b) + \cdots] \cos \omega_0 t\\<br />
&+ [\frac{A^2}{4} i^{(2)}(V_b) + \frac{A^4}{48}i^{(4)}(V_b)+\cdots] \cos 2\omega_0 t\\<br />
&+ [\frac{A^3}{24} i^{(3)}(V_b) + \frac{A^5}{384}i^{(4)}(V_b)+\cdots] \cos 3\omega_0 t\\<br />
&+ \cdots<br />
\end{align}<br />
</math><br />
<br />
where we can see that an infinite sum of harmonics has been created due the non-linear behavior of the diode.<br />
<!-- Note also, that each term can be viewed as coefficient of Fourier series of the decomposition <math>i(V_d, t)</math>. --><br />
<br />
<!-- [[File:Vtime.png|300px|thumb|right|Voltage across R in the time domain]] --><br />
<br />
[[File:Vfrequency.png|300px|thumb|right|Fig. 3: Voltage across R in the frequency domain]]<br />
<br />
This circuit can easily be simulated using <syntaxhighlight lang="text" inline>ngspice</syntaxhighlight> using the transient analysis to clearly see the effect of the non-linearity of a HSMS285x diode.<br />
Amplitude has been set to 1V, frequency at 915 MHz. Simulation has been computed over a duration of 10 periods with 100 samples per period. Fourier series have been computed over the voltage across the load.<br />
<br />
<syntaxhighlight lang="text" line="line"><br />
.title diode<br />
.param A = 1<br />
.param f0 = 915e6<br />
.model hsms285x D (IS=3e-6 RS=25 N=1.06 CJO=0.18pF VJ=0.35 M=0.5 EG=0.69 XTI=2 BV=3.8 IBV=3e-4)<br />
V1 1 0 dc 0 SIN(0 A f0 0NS 0)<br />
Ra 2 1 50<br />
D1 2 3 hsms285x<br />
Rl 3 0 50<br />
.end<br />
<br />
.csparam csf0 = {f0}<br />
.csparam duration = {10.0/f0}<br />
.csparam fsample = {1/(100*f0)}<br />
.control<br />
tran $&fsample $&duration<br />
plot v(3)<br />
fourier $&csf0 v(3)<br />
.endc<br />
</syntaxhighlight><br />
<br />
The simulation clearly shows that the power dissipated into the load contains power at <math>f_0</math> but also at <math>n f_0</math> due to the non-linear behavior of the diode.<br />
Harvesters use the power located at <math>n=0</math> where as harmonic transponders are based on the power located at <math>n > 1</math>.<br />
<br />
For passive harmonic transponders, an antenna accepting the power at <math>f_0</math> have to be added. The backscattered power at <math>n f_0</math> should also be re-radiated by another antenna.<br />
The main difficulty appears from the incident power which is very low (few micro Watt) which need to generate a voltage higher than the threshold of the diode (around 0.3 V). Usually the conversion loss associated to these devices is lower than -20 dB (i.e. only 1% of the incident power is converted to an harmonic frequency). However, read range of these transponders can easily achieve more than 5 m while satisfying regulation standards.<br />
<br />
----<br />
<br />
Finally, all presented systems (time-varing and non-linear transponders) can also be characterized by a non-zero differential RCS (or delta RCS) <math>\sigma_d</math> since they are able to modulate their backscattered power. This delta RCS is the direct generalization of the quantity classically defined for UHF tags. More information can be found [[Differential RCS|here]].<br />
<br />
== Conclusion ==<br />
<br />
I hope you have liked this page. If you have any comment, remarks or questions about these ideas, feel free to send me an email:<br />
<br />
[mailto:nicolas.barbot@lcis.grenoble-inp.fr <syntaxhighlight lang="text" inline>nicolas.barbot@lcis.grenoble-inp.fr</syntaxhighlight>]<br />
<br />
Collaborations often start by simple emails...<br />
<br />
==References==<br />
<br />
<references /></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Nicolas_Barbot&diff=571Nicolas Barbot2026-01-08T11:04:14Z<p>Nico: </p>
<hr />
<div>{{Infobox person<br />
| name = Nicolas Barbot<br />
| image = File:NBarbot.jpg<br />
| image_size = 220px<br />
| nationality = French<br />
| birth_date = {{Birth date and age|1986|08|11}}<br />
| birth_place = Limoges, France<br />
}}<br />
<br />
'''Nicolas Barbot''' received the M.Sc. degree and Ph.D. degree from the University de Limoges, France in 2010 and 2013 respectively. His Ph.D. work in [https://www.xlim.fr/ Xlim] Laboratory was focused on error-correcting codes for the optical wireless channel. He also completed a post-doctoral work in joint source-channel decoding at [https://l2s.centralesupelec.fr/ L2S] Laboratory, in Gif-sur-Yvette, France. Since September 2014, he has been an Associate Professor at the Université Grenoble Alpes - Grenoble Institute of Technology, in Valence, France. His scientific background at [https://lcis.grenoble-inp.fr/ LCIS] Laboratory covers wireless communications systems based on backscattering principle which include classical RFID and chipless RFID.<br />
<br />
His research interests include transponders which can not be described by linear time-invariant systems. This gathers harmonic transponders which are based on the use of a non-linear component (Schottky diode) or linear time-variant transponders which are based on the modification of their response in the time domain.<br />
He also places special interests on antenna design and instrumentation based on these phenomena.<br />
<br />
==Education==<br />
<br />
{| class="wikitable" style="text-align: left;width: 80%;"<br />
|-<br />
!Period<br />
!Postion/Diploma<br />
|-<br />
|2023<br />
|align=left|HDR, Linear Time-Variant and Non-Linear Transponders for Identification and Sensing Applications, Valence, France<br />
|-<br />
|2014–2021<br />
|align=left|Assistant Professor at Grenoble INP - Esisar, LCIS, Valence, France<br />
|-<br />
|2013–2014<br />
|align=left|Post-Doc at Laboratoire des Signaux et Systèmes (L2S), ''Cross-Layer Design of Wireless Tranceivers'', Gif-sur-Yvette, France<br />
|-<br />
|2010–2013<br />
|align=left|PhD Thesis, Xlim CNRS UMR 7252, ''Channel Coding for Optical Wireless Communications'', Limoges, France<br />
|-<br />
|2009–2010<br />
|align=left|Master Degree, Faculté des Sciences, ''Technologies Hyperfréquences, Électronique et Optique'', Limoges, France<br />
|-<br />
|2007–2010<br />
|align=left|Diplome d'ingénieur, École Nationale Supérieure d’Ingénieurs de Limoges, Électronique et Télécommunications, Limoges, France<br />
|-<br />
|2005–2007<br />
|align=left|DUT Mesures Physiques, IUT du Limousin, Limoges, France<br />
|}<br />
<br />
==Teaching ==<br />
<br />
{| class="wikitable" style="text-align: left;width: 80%;"<br />
|-<br />
!Courses<br />
!Full name<br />
!Grade<br />
!ECTS<br />
|-<br />
|[[CE515 Advanced Processor Architecture and SoC Design|CE515]]<br />
|align=left|Advanced Processor Architecture and SoC Design<br />
|5A<br />
|4<br />
|-<br />
|[[PX505 Innovation Project|PX505]]<br />
|align=left|Innovation Project<br />
|5A<br />
|4<br />
|-<br />
|[[AC469 Introduction to statistical signal processing|AC469]]<br />
|align=left|Introduction to statistical signal processing<br />
|4App<br />
|1.5<br />
|-<br />
|[[SN424 Software Defined Radio|SN424]]<br />
|align=left|Software Defined Radio<br />
|4A<br />
|2.5<br />
|-<br />
|[[MA331 Information Theory and Channel Coding|MA331]]<br />
|align=left|Information Theory and Channel Coding<br />
|3A<br />
|3<br />
|-<br />
|[[PX302 Introduction to STM32 micro-controllers|PX302]]<br />
|align=left|Introduction to STM32 micro-controllers<br />
|3A<br />
|3<br />
|-<br />
|[[PX212 Mini-Project|PX212]]<br />
|align=left|Mini-Project<br />
|2A<br />
|6<br />
|}<br />
<br />
==Research Activities==<br />
<br />
In the first part of my career, my research activities have been focused on chipless RFID.<br />
This technology allows one to reduce the cost of the tags since information can be embedded and transmitted to the reader<br />
without using a silicon chip. However, since these tags are Linear Time-Invariant (LTI) systems<br />
<ref>N. Barbot, O. Rance, and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/range.pdf "Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?,"]<br />
IEEE Transactions on Microwave Theory and Techniques, vol. 69, no. 9, pp. 4199-4208, Sept. 2021.</ref>, their backscattered power<br />
are also located in the same bandwidth as the one used by the reader making the reading difficult in non-free space environments.<br />
Consequently, significant limitations appears in term of read range, coding capacity and media access control for any chipless tag.<br />
In order to break these limitations, my research investigations now cover:<br />
* non-linear (or harmonic) transponders which can backscatter a power at <math>n f_0</math>. These transponders are base on a non-linear component (typically a Schottky diode).<br />
* linear time-variant transponders which can backscatter a power around <math>f_0</math> <ref>N. Barbot and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/nl.pdf "Linear time-variant chipless RFID sensor,"] IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022.</ref>. These transponders can modulate the backscattered signal (classical UHF tags, micro-Doppler or more generally any moving scatterers).<br />
<br />
In these two cases, the tags cannot be described by LTI systems and are not bounded by the previous limitations. They<br />
are also characterized by a non zero [[Differential RCS|delta RCS]] <math>\sigma_d</math><ref>N. Barbot, O. Rance, and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/rcs.pdf "Differential RCS of modulated tag,"] IEEE Transactions on Antennas and Propagation, vol. 69, no. 9, pp. 6128-6133, Sept. 2021.</ref>.<br />
<br />
Additional details can be found [[Research Activities|here]].<br />
<br />
PhD students:<br />
* '''Meng Yang''', "Non-linear Transponders for Identification and Sensing Applications," Directeur: Nicolas Barbot.<br />
<br />
* '''Ashkan Azarfar''', "Détection de tags sans puce basée sur l'effet Doppler pour les applications de reconnaissance de gestes," Directeur: Etienne Perret, Co-directeur: Nicolas Barbot.<br />
<br />
* '''Florian Requena''', "Conception de tags RIFD sans puce, robustes, pour applications capteur," Directeur: Etienne Perret, Co-directeur: Darine Kaddour, Nicolas Barbot.<br />
<br />
* '''Raymundo de Amorim Junior''', "Tags sans puce millimétriques pour applications sécurisées," Directeur: Etienne Perret, Co-directeur: Romain Siragusa, Nicolas Barbot.<br />
<br />
* '''Rahul Unnikrishnan''', "Reconnaissance de gestes avec des tags chipless," Directeur: Etienne Perret, Co-directeur: Nicolas Barbot.<br />
<br />
* '''Raphael Tavares de Alencar''', "Contribution à la conception et la réalisation de tags RFID sans puce compatibles avec des procédés industriels de fabrication," Directeur: Etienne Perret, Co-directeur: Marco Garbati, Nicolas Barbot.<br />
<br />
* '''Florent Bonnefoy''', "Authentification dans le domaine THz," Directeur: Frédéric Garet, Co-directeur: Maxime Bernier, Nicolas Barbot.<br />
<br />
See the complete [[List of Publications]].<br />
<br />
==CV==<br />
<br />
[https://nicolas-barbot.ovh/wiki/pool/cv_en.pdf English Version]<br />
<br />
[https://nicolas-barbot.ovh/wiki/pool/cv.pdf French Version]<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
==External links==<br />
[https://scholar.google.com/citations?user=mMhPOZYAAAAJ&hl=en&oi=ao Google Scholar]<br />
<br />
[https://orcid.org/0000-0001-6355-9109 ORCID ID]</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=SN420_Software_Defined_Radio&diff=570SN420 Software Defined Radio2026-01-08T11:03:41Z<p>Nico: Nico moved page SN420 Software Defined Radio to SN424 Software Defined Radio</p>
<hr />
<div>#REDIRECT [[SN424 Software Defined Radio]]</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=SN424_Software_Defined_Radio&diff=569SN424 Software Defined Radio2026-01-08T11:03:37Z<p>Nico: Nico moved page SN420 Software Defined Radio to SN424 Software Defined Radio</p>
<hr />
<div>The objective of this course is to understand how we can, with a Software Defined Radio, transmit a message in-between two transceivers spatially separated. Especially, how we can use signal processing operations to adapt (i.e. modulate and demodulate) or any operation normally done in the physical layer. This course describes the processes realized at a signal level and can be related to [[MA331 Information Theory and Channel Coding]] (which presents the general problem at a higher level).<br />
<br />
The following of this page corresponds to the labs.<br />
<br />
__TOC__<br />
<br />
In this labs, we will realize different modulations and demodulations used to transmit and receive analog and digital messages.<br />
Spectrum (or power spectral density) will also be determined.<br />
Finally, performance, in term of Sinal to Noise Ratio (SNR) or Bit Error Rate (BER) will be estimated in each case.<br />
<br />
These labs are based on [https://www.gnuradio.org/ GNU Radio] which is a free software that provides a large number of software blocks to perform most signal processing operations. The blocks are mostly written in C ++. It is possible to use these blocks directly from Python to simulate or create telecommunication systems.<br />
In addition, to make it easier to get started, GNU Radio also provides a utility called <syntaxhighlight lang="text" inline>gnuradio-companion</syntaxhighlight> to assemble blocks graphically and to generate the corresponding python script. This subject have been written for GNU Radio, but it can be equivalently realized using [https://www.gnu.org/software/octave/index Octave], or [http://itpp.sourceforge.net/4.3.1/ IT++] library.<br />
<br />
== Getting Started ==<br />
<br />
* Open a terminal.<br />
<br />
* Create a working directory in which you will place your scripts.<br />
<br />
* Run <syntaxhighlight lang="text" inline>gnuradio-companion</syntaxhighlight>.<br />
<br />
This software allows you to use blocks (available in the right column) and to connect them to realize any complex signal processing operations. Resulting program is called a flowgraph in GNU Radio language.<br />
<br />
For any flowgraph, there is basically 3 types of blocks: sources (which produce samples and have at least 1 output), sinks (which consume samples and have at least 1 input) and processing block (which have at least 1 input and 1 output). Blocks are simply connected by creating a link in-between an output of a block and an input of another block.<br />
<br />
* Create the flowgraph presented in Fig. 1.<br />
<br />
[[File:Im1.png|frame|center|Fig. 1: Simple generation and data plotting]]<br />
<br />
The topleft block <syntaxhighlight lang="text" inline>Options</syntaxhighlight> indicates the global options of the flowgraph. In this block, you can select the libraries used to generate the script (in this case the WX library, on the school computers, this library has the be replaced by the GTK library). The <syntaxhighlight lang="text" inline>Signal Source</syntaxhighlight> block generates an infinity of sinusoidal samples (or other) from the different parameters. These samples are displayed according to the time using the <syntaxhighlight lang="text" inline>Scope Sink</syntaxhighlight> block (on the school computers, this<br />
block has to be replaced by a <syntaxhighlight lang="text" inline>Time Sink</syntaxhighlight>. <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block does not modify the samples but allows to perform a flow control on all the data circulating between the source and the sink. Last, be careful to the color of the input and output of each block since they represent the type of data flowing on the link. The following table presents main data type and associated used by GNU Radio. Also, since Python is strongly typed, colors located at both ends of a wire have to be the same.<br />
<br />
{| class="wikitable" style="text-align: left;"<br />
|-<br />
!Color<br />
!Type<br />
!Size<br />
|-<br />
|style="background: #3399ff;"|<br />
|Complex<br />
|2 x 64 bits<br />
|-<br />
|style="background: #f57c00;"|<br />
|Float<br />
|64 bits<br />
|-<br />
|style="background: #009688;"|<br />
|Int<br />
|64/32 bits<br />
|-<br />
|style="background: #ffeb3b;"|<br />
|Short<br />
|16 bits<br />
|-<br />
|style="background: #d500f9;"|<br />
|Char<br />
|8 bits<br />
|}<br />
<br />
* Save the flowgraph under your directory. This file is saved with a <syntaxhighlight lang="text" inline>.grc</syntaxhighlight> extension.<br />
<br />
* Generate the associated Python script associated to your flowgraph using the "blue to red" button. If errors are present, the script is not generated and full listing is present under the no entry sign. When successful, observe the python script named <syntaxhighlight lang="text" inline>top_block.py</syntaxhighlight> in your directory.<br />
<br />
* Execute the script by pressing the run button. Equivalently, you can also invoke <syntaxhighlight lang="text" inline>python top_block.py</syntaxhighlight>.<br />
<br />
The execution should display an oscilloscope-like widow with the corresponding signal (a cosine function). You can stop the execution by closing the window or by pressing the stop button.<br />
<br />
* Check the amplitude and the period of the generated signal.<br />
<br />
* Add a <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> (on the school computers use a <syntaxhighlight lang="text" inline>Frequency Sink</syntaxhighlight>) to observe the signal spectrum. Place it in parallel of the <syntaxhighlight lang="text" inline>Scope Sink</syntaxhighlight> (or <syntaxhighlight lang="text" inline>Time Sink</syntaxhighlight>).<br />
<br />
* Add a <syntaxhighlight lang="text" inline>Slider</syntaxhighlight> block to modify the frequency of the signal in real time (without recompiling the flowgraph) and check the operation on the scope. Save the flowgraph.<br />
<br />
* Finally, observe the signal (in time and frequency) for a signal frequency lower and higher than 16 kHz. With your observations, redemonstrate Nyquist's theorem.<br />
<br />
Note that the source simply generates samples which are plotted by the sink, however, this source and this sink can produce and consume as much data that your CPU can handle (data are just generated and plotted iteratively as fast as possible). To overcome this issue, the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block is used to process a given number of sample per second, thus lowering the CPU load to few percents. Most of the blocks in GNU Radio do not fixed the rate at which samples are processed: when sufficient number of samples are present at the input, the considered function is called and produces samples at the output which are then available for the other blocks. Usually, this rate is fixed when we work with real devices (for example an audio card can acquire samples at a given frequency e.g. 48 kHz) which fixed the rate for the whole flowgraph. In our example, we do not use any real device so the rate has to be fixed using the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block. Also, for each flowgraph, a single rate has to be used thus if we work with a real device, the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block is not needed anymore and has to be removed.<br />
<br />
<br />
* Create the flowgraph presented in Fig. 2.<br />
<br />
[[File:Im2.png|frame|center|Fig. 2: Simple operations on signals]]<br />
<br />
* Add a <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> (on the school computers use a <syntaxhighlight lang="text" inline>Frequency Sink</syntaxhighlight>) to observe the signal spectrum. On the graph, the two peaks are very close and seem to be confused. Reduce the frequency sampling to increase the frequency resolution. Explain the phenomenum.<br />
<br />
* What is the minimum value of the sampling frequency? Observe the signal (in time and in frequency) for frequencies below this limit.<br />
<br />
* Replace the <syntaxhighlight lang="text" inline>Add</syntaxhighlight> block with a multiplier block <syntaxhighlight lang="text" inline>Mult</syntaxhighlight>. Predict the position of the peaks in the output signal. Check your results.<br />
<br />
* Add a filter (block <syntaxhighlight lang="text" inline>Low Pass Filter</syntaxhighlight>) to recover the low frequency part of the signal. Check your results in the time and frequency domain. Repeat the manipulation to keep the high frequency part.<br />
<br />
The <syntaxhighlight lang="text" inline>Low Pass Filter</syntaxhighlight> (and <syntaxhighlight lang="text" inline>High Pass Filter</syntaxhighlight>) blocks are high-level blocks which realize the design (i.e. determining the coefficients of the filter) as well as the filtering (i.e. the convolution). The filter design can also be done with <syntaxhighlight lang="text" inline>gr_filter_design</syntaxhighlight> to obtain the coefficients. These coefficients can then be used directly by the blocks <syntaxhighlight lang="text" inline>FIR Filter</syntaxhighlight> and <syntaxhighlight lang="text" inline>IIR Filter</syntaxhighlight>.<br />
<br />
== Amplitude Modulation ==<br />
<br />
=== Double side band without carrier ===<br />
<br />
* Realize the modulation of a signal <math>m(t)=\cos 2\pi f_m t</math> using a double side band without carrier. Note that transmitted signal can be expressed as<br />
<br />
<math><br />
s(t) = A m(t) \cos 2 \pi f_0 t<br />
</math><br />
<br />
* Observe the signal in both time and frequency domain.<br />
<br />
* Give the architecture of a coherent detector used to recover the message <math>m(t)</math> from <math>s(t)</math>.<br />
<br />
* Implement this detector to demodulate the signal and verify the good operation. You can use 2 different flowgraphs (1 for the transmission and 1 for the reception) using a <syntaxhighlight lang="text" inline>File Sink</syntaxhighlight> and <syntaxhighlight lang="text" inline>File Source</syntaxhighlight> respectively.<br />
<br />
=== Double side band with carrier ===<br />
<br />
* Realize the modulation of a signal <math>m(t)=\cos 2\pi f_m t</math> using a double side band with carrier. Note that transmitted signal can be expressed as<br />
<br />
[[File:Env.png|thumb|right|Fig. 3: Envelope detector used for AM signals.]]<br />
<br />
<math><br />
s(t) = A (1 + k_a m(t)) \cos 2 \pi f_0 t<br />
</math><br />
<br />
* Observe the signal in both time and frequency domain.<br />
<br />
* Modify the modulation index <math>k_a</math> using a slider and observe the modification of the signal.<br />
<br />
* AM signals are usually demodulted using a simple envelope detector. The architecture of this decoder is presented in Fig. 3.<br />
<br />
* Implement this detector to demodulate the signal and verify the good operation.<br />
<br />
* Check also if the AM signal can be decoded using the coherent detector.<br />
<br />
* Finally, download the file [https://nicolas-barbot.ovh/wiki/pool/am_usrp710.dat <syntaxhighlight lang="text" inline>am_usrp710.dat</syntaxhighlight>]. This file contains the complex envelope (I and Q channels) received by a USRP around the frequency 710 kHz with a sampling frequency of 256 kHz. Visualize the data with a block <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> (insert a block <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> to avoid overloading the processor). On the graph, we can see two stations transmit at 710 kHz (center) and 790 kHz (to the right). Knowing that the bandwidth of an AM signal is 10 kHz, insert a low pass filter allowing to select the station located around 710 kHz. Check that the filter is working properly on the graph. Insert the envelope detector at the output of the filter and a block <syntaxhighlight lang="text" inline>Rational Resampler</syntaxhighlight> to adapt the bit rate to the sound card (48 kHz) using an <syntaxhighlight lang="text" inline>Audio Sink</syntaxhighlight>.<br />
<br />
* Check the correct operation on the PC speakers (add if needed a <syntaxhighlight lang="text" inline>Multiply Const.</syntaxhighlight> block to set the volume of the station).<br />
<br />
* Bonus: Demodulate the station at 790 kHz.<br />
<br />
== Frequency Modulation ==<br />
<br />
Expression of a frequency modulated signal is given by:<br />
<br />
<math><br />
s(t) = A \cos(2\pi f_0 t + 2\pi k_f \int_0^t m(u) du)<br />
</math><br />
<br />
Spectrum for general signal is usually unknown unless for very simple cases.<br />
<br />
* Create the following flowgraph to generate a frequency (or phase) modulated signal.<br />
<br />
[[File:Fm1.png|frame|center|Fig. 4: Frequency modulation generation.]]<br />
<br />
* Observe the transmitted spectrum.<br />
<br />
* Find the values of the modulation index <math>\beta</math> to cancel the power at <math>f_0</math>, <math>f_0\pm f_m</math>, <math>f_0\pm 2f_m</math>...<br />
<br />
* Create a decoder for the transmitted signal. Check the correct operation for different messages <math>m(t)</math></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=SN424_Software_Defined_Radio&diff=568SN424 Software Defined Radio2026-01-08T10:53:11Z<p>Nico: </p>
<hr />
<div>The objective of this course is to understand how we can, with a Software Defined Radio, transmit a message in-between two transceivers spatially separated. Especially, how we can use signal processing operations to adapt (i.e. modulate and demodulate) or any operation normally done in the physical layer. This course describes the processes realized at a signal level and can be related to [[MA331 Information Theory and Channel Coding]] (which presents the general problem at a higher level).<br />
<br />
The following of this page corresponds to the labs.<br />
<br />
__TOC__<br />
<br />
In this labs, we will realize different modulations and demodulations used to transmit and receive analog and digital messages.<br />
Spectrum (or power spectral density) will also be determined.<br />
Finally, performance, in term of Sinal to Noise Ratio (SNR) or Bit Error Rate (BER) will be estimated in each case.<br />
<br />
These labs are based on [https://www.gnuradio.org/ GNU Radio] which is a free software that provides a large number of software blocks to perform most signal processing operations. The blocks are mostly written in C ++. It is possible to use these blocks directly from Python to simulate or create telecommunication systems.<br />
In addition, to make it easier to get started, GNU Radio also provides a utility called <syntaxhighlight lang="text" inline>gnuradio-companion</syntaxhighlight> to assemble blocks graphically and to generate the corresponding python script. This subject have been written for GNU Radio, but it can be equivalently realized using [https://www.gnu.org/software/octave/index Octave], or [http://itpp.sourceforge.net/4.3.1/ IT++] library.<br />
<br />
== Getting Started ==<br />
<br />
* Open a terminal.<br />
<br />
* Create a working directory in which you will place your scripts.<br />
<br />
* Run <syntaxhighlight lang="text" inline>gnuradio-companion</syntaxhighlight>.<br />
<br />
This software allows you to use blocks (available in the right column) and to connect them to realize any complex signal processing operations. Resulting program is called a flowgraph in GNU Radio language.<br />
<br />
For any flowgraph, there is basically 3 types of blocks: sources (which produce samples and have at least 1 output), sinks (which consume samples and have at least 1 input) and processing block (which have at least 1 input and 1 output). Blocks are simply connected by creating a link in-between an output of a block and an input of another block.<br />
<br />
* Create the flowgraph presented in Fig. 1.<br />
<br />
[[File:Im1.png|frame|center|Fig. 1: Simple generation and data plotting]]<br />
<br />
The topleft block <syntaxhighlight lang="text" inline>Options</syntaxhighlight> indicates the global options of the flowgraph. In this block, you can select the libraries used to generate the script (in this case the WX library, on the school computers, this library has the be replaced by the GTK library). The <syntaxhighlight lang="text" inline>Signal Source</syntaxhighlight> block generates an infinity of sinusoidal samples (or other) from the different parameters. These samples are displayed according to the time using the <syntaxhighlight lang="text" inline>Scope Sink</syntaxhighlight> block (on the school computers, this<br />
block has to be replaced by a <syntaxhighlight lang="text" inline>Time Sink</syntaxhighlight>. <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block does not modify the samples but allows to perform a flow control on all the data circulating between the source and the sink. Last, be careful to the color of the input and output of each block since they represent the type of data flowing on the link. The following table presents main data type and associated used by GNU Radio. Also, since Python is strongly typed, colors located at both ends of a wire have to be the same.<br />
<br />
{| class="wikitable" style="text-align: left;"<br />
|-<br />
!Color<br />
!Type<br />
!Size<br />
|-<br />
|style="background: #3399ff;"|<br />
|Complex<br />
|2 x 64 bits<br />
|-<br />
|style="background: #f57c00;"|<br />
|Float<br />
|64 bits<br />
|-<br />
|style="background: #009688;"|<br />
|Int<br />
|64/32 bits<br />
|-<br />
|style="background: #ffeb3b;"|<br />
|Short<br />
|16 bits<br />
|-<br />
|style="background: #d500f9;"|<br />
|Char<br />
|8 bits<br />
|}<br />
<br />
* Save the flowgraph under your directory. This file is saved with a <syntaxhighlight lang="text" inline>.grc</syntaxhighlight> extension.<br />
<br />
* Generate the associated Python script associated to your flowgraph using the "blue to red" button. If errors are present, the script is not generated and full listing is present under the no entry sign. When successful, observe the python script named <syntaxhighlight lang="text" inline>top_block.py</syntaxhighlight> in your directory.<br />
<br />
* Execute the script by pressing the run button. Equivalently, you can also invoke <syntaxhighlight lang="text" inline>python top_block.py</syntaxhighlight>.<br />
<br />
The execution should display an oscilloscope-like widow with the corresponding signal (a cosine function). You can stop the execution by closing the window or by pressing the stop button.<br />
<br />
* Check the amplitude and the period of the generated signal.<br />
<br />
* Add a <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> (on the school computers use a <syntaxhighlight lang="text" inline>Frequency Sink</syntaxhighlight>) to observe the signal spectrum. Place it in parallel of the <syntaxhighlight lang="text" inline>Scope Sink</syntaxhighlight> (or <syntaxhighlight lang="text" inline>Time Sink</syntaxhighlight>).<br />
<br />
* Add a <syntaxhighlight lang="text" inline>Slider</syntaxhighlight> block to modify the frequency of the signal in real time (without recompiling the flowgraph) and check the operation on the scope. Save the flowgraph.<br />
<br />
* Finally, observe the signal (in time and frequency) for a signal frequency lower and higher than 16 kHz. With your observations, redemonstrate Nyquist's theorem.<br />
<br />
Note that the source simply generates samples which are plotted by the sink, however, this source and this sink can produce and consume as much data that your CPU can handle (data are just generated and plotted iteratively as fast as possible). To overcome this issue, the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block is used to process a given number of sample per second, thus lowering the CPU load to few percents. Most of the blocks in GNU Radio do not fixed the rate at which samples are processed: when sufficient number of samples are present at the input, the considered function is called and produces samples at the output which are then available for the other blocks. Usually, this rate is fixed when we work with real devices (for example an audio card can acquire samples at a given frequency e.g. 48 kHz) which fixed the rate for the whole flowgraph. In our example, we do not use any real device so the rate has to be fixed using the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block. Also, for each flowgraph, a single rate has to be used thus if we work with a real device, the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block is not needed anymore and has to be removed.<br />
<br />
<br />
* Create the flowgraph presented in Fig. 2.<br />
<br />
[[File:Im2.png|frame|center|Fig. 2: Simple operations on signals]]<br />
<br />
* Add a <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> (on the school computers use a <syntaxhighlight lang="text" inline>Frequency Sink</syntaxhighlight>) to observe the signal spectrum. On the graph, the two peaks are very close and seem to be confused. Reduce the frequency sampling to increase the frequency resolution. Explain the phenomenum.<br />
<br />
* What is the minimum value of the sampling frequency? Observe the signal (in time and in frequency) for frequencies below this limit.<br />
<br />
* Replace the <syntaxhighlight lang="text" inline>Add</syntaxhighlight> block with a multiplier block <syntaxhighlight lang="text" inline>Mult</syntaxhighlight>. Predict the position of the peaks in the output signal. Check your results.<br />
<br />
* Add a filter (block <syntaxhighlight lang="text" inline>Low Pass Filter</syntaxhighlight>) to recover the low frequency part of the signal. Check your results in the time and frequency domain. Repeat the manipulation to keep the high frequency part.<br />
<br />
The <syntaxhighlight lang="text" inline>Low Pass Filter</syntaxhighlight> (and <syntaxhighlight lang="text" inline>High Pass Filter</syntaxhighlight>) blocks are high-level blocks which realize the design (i.e. determining the coefficients of the filter) as well as the filtering (i.e. the convolution). The filter design can also be done with <syntaxhighlight lang="text" inline>gr_filter_design</syntaxhighlight> to obtain the coefficients. These coefficients can then be used directly by the blocks <syntaxhighlight lang="text" inline>FIR Filter</syntaxhighlight> and <syntaxhighlight lang="text" inline>IIR Filter</syntaxhighlight>.<br />
<br />
== Amplitude Modulation ==<br />
<br />
=== Double side band without carrier ===<br />
<br />
* Realize the modulation of a signal <math>m(t)=\cos 2\pi f_m t</math> using a double side band without carrier. Note that transmitted signal can be expressed as<br />
<br />
<math><br />
s(t) = A m(t) \cos 2 \pi f_0 t<br />
</math><br />
<br />
* Observe the signal in both time and frequency domain.<br />
<br />
* Give the architecture of a coherent detector used to recover the message <math>m(t)</math> from <math>s(t)</math>.<br />
<br />
* Implement this detector to demodulate the signal and verify the good operation. You can use 2 different flowgraphs (1 for the transmission and 1 for the reception) using a <syntaxhighlight lang="text" inline>File Sink</syntaxhighlight> and <syntaxhighlight lang="text" inline>File Source</syntaxhighlight> respectively.<br />
<br />
=== Double side band with carrier ===<br />
<br />
* Realize the modulation of a signal <math>m(t)=\cos 2\pi f_m t</math> using a double side band with carrier. Note that transmitted signal can be expressed as<br />
<br />
[[File:Env.png|thumb|right|Fig. 3: Envelope detector used for AM signals.]]<br />
<br />
<math><br />
s(t) = A (1 + k_a m(t)) \cos 2 \pi f_0 t<br />
</math><br />
<br />
* Observe the signal in both time and frequency domain.<br />
<br />
* Modify the modulation index <math>k_a</math> using a slider and observe the modification of the signal.<br />
<br />
* AM signals are usually demodulted using a simple envelope detector. The architecture of this decoder is presented in Fig. 3.<br />
<br />
* Implement this detector to demodulate the signal and verify the good operation.<br />
<br />
* Check also if the AM signal can be decoded using the coherent detector.<br />
<br />
* Finally, download the file [https://nicolas-barbot.ovh/wiki/pool/am_usrp710.dat <syntaxhighlight lang="text" inline>am_usrp710.dat</syntaxhighlight>]. This file contains the complex envelope (I and Q channels) received by a USRP around the frequency 710 kHz with a sampling frequency of 256 kHz. Visualize the data with a block <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> (insert a block <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> to avoid overloading the processor). On the graph, we can see two stations transmit at 710 kHz (center) and 790 kHz (to the right). Knowing that the bandwidth of an AM signal is 10 kHz, insert a low pass filter allowing to select the station located around 710 kHz. Check that the filter is working properly on the graph. Insert the envelope detector at the output of the filter and a block <syntaxhighlight lang="text" inline>Rational Resampler</syntaxhighlight> to adapt the bit rate to the sound card (48 kHz) using an <syntaxhighlight lang="text" inline>Audio Sink</syntaxhighlight>.<br />
<br />
* Check the correct operation on the PC speakers (add if needed a <syntaxhighlight lang="text" inline>Multiply Const.</syntaxhighlight> block to set the volume of the station).<br />
<br />
* Bonus: Demodulate the station at 790 kHz.<br />
<br />
== Frequency Modulation ==<br />
<br />
Expression of a frequency modulated signal is given by:<br />
<br />
<math><br />
s(t) = A \cos(2\pi f_0 t + 2\pi k_f \int_0^t m(u) du)<br />
</math><br />
<br />
Spectrum for general signal is usually unknown unless for very simple cases.<br />
<br />
* Create the following flowgraph to generate a frequency (or phase) modulated signal.<br />
<br />
[[File:Fm1.png|frame|center|Fig. 4: Frequency modulation generation.]]<br />
<br />
* Observe the transmitted spectrum.<br />
<br />
* Find the values of the modulation index <math>\beta</math> to cancel the power at <math>f_0</math>, <math>f_0\pm f_m</math>, <math>f_0\pm 2f_m</math>...<br />
<br />
* Create a decoder for the transmitted signal. Check the correct operation for different messages <math>m(t)</math></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=SN424_Software_Defined_Radio&diff=567SN424 Software Defined Radio2026-01-08T10:42:32Z<p>Nico: </p>
<hr />
<div>The objective of this course is to understand how we can, with a Software Defined Radio, transmit a message in-between two transceivers spatially separated. Especially, how we can use signal processing operations to adapt (i.e. modulate and demodulate) or any operation normally done in the physical layer. This course describes the processes realized at a signal level and can be related to [[MA331 Information Theory and Channel Coding]] (which presents the general problem at a higher level).<br />
<br />
The following of this page corresponds to the labs.<br />
<br />
__TOC__<br />
<br />
In this labs, we will realize different modulations and demodulations used to transmit and receive analog and digital messages.<br />
Spectrum (or power spectral density) will also be determined.<br />
Finally, performance, in term of Sinal to Noise Ratio (SNR) or Bit Error Rate (BER) will be estimated in each case.<br />
<br />
These labs are based on [https://www.gnuradio.org/ GNU Radio] which is a free software that provides a large number of software blocks to perform most signal processing operations. The blocks are mostly written in C ++. It is possible to use these blocks directly from Python to simulate or create telecommunication systems.<br />
In addition, to make it easier to get started, GNU Radio also provides a utility called <syntaxhighlight lang="text" inline>gnuradio-companion</syntaxhighlight> to assemble blocks graphically and to generate the corresponding python script. This subject have been written for GNU Radio, but it can be equivalently realized using [https://www.gnu.org/software/octave/index Octave], or [http://itpp.sourceforge.net/4.3.1/ IT++] library.<br />
<br />
== Getting Started ==<br />
<br />
* Open a terminal.<br />
<br />
* Create a working directory in which you will place your scripts.<br />
<br />
* Run <syntaxhighlight lang="text" inline>gnuradio-companion</syntaxhighlight>.<br />
<br />
This software allows you to use blocks (available in the right column) and to connect them to realize any complex signal processing operations. Resulting program is called a flowgraph in GNU Radio language.<br />
<br />
For any flowgraph, there is basically 3 types of blocks: sources (which produce samples and have at least 1 output), sinks (which consume samples and have at least 1 input) and processing block (which have at least 1 input and 1 output). Blocks are simply connected by creating a link in-between an output of a block and an input of another block.<br />
<br />
* Create the flowgraph presented in Fig. 1.<br />
<br />
[[File:Im1.png|frame|center|Fig. 1: Simple generation and data plotting]]<br />
<br />
The topleft block <syntaxhighlight lang="text" inline>Options</syntaxhighlight> indicates the global options of the flowgraph. In this block, you can select the libraries used to generate the script (in this case the WX library, on the school computers, this library has the be replaced by the GTK library). The <syntaxhighlight lang="text" inline>Signal Source</syntaxhighlight> block generates an infinity of sinusoidal samples (or other) from the different parameters. These samples are displayed according to the time using the <syntaxhighlight lang="text" inline>Scope Sink</syntaxhighlight> block (on the school computers, this<br />
block has to be replaced by a <syntaxhighlight lang="text" inline>Time Sink</syntaxhighlight>. <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block does not modify the samples but allows to perform a flow control on all the data circulating between the source and the sink. Last, be careful to the color of the input and output of each block since they represent the type of data flowing on the link. The following table presents main data type and associated used by GNU Radio. Also, since Python is strongly typed, colors located at both ends of a wire have to be the same.<br />
<br />
{| class="wikitable" style="text-align: left;"<br />
|-<br />
!Color<br />
!Type<br />
!Size<br />
|-<br />
|style="background: #3399ff;"|<br />
|Complex<br />
|2 x 64 bits<br />
|-<br />
|style="background: #f57c00;"|<br />
|Float<br />
|64 bits<br />
|-<br />
|style="background: #009688;"|<br />
|Int<br />
|64/32 bits<br />
|-<br />
|style="background: #ffeb3b;"|<br />
|Short<br />
|16 bits<br />
|-<br />
|style="background: #d500f9;"|<br />
|Char<br />
|8 bits<br />
|}<br />
<br />
* Save the flowgraph under your directory. This file is saved with a <syntaxhighlight lang="text" inline>.grc</syntaxhighlight> extension.<br />
<br />
* Generate the associated Python script associated to your flowgraph using the "blue to red" button. If errors are present, the script is not generated and full listing is present under the no entry sign. When successful, observe the python script named <syntaxhighlight lang="text" inline>top_block.py</syntaxhighlight> in your directory.<br />
<br />
* Execute the script by pressing the run button. Equivalently, you can also invoke <syntaxhighlight lang="text" inline>python top_block.py</syntaxhighlight>.<br />
<br />
The execution should display an oscilloscope-like widow with the corresponding signal (a cosine function). You can stop the execution by closing the window or by pressing the stop button.<br />
<br />
* Check the amplitude and the period of the generated signal.<br />
<br />
* Finally, add a <syntaxhighlight lang="text" inline>Slider</syntaxhighlight> block to modify the frequency of the signal in real time (without recompiling the flowgraph) and check the operation on the scope. Save the flowgraph.<br />
<br />
Note that the source simply generates samples which are plotted by the sink, however, this source and this sink can produce and consume as much data that your CPU can handle (data are just generated and plotted iteratively as fast as possible). To overcome this issue, the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block is used to process a given number of sample per second, thus lowering the CPU load to few percents. Most of the blocks in GNU Radio do not fixed the rate at which samples are processed: when sufficient number of samples are present at the input, the considered function is called and produces samples at the output which are then available for the other blocks. Usually, this rate is fixed when we work with real devices (for example an audio card can acquire samples at a given frequency e.g. 48 kHz) which fixed the rate for the whole flowgraph. In our example, we do not use any real device so the rate has to be fixed using the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block. Also, for each flowgraph, a single rate has to be used thus if we work with a real device, the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block is not needed anymore and has to be removed.<br />
<br />
<br />
* Create the flowgraph presented in Fig. 2.<br />
<br />
[[File:Im2.png|frame|center|Fig. 2: Simple operations on signals]]<br />
<br />
* Add a <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> to observe the signal spectrum. On the graph, the two peaks are very close and seem to be confused. Reduce the frequency sampling to increase the frequency resolution. Explain the phenomenum.<br />
<br />
* What is the minimum value of the sampling frequency? Observe the signal (in time and in frequency) for frequencies below this limit.<br />
<br />
* Replace the <syntaxhighlight lang="text" inline>Add</syntaxhighlight> block with a multiplier block <syntaxhighlight lang="text" inline>Mult</syntaxhighlight>. Predict the position of the peaks in the output signal. Check your results.<br />
<br />
* Add a filter (block <syntaxhighlight lang="text" inline>Low Pass Filter</syntaxhighlight>) to recover the low frequency part of the signal. Check your results in the time and frequency domain. Repeat the manipulation to keep the high frequency part.<br />
<br />
The <syntaxhighlight lang="text" inline>Low Pass Filter</syntaxhighlight> (and <syntaxhighlight lang="text" inline>High Pass Filter</syntaxhighlight>) blocks are high-level blocks which realize the design (i.e. determining the coefficients of the filter) as well as the filtering (i.e. the convolution). The filter design can also be done with <syntaxhighlight lang="text" inline>gr_filter_design</syntaxhighlight> to obtain the coefficients. These coefficients can then be used directly by the blocks <syntaxhighlight lang="text" inline>FIR Filter</syntaxhighlight> and <syntaxhighlight lang="text" inline>IIR Filter</syntaxhighlight>.<br />
<br />
== Amplitude Modulation ==<br />
<br />
=== Double side band without carrier ===<br />
<br />
* Realize the modulation of a signal <math>m(t)=\cos 2\pi f_m t</math> using a double side band without carrier. Note that transmitted signal can be expressed as<br />
<br />
<math><br />
s(t) = A m(t) \cos 2 \pi f_0 t<br />
</math><br />
<br />
* Observe the signal in both time and frequency domain.<br />
<br />
* Give the architecture of a coherent detector used to recover the message <math>m(t)</math> from <math>s(t)</math>.<br />
<br />
* Implement this detector to demodulate the signal and verify the good operation. You can use 2 different flowgraphs (1 for the transmission and 1 for the reception) using a <syntaxhighlight lang="text" inline>File Sink</syntaxhighlight> and <syntaxhighlight lang="text" inline>File Source</syntaxhighlight> respectively.<br />
<br />
=== Double side band with carrier ===<br />
<br />
* Realize the modulation of a signal <math>m(t)=\cos 2\pi f_m t</math> using a double side band with carrier. Note that transmitted signal can be expressed as<br />
<br />
[[File:Env.png|thumb|right|Fig. 3: Envelope detector used for AM signals.]]<br />
<br />
<math><br />
s(t) = A (1 + k_a m(t)) \cos 2 \pi f_0 t<br />
</math><br />
<br />
* Observe the signal in both time and frequency domain.<br />
<br />
* Modify the modulation index <math>k_a</math> using a slider and observe the modification of the signal.<br />
<br />
* AM signals are usually demodulted using a simple envelope detector. The architecture of this decoder is presented in Fig. 3.<br />
<br />
* Implement this detector to demodulate the signal and verify the good operation.<br />
<br />
* Check also if the AM signal can be decoded using the coherent detector.<br />
<br />
* Finally, download the file [https://nicolas-barbot.ovh/wiki/pool/am_usrp710.dat <syntaxhighlight lang="text" inline>am_usrp710.dat</syntaxhighlight>]. This file contains the complex envelope (I and Q channels) received by a USRP around the frequency 710 kHz with a sampling frequency of 256 kHz. Visualize the data with a block <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> (insert a block <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> to avoid overloading the processor). On the graph, we can see two stations transmit at 710 kHz (center) and 790 kHz (to the right). Knowing that the bandwidth of an AM signal is 10 kHz, insert a low pass filter allowing to select the station located around 710 kHz. Check that the filter is working properly on the graph. Insert the envelope detector at the output of the filter and a block <syntaxhighlight lang="text" inline>Rational Resampler</syntaxhighlight> to adapt the bit rate to the sound card (48 kHz) using an <syntaxhighlight lang="text" inline>Audio Sink</syntaxhighlight>.<br />
<br />
* Check the correct operation on the PC speakers (add if needed a <syntaxhighlight lang="text" inline>Multiply Const.</syntaxhighlight> block to set the volume of the station).<br />
<br />
* Bonus: Demodulate the station at 790 kHz.<br />
<br />
== Frequency Modulation ==<br />
<br />
Expression of a frequency modulated signal is given by:<br />
<br />
<math><br />
s(t) = A \cos(2\pi f_0 t + 2\pi k_f \int_0^t m(u) du)<br />
</math><br />
<br />
Spectrum for general signal is usually unknown unless for very simple cases.<br />
<br />
* Create the following flowgraph to generate a frequency (or phase) modulated signal.<br />
<br />
[[File:Fm1.png|frame|center|Fig. 4: Frequency modulation generation.]]<br />
<br />
* Observe the transmitted spectrum.<br />
<br />
* Find the values of the modulation index <math>\beta</math> to cancel the power at <math>f_0</math>, <math>f_0\pm f_m</math>, <math>f_0\pm 2f_m</math>...<br />
<br />
* Create a decoder for the transmitted signal. Check the correct operation for different messages <math>m(t)</math></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=SN424_Software_Defined_Radio&diff=566SN424 Software Defined Radio2026-01-08T10:33:00Z<p>Nico: Created page with "The objective of this course is to understand how we can, with a Software Defined Radio, transmit a message in-between two transceivers spatially separated. Especially, how we..."</p>
<hr />
<div>The objective of this course is to understand how we can, with a Software Defined Radio, transmit a message in-between two transceivers spatially separated. Especially, how we can use signal processing operations to adapt (i.e. modulate and demodulate) or any operation normally done in the physical layer. This course describes the processes realized at a signal level and can be related to [[MA331 Information Theory and Channel Coding]] (which presents the general problem at a higher level).<br />
<br />
The following of this page corresponds to the labs.<br />
<br />
__TOC__<br />
<br />
In this labs, we will realize different modulations and demodulations used to transmit and receive analog and digital messages.<br />
Spectrum (or power spectral density) will also be determined.<br />
Finally, performance, in term of Sinal to Noise Ratio (SNR) or Bit Error Rate (BER) will be estimated in each case.<br />
<br />
These labs are based on [https://www.gnuradio.org/ GNU Radio] which is a free software that provides a large number of software blocks to perform most signal processing operations. The blocks are mostly written in C ++. It is possible to use these blocks directly from Python to simulate or create telecommunication systems.<br />
In addition, to make it easier to get started, GNU Radio also provides a utility called <syntaxhighlight lang="text" inline>gnuradio-companion</syntaxhighlight> to assemble blocks graphically and to generate the corresponding python script. This subject have been written for GNU Radio, but it can be equivalently realized using [https://www.gnu.org/software/octave/index Octave], or [http://itpp.sourceforge.net/4.3.1/ IT++] library.<br />
<br />
== Getting Started ==<br />
<br />
* Open a terminal.<br />
<br />
* Create a working directory in which you will place your scripts.<br />
<br />
* Run <syntaxhighlight lang="text" inline>gnuradio-companion</syntaxhighlight>.<br />
<br />
This software allows you to use blocks (available in the right column) and to connect them to realize any complex signal processing operations. Resulting program is called a flowgraph in GNU Radio language.<br />
<br />
For any flowgraph, there is basically 3 types of blocks: sources (which produce samples and have at least 1 output), sinks (which consume samples and have at least 1 input) and processing block (which have at least 1 input and 1 output). Blocks are simply connected by creating a link in-between an output of a block and an input of another block.<br />
<br />
* Create the flowgraph presented in Fig. 1.<br />
<br />
[[File:Im1.png|frame|center|Fig. 1: Simple generation and data plotting]]<br />
<br />
The <syntaxhighlight lang="text" inline>Signal Source</syntaxhighlight> block generates an infinity of sinusoidal samples (or other) from the different parameters. These samples are displayed according to the time using the <syntaxhighlight lang="text" inline>Scope Sink</syntaxhighlight> block. <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block does not modify the samples but allows to perform a flow control on all the data circulating between the source and the sink. Last, be careful to the color of the input and output of each block since they represent the type of data flowing on the link. The following table presents main data type and associated used by GNU Radio. Also, since Python is strongly typed, colors located at both ends of a wire have to be the same.<br />
<br />
{| class="wikitable" style="text-align: left;"<br />
|-<br />
!Color<br />
!Type<br />
!Size<br />
|-<br />
|style="background: #3399ff;"|<br />
|Complex<br />
|2 x 64 bits<br />
|-<br />
|style="background: #f57c00;"|<br />
|Float<br />
|64 bits<br />
|-<br />
|style="background: #009688;"|<br />
|Int<br />
|64/32 bits<br />
|-<br />
|style="background: #ffeb3b;"|<br />
|Short<br />
|16 bits<br />
|-<br />
|style="background: #d500f9;"|<br />
|Char<br />
|8 bits<br />
|}<br />
<br />
* Save the flowgraph under your directory. This file is saved with a <syntaxhighlight lang="text" inline>.grc</syntaxhighlight> extension.<br />
<br />
* Generate the associated Python script associated to your flowgraph using the "blue to red" button. If errors are present, the script is not generated and full listing is present under the no entry sign. When successful, observe the python script named <syntaxhighlight lang="text" inline>top_block.py</syntaxhighlight> in your directory.<br />
<br />
* Execute the script by pressing the run button. Equivalently, you can also invoke <syntaxhighlight lang="text" inline>python top_block.py</syntaxhighlight>.<br />
<br />
The execution should display an oscilloscope-like widow with the corresponding signal (a cosine function). You can stop the execution by closing the window or by pressing the stop button.<br />
<br />
* Check the amplitude and the period of the generated signal.<br />
<br />
* Finally, add a <syntaxhighlight lang="text" inline>Slider</syntaxhighlight> block to modify the frequency of the signal in real time (without recompiling the flowgraph) and check the operation on the scope. Save the flowgraph.<br />
<br />
Note that the source simply generates samples which are plotted by the sink, however, this source and this sink can produce and consume as much data that your CPU can handle (data are just generated and plotted iteratively as fast as possible). To overcome this issue, the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block is used to process a given number of sample per second, thus lowering the CPU load to few percents. Most of the blocks in GNU Radio do not fixed the rate at which samples are processed: when sufficient number of samples are present at the input, the considered function is called and produces samples at the output which are then available for the other blocks. Usually, this rate is fixed when we work with real devices (for example an audio card can acquire samples at a given frequency e.g. 48 kHz) which fixed the rate for the whole flowgraph. In our example, we do not use any real device so the rate has to be fixed using the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block. Also, for each flowgraph, a single rate has to be used thus if we work with a real device, the <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> block is not needed anymore and has to be removed.<br />
<br />
<br />
* Create the flowgraph presented in Fig. 2.<br />
<br />
[[File:Im2.png|frame|center|Fig. 2: Simple operations on signals]]<br />
<br />
* Add a <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> to observe the signal spectrum. On the graph, the two peaks are very close and seem to be confused. Reduce the frequency sampling to increase the frequency resolution. Explain the phenomenum.<br />
<br />
* What is the minimum value of the sampling frequency? Observe the signal (in time and in frequency) for frequencies below this limit.<br />
<br />
* Replace the <syntaxhighlight lang="text" inline>Add</syntaxhighlight> block with a multiplier block <syntaxhighlight lang="text" inline>Mult</syntaxhighlight>. Predict the position of the peaks in the output signal. Check your results.<br />
<br />
* Add a filter (block <syntaxhighlight lang="text" inline>Low Pass Filter</syntaxhighlight>) to recover the low frequency part of the signal. Check your results in the time and frequency domain. Repeat the manipulation to keep the high frequency part.<br />
<br />
The <syntaxhighlight lang="text" inline>Low Pass Filter</syntaxhighlight> (and <syntaxhighlight lang="text" inline>High Pass Filter</syntaxhighlight>) blocks are high-level blocks which realize the design (i.e. determining the coefficients of the filter) as well as the filtering (i.e. the convolution). The filter design can also be done with <syntaxhighlight lang="text" inline>gr_filter_design</syntaxhighlight> to obtain the coefficients. These coefficients can then be used directly by the blocks <syntaxhighlight lang="text" inline>FIR Filter</syntaxhighlight> and <syntaxhighlight lang="text" inline>IIR Filter</syntaxhighlight>.<br />
<br />
== Amplitude Modulation ==<br />
<br />
=== Double side band without carrier ===<br />
<br />
* Realize the modulation of a signal <math>m(t)=\cos 2\pi f_m t</math> using a double side band without carrier. Note that transmitted signal can be expressed as<br />
<br />
<math><br />
s(t) = A m(t) \cos 2 \pi f_0 t<br />
</math><br />
<br />
* Observe the signal in both time and frequency domain.<br />
<br />
* Give the architecture of a coherent detector used to recover the message <math>m(t)</math> from <math>s(t)</math>.<br />
<br />
* Implement this detector to demodulate the signal and verify the good operation. You can use 2 different flowgraphs (1 for the transmission and 1 for the reception) using a <syntaxhighlight lang="text" inline>File Sink</syntaxhighlight> and <syntaxhighlight lang="text" inline>File Source</syntaxhighlight> respectively.<br />
<br />
=== Double side band with carrier ===<br />
<br />
* Realize the modulation of a signal <math>m(t)=\cos 2\pi f_m t</math> using a double side band with carrier. Note that transmitted signal can be expressed as<br />
<br />
[[File:Env.png|thumb|right|Fig. 3: Envelope detector used for AM signals.]]<br />
<br />
<math><br />
s(t) = A (1 + k_a m(t)) \cos 2 \pi f_0 t<br />
</math><br />
<br />
* Observe the signal in both time and frequency domain.<br />
<br />
* Modify the modulation index <math>k_a</math> using a slider and observe the modification of the signal.<br />
<br />
* AM signals are usually demodulted using a simple envelope detector. The architecture of this decoder is presented in Fig. 3.<br />
<br />
* Implement this detector to demodulate the signal and verify the good operation.<br />
<br />
* Check also if the AM signal can be decoded using the coherent detector.<br />
<br />
* Finally, download the file [https://nicolas-barbot.ovh/wiki/pool/am_usrp710.dat <syntaxhighlight lang="text" inline>am_usrp710.dat</syntaxhighlight>]. This file contains the complex envelope (I and Q channels) received by a USRP around the frequency 710 kHz with a sampling frequency of 256 kHz. Visualize the data with a block <syntaxhighlight lang="text" inline>FFT Sink</syntaxhighlight> (insert a block <syntaxhighlight lang="text" inline>Throttle</syntaxhighlight> to avoid overloading the processor). On the graph, we can see two stations transmit at 710 kHz (center) and 790 kHz (to the right). Knowing that the bandwidth of an AM signal is 10 kHz, insert a low pass filter allowing to select the station located around 710 kHz. Check that the filter is working properly on the graph. Insert the envelope detector at the output of the filter and a block <syntaxhighlight lang="text" inline>Rational Resampler</syntaxhighlight> to adapt the bit rate to the sound card (48 kHz) using an <syntaxhighlight lang="text" inline>Audio Sink</syntaxhighlight>.<br />
<br />
* Check the correct operation on the PC speakers (add if needed a <syntaxhighlight lang="text" inline>Multiply Const.</syntaxhighlight> block to set the volume of the station).<br />
<br />
* Bonus: Demodulate the station at 790 kHz.<br />
<br />
== Frequency Modulation ==<br />
<br />
Expression of a frequency modulated signal is given by:<br />
<br />
<math><br />
s(t) = A \cos(2\pi f_0 t + 2\pi k_f \int_0^t m(u) du)<br />
</math><br />
<br />
Spectrum for general signal is usually unknown unless for very simple cases.<br />
<br />
* Create the following flowgraph to generate a frequency (or phase) modulated signal.<br />
<br />
[[File:Fm1.png|frame|center|Fig. 4: Frequency modulation generation.]]<br />
<br />
* Observe the transmitted spectrum.<br />
<br />
* Find the values of the modulation index <math>\beta</math> to cancel the power at <math>f_0</math>, <math>f_0\pm f_m</math>, <math>f_0\pm 2f_m</math>...<br />
<br />
* Create a decoder for the transmitted signal. Check the correct operation for different messages <math>m(t)</math></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Nicolas_Barbot&diff=565Nicolas Barbot2026-01-08T10:24:42Z<p>Nico: </p>
<hr />
<div>{{Infobox person<br />
| name = Nicolas Barbot<br />
| image = File:NBarbot.jpg<br />
| image_size = 220px<br />
| nationality = French<br />
| birth_date = {{Birth date and age|1986|08|11}}<br />
| birth_place = Limoges, France<br />
}}<br />
<br />
'''Nicolas Barbot''' received the M.Sc. degree and Ph.D. degree from the University de Limoges, France in 2010 and 2013 respectively. His Ph.D. work in [https://www.xlim.fr/ Xlim] Laboratory was focused on error-correcting codes for the optical wireless channel. He also completed a post-doctoral work in joint source-channel decoding at [https://l2s.centralesupelec.fr/ L2S] Laboratory, in Gif-sur-Yvette, France. Since September 2014, he has been an Associate Professor at the Université Grenoble Alpes - Grenoble Institute of Technology, in Valence, France. His scientific background at [https://lcis.grenoble-inp.fr/ LCIS] Laboratory covers wireless communications systems based on backscattering principle which include classical RFID and chipless RFID.<br />
<br />
His research interests include transponders which can not be described by linear time-invariant systems. This gathers harmonic transponders which are based on the use of a non-linear component (Schottky diode) or linear time-variant transponders which are based on the modification of their response in the time domain.<br />
He also places special interests on antenna design and instrumentation based on these phenomena.<br />
<br />
==Education==<br />
<br />
{| class="wikitable" style="text-align: left;width: 80%;"<br />
|-<br />
!Period<br />
!Postion/Diploma<br />
|-<br />
|2023<br />
|align=left|HDR, Linear Time-Variant and Non-Linear Transponders for Identification and Sensing Applications, Valence, France<br />
|-<br />
|2014–2021<br />
|align=left|Assistant Professor at Grenoble INP - Esisar, LCIS, Valence, France<br />
|-<br />
|2013–2014<br />
|align=left|Post-Doc at Laboratoire des Signaux et Systèmes (L2S), ''Cross-Layer Design of Wireless Tranceivers'', Gif-sur-Yvette, France<br />
|-<br />
|2010–2013<br />
|align=left|PhD Thesis, Xlim CNRS UMR 7252, ''Channel Coding for Optical Wireless Communications'', Limoges, France<br />
|-<br />
|2009–2010<br />
|align=left|Master Degree, Faculté des Sciences, ''Technologies Hyperfréquences, Électronique et Optique'', Limoges, France<br />
|-<br />
|2007–2010<br />
|align=left|Diplome d'ingénieur, École Nationale Supérieure d’Ingénieurs de Limoges, Électronique et Télécommunications, Limoges, France<br />
|-<br />
|2005–2007<br />
|align=left|DUT Mesures Physiques, IUT du Limousin, Limoges, France<br />
|}<br />
<br />
==Teaching ==<br />
<br />
{| class="wikitable" style="text-align: left;width: 80%;"<br />
|-<br />
!Courses<br />
!Full name<br />
!Grade<br />
!ECTS<br />
|-<br />
|[[CE515 Advanced Processor Architecture and SoC Design|CE515]]<br />
|align=left|Advanced Processor Architecture and SoC Design<br />
|5A<br />
|4<br />
|-<br />
|[[PX505 Innovation Project|PX505]]<br />
|align=left|Innovation Project<br />
|5A<br />
|4<br />
|-<br />
|[[AC469 Introduction to statistical signal processing|AC469]]<br />
|align=left|Introduction to statistical signal processing<br />
|4App<br />
|1.5<br />
|-<br />
|[[SN420 Software Defined Radio|SN420]]<br />
|align=left|Software Defined Radio<br />
|4A<br />
|2.5<br />
|-<br />
|[[MA331 Information Theory and Channel Coding|MA331]]<br />
|align=left|Information Theory and Channel Coding<br />
|3A<br />
|3<br />
|-<br />
|[[PX302 Introduction to STM32 micro-controllers|PX302]]<br />
|align=left|Introduction to STM32 micro-controllers<br />
|3A<br />
|3<br />
|-<br />
|[[PX212 Mini-Project|PX212]]<br />
|align=left|Mini-Project<br />
|2A<br />
|6<br />
|}<br />
<br />
==Research Activities==<br />
<br />
In the first part of my career, my research activities have been focused on chipless RFID.<br />
This technology allows one to reduce the cost of the tags since information can be embedded and transmitted to the reader<br />
without using a silicon chip. However, since these tags are Linear Time-Invariant (LTI) systems<br />
<ref>N. Barbot, O. Rance, and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/range.pdf "Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?,"]<br />
IEEE Transactions on Microwave Theory and Techniques, vol. 69, no. 9, pp. 4199-4208, Sept. 2021.</ref>, their backscattered power<br />
are also located in the same bandwidth as the one used by the reader making the reading difficult in non-free space environments.<br />
Consequently, significant limitations appears in term of read range, coding capacity and media access control for any chipless tag.<br />
In order to break these limitations, my research investigations now cover:<br />
* non-linear (or harmonic) transponders which can backscatter a power at <math>n f_0</math>. These transponders are base on a non-linear component (typically a Schottky diode).<br />
* linear time-variant transponders which can backscatter a power around <math>f_0</math> <ref>N. Barbot and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/nl.pdf "Linear time-variant chipless RFID sensor,"] IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022.</ref>. These transponders can modulate the backscattered signal (classical UHF tags, micro-Doppler or more generally any moving scatterers).<br />
<br />
In these two cases, the tags cannot be described by LTI systems and are not bounded by the previous limitations. They<br />
are also characterized by a non zero [[Differential RCS|delta RCS]] <math>\sigma_d</math><ref>N. Barbot, O. Rance, and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/rcs.pdf "Differential RCS of modulated tag,"] IEEE Transactions on Antennas and Propagation, vol. 69, no. 9, pp. 6128-6133, Sept. 2021.</ref>.<br />
<br />
Additional details can be found [[Research Activities|here]].<br />
<br />
PhD students:<br />
* '''Meng Yang''', "Non-linear Transponders for Identification and Sensing Applications," Directeur: Nicolas Barbot.<br />
<br />
* '''Ashkan Azarfar''', "Détection de tags sans puce basée sur l'effet Doppler pour les applications de reconnaissance de gestes," Directeur: Etienne Perret, Co-directeur: Nicolas Barbot.<br />
<br />
* '''Florian Requena''', "Conception de tags RIFD sans puce, robustes, pour applications capteur," Directeur: Etienne Perret, Co-directeur: Darine Kaddour, Nicolas Barbot.<br />
<br />
* '''Raymundo de Amorim Junior''', "Tags sans puce millimétriques pour applications sécurisées," Directeur: Etienne Perret, Co-directeur: Romain Siragusa, Nicolas Barbot.<br />
<br />
* '''Rahul Unnikrishnan''', "Reconnaissance de gestes avec des tags chipless," Directeur: Etienne Perret, Co-directeur: Nicolas Barbot.<br />
<br />
* '''Raphael Tavares de Alencar''', "Contribution à la conception et la réalisation de tags RFID sans puce compatibles avec des procédés industriels de fabrication," Directeur: Etienne Perret, Co-directeur: Marco Garbati, Nicolas Barbot.<br />
<br />
* '''Florent Bonnefoy''', "Authentification dans le domaine THz," Directeur: Frédéric Garet, Co-directeur: Maxime Bernier, Nicolas Barbot.<br />
<br />
See the complete [[List of Publications]].<br />
<br />
==CV==<br />
<br />
[https://nicolas-barbot.ovh/wiki/pool/cv_en.pdf English Version]<br />
<br />
[https://nicolas-barbot.ovh/wiki/pool/cv.pdf French Version]<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
==External links==<br />
[https://scholar.google.com/citations?user=mMhPOZYAAAAJ&hl=en&oi=ao Google Scholar]<br />
<br />
[https://orcid.org/0000-0001-6355-9109 ORCID ID]</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=564Simple Low Cost Open Source UHF RFID Reader2025-09-01T14:44:46Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 of the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obsolete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1.0''' RF signal generation is based on the Melexis chip (obsolete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1.1''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Output power is around -4 dBm. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1.2''' RF signal generation is based on the Atmel ATA8403 chip. A Power Amplifier based on a SKY65162-70LF chip has been added to increase the output power to 13 dBm. Tx and Rx paths were connected using a power divider.<br />
<br />
<gallery widths=230px><br />
File:version0a.jpg|Version 0a<br />
File:version0b.jpg|Version 0b<br />
File:version1a.jpg|Version 1<math>\alpha</math><br />
File:version1a2.jpg|Version 1.0<br />
</gallery><br />
<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
'''Tag platform''' This board emulate a (basic) UHF RFID tag<ref>N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83</ref>. A modular architecture has been adopted to easily prototype the design. Firmware is also available on a [https://github.com/nicolas-barbot/SDR_UHF_RFID_tag Github repository]<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=563List of Publications2025-07-05T11:23:13Z<p>Nico: </p>
<hr />
<div>__FORCETOC__<br />
<br />
==Journal Articles==<br />
*N. Barbot and M. Reynolds, "A General Receiver for Backscatter Signals," in IEEE Microwave Magazine, in press<br />
<br />
*N. Barbot, I. Prodan and P. Nikitin, "Differential RCS of Multi-Port Tag Antenna With Synchronous Modulated Backscatter," in IEEE Journal of Radio Frequency Identification, early access.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Real-Time Hand Motion-Modulated Chipless RFID With Gesture Recognition Capability," in IEEE Transactions on Microwave Theory and Techniques, vol. 73, no. 1, pp. 383-396, Jan. 2025<br />
<br />
*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, vol. 8, pp. 145-153, 2024.<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop". Scientific Report 12, 22032 (2022).<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
<br />
*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023. '''IEEE CRFID James Clerk Maxwell Best Journal Paper Award 2024'''<br />
<br />
*F. Requena, S. Ahoulou, N. Barbot, D. Kaddour, J.-M. Nedelec, T. Baron and E. Perret "Towards Wireless Detection of Surface Modification of Silicon Nanowires by an RF Approach," Nanomaterials, 12(23), 4237, 2022 <br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
<br />
*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comments on “Development of Cross-Polar Orientation-Insensitive Chipless RFID Tags”," in IEEE Transactions on Antennas and Propagation, vol. 70, no. 5, pp. 3922-3923, May 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
<br />
*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” in IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022. <br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
<br />
*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
<br />
*F.Bonnefoy, M. Bernier, E. Perret, N. Barbot, R. Siragusa, D. Hely, E. Kato, F. Garet "Video-Rate Identification of High-Capacity Low-Cost Tags in the Terahertz Domain," Sensors, 21(11):3692 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021. doi: 10.1109/TAP.2021.3060126.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
<br />
*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim Jr., N. Barbot, R. Siragusa, E. Perret and F. Popescu "A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches," Sensors. 20(21):6385, 2020.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
<br />
*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
<br />
*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
<br />
*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
<br />
*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
<br />
==International Conferences==<br />
*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
<br />
*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
<br />
*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
<br />
*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
<br />
*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
<br />
*N. Barbot and V. C. V, "Open Testing and Measurement Bench for UHF RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 158-161.<br />
<br />
*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
<br />
*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
<br />
*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
<br />
*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF RFID tags: HRFID project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
<br />
*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
<br />
*Z. Ali, N. Barbot and E. Perret, "Gesture Recognition Using Chipless RFID Tag Held in Hand," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 40-43.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Vibration Sensing using Doppler-modulated Chipless RFID Tags," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 129-132.<br />
<br />
*N. Barbot and S. Tedjini, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, D. Allane and S. Tedjini, “Orientation Sensor Based on Harmonic Transponder,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comparison between Cross-polarization and Circular Polarization Interrogation for Robust Chipless RFID Reading," 2021 51st European Microwave Conference (EuMC), London, United Kingdom, 2022, pp. 668-671.<br />
<br />
*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
<br />
*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
<br />
*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
<br />
*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
<br />
*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
<br />
*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
<br />
*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
<br />
*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
<br />
*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
<br />
*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
<br />
*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
<br />
*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
<br />
*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
<br />
==National Conferences==<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
<br />
*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
<br />
*O. Rance, Z. Ali, N. Barbot, E. Perret, "Diffuseur dépolarisant invariant par rotation", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Capteur chipless basé sur la modulation de polarisation", Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Distance de lecture en technologie RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, "RCS différentiel de tags modulés", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, "Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Capteur RFID sans puce de température et d’humidité", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
<br />
*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
<br />
*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Nicolas_Barbot&diff=562Nicolas Barbot2025-04-07T14:21:02Z<p>Nico: </p>
<hr />
<div>{{Infobox person<br />
| name = Nicolas Barbot<br />
| image = File:NBarbot.jpg<br />
| image_size = 220px<br />
| nationality = French<br />
| birth_date = {{Birth date and age|1986|08|11}}<br />
| birth_place = Limoges, France<br />
}}<br />
<br />
'''Nicolas Barbot''' received the M.Sc. degree and Ph.D. degree from the University de Limoges, France in 2010 and 2013 respectively. His Ph.D. work in [https://www.xlim.fr/ Xlim] Laboratory was focused on error-correcting codes for the optical wireless channel. He also completed a post-doctoral work in joint source-channel decoding at [https://l2s.centralesupelec.fr/ L2S] Laboratory, in Gif-sur-Yvette, France. Since September 2014, he has been an Associate Professor at the Université Grenoble Alpes - Grenoble Institute of Technology, in Valence, France. His scientific background at [https://lcis.grenoble-inp.fr/ LCIS] Laboratory covers wireless communications systems based on backscattering principle which include classical RFID and chipless RFID.<br />
<br />
His research interests include transponders which can not be described by linear time-invariant systems. This gathers harmonic transponders which are based on the use of a non-linear component (Schottky diode) or linear time-variant transponders which are based on the modification of their response in the time domain.<br />
He also places special interests on antenna design and instrumentation based on these phenomena.<br />
<br />
==Education==<br />
<br />
{| class="wikitable" style="text-align: left;width: 80%;"<br />
|-<br />
!Period<br />
!Postion/Diploma<br />
|-<br />
|2023<br />
|align=left|HDR, Linear Time-Variant and Non-Linear Transponders for Identification and Sensing Applications, Valence, France<br />
|-<br />
|2014–2021<br />
|align=left|Assistant Professor at Grenoble INP - Esisar, LCIS, Valence, France<br />
|-<br />
|2013–2014<br />
|align=left|Post-Doc at Laboratoire des Signaux et Systèmes (L2S), ''Cross-Layer Design of Wireless Tranceivers'', Gif-sur-Yvette, France<br />
|-<br />
|2010–2013<br />
|align=left|PhD Thesis, Xlim CNRS UMR 7252, ''Channel Coding for Optical Wireless Communications'', Limoges, France<br />
|-<br />
|2009–2010<br />
|align=left|Master Degree, Faculté des Sciences, ''Technologies Hyperfréquences, Électronique et Optique'', Limoges, France<br />
|-<br />
|2007–2010<br />
|align=left|Diplome d'ingénieur, École Nationale Supérieure d’Ingénieurs de Limoges, Électronique et Télécommunications, Limoges, France<br />
|-<br />
|2005–2007<br />
|align=left|DUT Mesures Physiques, IUT du Limousin, Limoges, France<br />
|}<br />
<br />
==Teaching ==<br />
<br />
{| class="wikitable" style="text-align: left;width: 80%;"<br />
|-<br />
!Courses<br />
!Full name<br />
!Grade<br />
!ECTS<br />
|-<br />
|[[CE515 Advanced Processor Architecture and SoC Design|CE515]]<br />
|align=left|Advanced Processor Architecture and SoC Design<br />
|5A<br />
|4<br />
|-<br />
|[[PX505 Innovation Project|PX505]]<br />
|align=left|Innovation Project<br />
|5A<br />
|4<br />
|-<br />
|[[AC469 Introduction to statistical signal processing|AC469]]<br />
|align=left|Introduction to statistical signal processing<br />
|4App<br />
|1.5<br />
|-<br />
|[[SC311 Wireless Communications|SC311]]<br />
|align=left|Wireless Communications<br />
|3A<br />
|2.5<br />
|-<br />
|[[MA331 Information Theory and Channel Coding|MA331]]<br />
|align=left|Information Theory and Channel Coding<br />
|3A<br />
|3<br />
|-<br />
|[[PX302 Introduction to STM32 micro-controllers|PX302]]<br />
|align=left|Introduction to STM32 micro-controllers<br />
|3A<br />
|3<br />
|-<br />
|[[PX212 Mini-Project|PX212]]<br />
|align=left|Mini-Project<br />
|2A<br />
|6<br />
|}<br />
<br />
==Research Activities==<br />
<br />
In the first part of my career, my research activities have been focused on chipless RFID.<br />
This technology allows one to reduce the cost of the tags since information can be embedded and transmitted to the reader<br />
without using a silicon chip. However, since these tags are Linear Time-Invariant (LTI) systems<br />
<ref>N. Barbot, O. Rance, and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/range.pdf "Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?,"]<br />
IEEE Transactions on Microwave Theory and Techniques, vol. 69, no. 9, pp. 4199-4208, Sept. 2021.</ref>, their backscattered power<br />
are also located in the same bandwidth as the one used by the reader making the reading difficult in non-free space environments.<br />
Consequently, significant limitations appears in term of read range, coding capacity and media access control for any chipless tag.<br />
In order to break these limitations, my research investigations now cover:<br />
* non-linear (or harmonic) transponders which can backscatter a power at <math>n f_0</math>. These transponders are base on a non-linear component (typically a Schottky diode).<br />
* linear time-variant transponders which can backscatter a power around <math>f_0</math> <ref>N. Barbot and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/nl.pdf "Linear time-variant chipless RFID sensor,"] IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022.</ref>. These transponders can modulate the backscattered signal (classical UHF tags, micro-Doppler or more generally any moving scatterers).<br />
<br />
In these two cases, the tags cannot be described by LTI systems and are not bounded by the previous limitations. They<br />
are also characterized by a non zero [[Differential RCS|delta RCS]] <math>\sigma_d</math><ref>N. Barbot, O. Rance, and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/rcs.pdf "Differential RCS of modulated tag,"] IEEE Transactions on Antennas and Propagation, vol. 69, no. 9, pp. 6128-6133, Sept. 2021.</ref>.<br />
<br />
Additional details can be found [[Research Activities|here]].<br />
<br />
PhD students:<br />
* '''Meng Yang''', "Non-linear Transponders for Identification and Sensing Applications," Directeur: Nicolas Barbot.<br />
<br />
* '''Ashkan Azarfar''', "Détection de tags sans puce basée sur l'effet Doppler pour les applications de reconnaissance de gestes," Directeur: Etienne Perret, Co-directeur: Nicolas Barbot.<br />
<br />
* '''Florian Requena''', "Conception de tags RIFD sans puce, robustes, pour applications capteur," Directeur: Etienne Perret, Co-directeur: Darine Kaddour, Nicolas Barbot.<br />
<br />
* '''Raymundo de Amorim Junior''', "Tags sans puce millimétriques pour applications sécurisées," Directeur: Etienne Perret, Co-directeur: Romain Siragusa, Nicolas Barbot.<br />
<br />
* '''Rahul Unnikrishnan''', "Reconnaissance de gestes avec des tags chipless," Directeur: Etienne Perret, Co-directeur: Nicolas Barbot.<br />
<br />
* '''Raphael Tavares de Alencar''', "Contribution à la conception et la réalisation de tags RFID sans puce compatibles avec des procédés industriels de fabrication," Directeur: Etienne Perret, Co-directeur: Marco Garbati, Nicolas Barbot.<br />
<br />
* '''Florent Bonnefoy''', "Authentification dans le domaine THz," Directeur: Frédéric Garet, Co-directeur: Maxime Bernier, Nicolas Barbot.<br />
<br />
See the complete [[List of Publications]].<br />
<br />
==CV==<br />
<br />
[https://nicolas-barbot.ovh/wiki/pool/cv_en.pdf English Version]<br />
<br />
[https://nicolas-barbot.ovh/wiki/pool/cv.pdf French Version]<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
==External links==<br />
[https://scholar.google.com/citations?user=mMhPOZYAAAAJ&hl=en&oi=ao Google Scholar]<br />
<br />
[https://orcid.org/0000-0001-6355-9109 ORCID ID]</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=561List of Publications2025-04-07T14:20:00Z<p>Nico: </p>
<hr />
<div>__FORCETOC__<br />
<br />
==Journal Articles==<br />
*N. Barbot, I. Prodan and P. Nikitin, "Differential RCS of Multi-Port Tag Antenna With Synchronous Modulated Backscatter," in IEEE Journal of Radio Frequency Identification, early access.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Real-Time Hand Motion-Modulated Chipless RFID With Gesture Recognition Capability," in IEEE Transactions on Microwave Theory and Techniques, vol. 73, no. 1, pp. 383-396, Jan. 2025<br />
<br />
*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, vol. 8, pp. 145-153, 2024.<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop". Scientific Report 12, 22032 (2022).<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
<br />
*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023. '''IEEE CRFID James Clerk Maxwell Best Journal Paper Award 2024'''<br />
<br />
*F. Requena, S. Ahoulou, N. Barbot, D. Kaddour, J.-M. Nedelec, T. Baron and E. Perret "Towards Wireless Detection of Surface Modification of Silicon Nanowires by an RF Approach," Nanomaterials, 12(23), 4237, 2022 <br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
<br />
*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comments on “Development of Cross-Polar Orientation-Insensitive Chipless RFID Tags”," in IEEE Transactions on Antennas and Propagation, vol. 70, no. 5, pp. 3922-3923, May 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
<br />
*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” in IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022. <br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
<br />
*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
<br />
*F.Bonnefoy, M. Bernier, E. Perret, N. Barbot, R. Siragusa, D. Hely, E. Kato, F. Garet "Video-Rate Identification of High-Capacity Low-Cost Tags in the Terahertz Domain," Sensors, 21(11):3692 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021. doi: 10.1109/TAP.2021.3060126.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
<br />
*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim Jr., N. Barbot, R. Siragusa, E. Perret and F. Popescu "A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches," Sensors. 20(21):6385, 2020.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
<br />
*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
<br />
*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
<br />
*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
<br />
*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
<br />
==International Conferences==<br />
*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
<br />
*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
<br />
*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
<br />
*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
<br />
*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
<br />
*N. Barbot and V. C. V, "Open Testing and Measurement Bench for UHF RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 158-161.<br />
<br />
*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
<br />
*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
<br />
*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
<br />
*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF RFID tags: HRFID project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
<br />
*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
<br />
*Z. Ali, N. Barbot and E. Perret, "Gesture Recognition Using Chipless RFID Tag Held in Hand," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 40-43.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Vibration Sensing using Doppler-modulated Chipless RFID Tags," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 129-132.<br />
<br />
*N. Barbot and S. Tedjini, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, D. Allane and S. Tedjini, “Orientation Sensor Based on Harmonic Transponder,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comparison between Cross-polarization and Circular Polarization Interrogation for Robust Chipless RFID Reading," 2021 51st European Microwave Conference (EuMC), London, United Kingdom, 2022, pp. 668-671.<br />
<br />
*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
<br />
*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
<br />
*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
<br />
*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
<br />
*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
<br />
*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
<br />
*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
<br />
*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
<br />
*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
<br />
*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
<br />
*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
<br />
*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
<br />
*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
<br />
==National Conferences==<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
<br />
*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
<br />
*O. Rance, Z. Ali, N. Barbot, E. Perret, "Diffuseur dépolarisant invariant par rotation", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Capteur chipless basé sur la modulation de polarisation", Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Distance de lecture en technologie RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, "RCS différentiel de tags modulés", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, "Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Capteur RFID sans puce de température et d’humidité", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
<br />
*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
<br />
*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=560List of Publications2025-03-15T12:34:45Z<p>Nico: </p>
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<div>__FORCETOC__<br />
<br />
==Journal Articles==<br />
*A. Azarfar, N. Barbot and E. Perret, "Real-Time Hand Motion-Modulated Chipless RFID With Gesture Recognition Capability," in IEEE Transactions on Microwave Theory and Techniques, vol. 73, no. 1, pp. 383-396, Jan. 2025<br />
<br />
*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, vol. 8, pp. 145-153, 2024.<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop". Scientific Report 12, 22032 (2022).<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
<br />
*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023. '''IEEE CRFID James Clerk Maxwell Best Journal Paper Award 2024'''<br />
<br />
*F. Requena, S. Ahoulou, N. Barbot, D. Kaddour, J.-M. Nedelec, T. Baron and E. Perret "Towards Wireless Detection of Surface Modification of Silicon Nanowires by an RF Approach," Nanomaterials, 12(23), 4237, 2022 <br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
<br />
*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comments on “Development of Cross-Polar Orientation-Insensitive Chipless RFID Tags”," in IEEE Transactions on Antennas and Propagation, vol. 70, no. 5, pp. 3922-3923, May 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
<br />
*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” in IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022. <br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
<br />
*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
<br />
*F.Bonnefoy, M. Bernier, E. Perret, N. Barbot, R. Siragusa, D. Hely, E. Kato, F. Garet "Video-Rate Identification of High-Capacity Low-Cost Tags in the Terahertz Domain," Sensors, 21(11):3692 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021. doi: 10.1109/TAP.2021.3060126.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
<br />
*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim Jr., N. Barbot, R. Siragusa, E. Perret and F. Popescu "A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches," Sensors. 20(21):6385, 2020.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
<br />
*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
<br />
*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
<br />
*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
<br />
*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
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*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
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==International Conferences==<br />
*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
<br />
*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
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*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
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*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
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*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
<br />
*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
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*N. Barbot and V. C. V, "Open Testing and Measurement Bench for UHF RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 158-161.<br />
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*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
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*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
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*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
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*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
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*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
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*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF RFID tags: HRFID project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
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*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
<br />
*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
<br />
*Z. Ali, N. Barbot and E. Perret, "Gesture Recognition Using Chipless RFID Tag Held in Hand," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 40-43.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Vibration Sensing using Doppler-modulated Chipless RFID Tags," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 129-132.<br />
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*N. Barbot and S. Tedjini, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
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*N. Barbot, D. Allane and S. Tedjini, “Orientation Sensor Based on Harmonic Transponder,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
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*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comparison between Cross-polarization and Circular Polarization Interrogation for Robust Chipless RFID Reading," 2021 51st European Microwave Conference (EuMC), London, United Kingdom, 2022, pp. 668-671.<br />
<br />
*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''.<br />
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*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
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*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
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*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
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*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
<br />
*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
<br />
*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
<br />
*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
<br />
*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
<br />
*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
<br />
*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
<br />
*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
<br />
*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
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*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
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*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
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*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
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*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
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*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
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*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
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*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
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*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
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*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
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==National Conferences==<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
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*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
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*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
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*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
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*O. Rance, Z. Ali, N. Barbot, E. Perret, "Diffuseur dépolarisant invariant par rotation", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*N. Barbot and E. Perret, "Capteur chipless basé sur la modulation de polarisation", Limoges, France, Jun. 2022.<br />
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*N. Barbot and E. Perret, "Distance de lecture en technologie RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*N. Barbot, O. Rance, and E. Perret, "RCS différentiel de tags modulés", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, "Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Capteur RFID sans puce de température et d’humidité", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
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*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
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*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
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*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
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*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
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*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=559List of Publications2025-03-15T10:46:07Z<p>Nico: </p>
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==Journal Articles==<br />
*A. Azarfar, N. Barbot and E. Perret, "Real-Time Hand Motion-Modulated Chipless RFID With Gesture Recognition Capability," in IEEE Transactions on Microwave Theory and Techniques, vol. 73, no. 1, pp. 383-396, Jan. 2025<br />
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*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, vol. 8, pp. 145-153, 2024.<br />
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*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop". Scientific Report 12, 22032 (2022).<br />
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*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
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*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
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*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023. '''IEEE CRFID James Clerk Maxwell Best Journal Paper Award 2024'''<br />
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*F. Requena, S. Ahoulou, N. Barbot, D. Kaddour, J.-M. Nedelec, T. Baron and E. Perret "Towards Wireless Detection of Surface Modification of Silicon Nanowires by an RF Approach," Nanomaterials, 12(23), 4237, 2022 <br />
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*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
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*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
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*O. Rance, N. Barbot and E. Perret, "Comments on “Development of Cross-Polar Orientation-Insensitive Chipless RFID Tags”," in IEEE Transactions on Antennas and Propagation, vol. 70, no. 5, pp. 3922-3923, May 2022.<br />
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*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
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*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” in IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022. <br />
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*F. Requena et al., "Thermal Modeling of Resonant Scatterers and Reflectometry Approach for Remote Temperature Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 69, no. 11, pp. 4720-4734, Nov. 2021, doi: 10.1109/TMTT.2021.3096986.<br />
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*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
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*F.Bonnefoy, M. Bernier, E. Perret, N. Barbot, R. Siragusa, D. Hely, E. Kato, F. Garet "Video-Rate Identification of High-Capacity Low-Cost Tags in the Terahertz Domain," Sensors, 21(11):3692 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
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*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021. doi: 10.1109/TAP.2021.3060126.<br />
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*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
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*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim Jr., N. Barbot, R. Siragusa, E. Perret and F. Popescu "A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches," Sensors. 20(21):6385, 2020.<br />
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*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
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*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
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*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
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*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
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*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
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*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
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*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
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*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
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*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
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*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
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*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
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*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
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*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
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*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
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*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
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==International Conferences==<br />
*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
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*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
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*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
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*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
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*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
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*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
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*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
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*N. Barbot and V. C. V, "Open Testing and Measurement Bench for UHF RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 158-161.<br />
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*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
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*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
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*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
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*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
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*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
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*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF RFID tags: HRFID project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
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*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
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*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
<br />
*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
<br />
*Z. Ali, N. Barbot and E. Perret, "Gesture Recognition Using Chipless RFID Tag Held in Hand," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 40-43.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Vibration Sensing using Doppler-modulated Chipless RFID Tags," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 129-132.<br />
<br />
*N. Barbot and S. Tedjini, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, D. Allane and S. Tedjini, “Orientation Sensor Based on Harmonic Transponder,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comparison between Cross-polarization and Circular Polarization Interrogation for Robust Chipless RFID Reading," 2021 51st European Microwave Conference (EuMC), London, United Kingdom, 2022, pp. 668-671.<br />
<br />
*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
<br />
*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
<br />
*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
<br />
*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
<br />
*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
<br />
*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
<br />
*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
<br />
*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
<br />
*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
<br />
*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
<br />
*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
<br />
*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
<br />
*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
<br />
==National Conferences==<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
<br />
*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
<br />
*O. Rance, Z. Ali, N. Barbot, E. Perret, "Diffuseur dépolarisant invariant par rotation", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Capteur chipless basé sur la modulation de polarisation", Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, "Distance de lecture en technologie RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, "RCS différentiel de tags modulés", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, "Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Capteur RFID sans puce de température et d’humidité", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF", 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
<br />
*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
<br />
*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=558List of Publications2025-03-14T21:16:56Z<p>Nico: </p>
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<div>__FORCETOC__<br />
<br />
==Journal Articles==<br />
*A. Azarfar, N. Barbot and E. Perret, "Real-Time Hand Motion-Modulated Chipless RFID With Gesture Recognition Capability," in IEEE Transactions on Microwave Theory and Techniques, vol. 73, no. 1, pp. 383-396, Jan. 2025<br />
<br />
*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, vol. 8, pp. 145-153, 2024.<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop". Scientific Report 12, 22032 (2022).<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
<br />
*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023. '''IEEE CRFID James Clerk Maxwell Best Journal Paper Award 2024'''<br />
<br />
*F. Requena, S. Ahoulou, N. Barbot, D. Kaddour, J.-M. Nedelec, T. Baron and E. Perret "Towards Wireless Detection of Surface Modification of Silicon Nanowires by an RF Approach," Nanomaterials, 12(23), 4237, 2022 <br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
<br />
*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comments on “Development of Cross-Polar Orientation-Insensitive Chipless RFID Tags”," in IEEE Transactions on Antennas and Propagation, vol. 70, no. 5, pp. 3922-3923, May 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
<br />
*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” in IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022. <br />
<br />
*F. Requena et al., "Thermal Modeling of Resonant Scatterers and Reflectometry Approach for Remote Temperature Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 69, no. 11, pp. 4720-4734, Nov. 2021, doi: 10.1109/TMTT.2021.3096986.<br />
<br />
*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
<br />
*F.Bonnefoy, M. Bernier, E. Perret, N. Barbot, R. Siragusa, D. Hely, E. Kato, F. Garet "Video-Rate Identification of High-Capacity Low-Cost Tags in the Terahertz Domain," Sensors, 21(11):3692 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021, early access. doi: 10.1109/TAP.2021.3060126.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
<br />
*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim Jr., N. Barbot, R. Siragusa, E. Perret and F. Popescu "A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches," Sensors. 20(21):6385, 2020.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
<br />
*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
<br />
*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
<br />
*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
<br />
*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
<br />
==International Conferences==<br />
*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
<br />
*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
<br />
*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
<br />
*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
<br />
*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
<br />
*N. Barbot and V. C. V, "Open Testing and Measurement Bench for UHF RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 158-161.<br />
<br />
*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
<br />
*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
<br />
*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
<br />
*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF RFID tags: HRFID project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
<br />
*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
<br />
*Z. Ali, N. Barbot and E. Perret, "Gesture Recognition Using Chipless RFID Tag Held in Hand," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 40-43.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Vibration Sensing using Doppler-modulated Chipless RFID Tags," 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022, Denver, CO, USA, 2022, pp. 129-132.<br />
<br />
*N. Barbot and S. Tedjini, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, D. Allane and S. Tedjini, “Orientation Sensor Based on Harmonic Transponder,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''.<br />
<br />
*O. Rance, N. Barbot and E. Perret, "Comparison between Cross-polarization and Circular Polarization Interrogation for Robust Chipless RFID Reading," 2021 51st European Microwave Conference (EuMC), London, United Kingdom, 2022, pp. 668-671.<br />
<br />
*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', Jun. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
<br />
*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
<br />
*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
<br />
*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
<br />
*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
<br />
*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
<br />
*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
<br />
*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
<br />
*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
<br />
*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
<br />
*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
<br />
*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
<br />
*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
<br />
==National Conferences==<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
<br />
*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
<br />
*N. Barbot and E. Perret, Capteur chipless basé sur la modulation de polarisation, Limoges, France, Jun. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, Distance de lecture en technologie RFID sans puce, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*O. Rance, Z. Ali, N. Barbot, E. Perret, Diffuseur dépolarisant invariant par rotation, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, RCS différentiel de tags modulés, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, Capteur RFID sans puce de température et d’humidité, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
<br />
*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
<br />
*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
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*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=557List of Publications2025-03-14T20:30:05Z<p>Nico: </p>
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==Journal Articles==<br />
*A. Azarfar, N. Barbot and E. Perret, "Real-Time Hand Motion-Modulated Chipless RFID With Gesture Recognition Capability," in IEEE Transactions on Microwave Theory and Techniques, vol. 73, no. 1, pp. 383-396, Jan. 2025<br />
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*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, vol. 8, pp. 145-153, 2024.<br />
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*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop". Scientific Report 12, 22032 (2022).<br />
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*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
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*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
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*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023. '''IEEE CRFID James Clerk Maxwell Best Journal Paper Award 2024'''<br />
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*F. Requena, S. Ahoulou, N. Barbot, D. Kaddour, J.-M. Nedelec, T. Baron and E. Perret "Towards Wireless Detection of Surface Modification of Silicon Nanowires by an RF Approach," Nanomaterials, 12(23), 4237, 2022 <br />
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*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
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*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
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*O. Rance, N. Barbot and E. Perret, "Comments on “Development of Cross-Polar Orientation-Insensitive Chipless RFID Tags”," in IEEE Transactions on Antennas and Propagation, vol. 70, no. 5, pp. 3922-3923, May 2022.<br />
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*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
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*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” in IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022. <br />
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*F. Requena et al., "Thermal Modeling of Resonant Scatterers and Reflectometry Approach for Remote Temperature Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 69, no. 11, pp. 4720-4734, Nov. 2021, doi: 10.1109/TMTT.2021.3096986.<br />
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*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
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*F.Bonnefoy, M. Bernier, E. Perret, N. Barbot, R. Siragusa, D. Hely, E. Kato, F. Garet "Video-Rate Identification of High-Capacity Low-Cost Tags in the Terahertz Domain," Sensors, 21(11):3692 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
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*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021, early access. doi: 10.1109/TAP.2021.3060126.<br />
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*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
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*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim Jr., N. Barbot, R. Siragusa, E. Perret and F. Popescu "A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches," Sensors. 20(21):6385, 2020.<br />
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*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
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*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
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*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
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*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
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*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
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*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
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*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
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*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
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*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
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*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
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*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
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*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
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*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
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*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
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*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
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==International Conferences==<br />
*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
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*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
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*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
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*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
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*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
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*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
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*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
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*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
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*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
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*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
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*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
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*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
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*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
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*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
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*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
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*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
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*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
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*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF rfid tags: Hrfid project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
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*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
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*N. Barbot and E. Perret, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
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*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''<br />
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*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
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*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', accepted, Jun. 2021.<br />
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*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', accepted, Jun. 2021.<br />
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*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''<br />
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*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
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*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
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*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
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*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
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*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
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*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
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*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
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*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
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*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
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*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
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*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
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*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
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*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
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*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
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*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
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*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
<br />
*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
<br />
*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
<br />
*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
<br />
*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
<br />
==National Conferences==<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
<br />
*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
<br />
*N. Barbot and E. Perret, Capteur chipless basé sur la modulation de polarisation, Limoges, France, Jun. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, Distance de lecture en technologie RFID sans puce, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*O. Rance, Z. Ali, N. Barbot, E. Perret, Diffuseur dépolarisant invariant par rotation, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, RCS différentiel de tags modulés, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, Capteur RFID sans puce de température et d’humidité, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
<br />
*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
<br />
*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Nicolas_Barbot&diff=556Nicolas Barbot2025-03-14T17:45:39Z<p>Nico: </p>
<hr />
<div>{{Infobox person<br />
| name = Nicolas Barbot<br />
| image = File:NBarbot.jpg<br />
| image_size = 220px<br />
| nationality = French<br />
| birth_date = {{Birth date and age|1986|08|11}}<br />
| birth_place = Limoges, France<br />
}}<br />
<br />
'''Nicolas Barbot''' received the M.Sc. degree and Ph.D. degree from the University de Limoges, France in 2010 and 2013 respectively. His Ph.D. work in [https://www.xlim.fr/ Xlim] Laboratory was focused on error-correcting codes for the optical wireless channel. He also completed a post-doctoral work in joint source-channel decoding at [https://l2s.centralesupelec.fr/ L2S] Laboratory, in Gif-sur-Yvette, France. Since September 2014, he has been an Assistant Professor at the Université Grenoble Alpes - Grenoble Institute of Technology, in Valence, France. His scientific background at [https://lcis.grenoble-inp.fr/ LCIS] Laboratory covers wireless communications systems based on backscattering principle which include classical RFID and chipless RFID.<br />
<br />
His research interests include transponders which can not be described by linear time-invariant systems. This gathers harmonic transponders which are based on the use of a non-linear component (Schottky diode) or linear time-variant transponders which are based on the modification of their response in the time domain.<br />
He also places special interests on antenna design and instrumentation based on these phenomena.<br />
<br />
==Education==<br />
<br />
{| class="wikitable" style="text-align: left;width: 80%;"<br />
|-<br />
!Period<br />
!Postion/Diploma<br />
|-<br />
|2023<br />
|align=left|HDR, Linear Time-Variant and Non-Linear Transponders for Identification and Sensing Applications, Valence, France<br />
|-<br />
|2014–2021<br />
|align=left|Assistant Professor at Grenoble INP - Esisar, LCIS, Valence, France<br />
|-<br />
|2013–2014<br />
|align=left|Post-Doc at Laboratoire des Signaux et Systèmes (L2S), ''Cross-Layer Design of Wireless Tranceivers'', Gif-sur-Yvette, France<br />
|-<br />
|2010–2013<br />
|align=left|PhD Thesis, Xlim CNRS UMR 7252, ''Channel Coding for Optical Wireless Communications'', Limoges, France<br />
|-<br />
|2009–2010<br />
|align=left|Master Degree, Faculté des Sciences, ''Technologies Hyperfréquences, Électronique et Optique'', Limoges, France<br />
|-<br />
|2007–2010<br />
|align=left|Diplome d'ingénieur, École Nationale Supérieure d’Ingénieurs de Limoges, Électronique et Télécommunications, Limoges, France<br />
|-<br />
|2005–2007<br />
|align=left|DUT Mesures Physiques, IUT du Limousin, Limoges, France<br />
|}<br />
<br />
==Teaching ==<br />
<br />
{| class="wikitable" style="text-align: left;width: 80%;"<br />
|-<br />
!Courses<br />
!Full name<br />
!Grade<br />
!ECTS<br />
|-<br />
|[[CE515 Advanced Processor Architecture and SoC Design|CE515]]<br />
|align=left|Advanced Processor Architecture and SoC Design<br />
|5A<br />
|4<br />
|-<br />
|[[PX505 Innovation Project|PX505]]<br />
|align=left|Innovation Project<br />
|5A<br />
|4<br />
|-<br />
|[[AC469 Introduction to statistical signal processing|AC469]]<br />
|align=left|Introduction to statistical signal processing<br />
|4App<br />
|1.5<br />
|-<br />
|[[SC311 Wireless Communications|SC311]]<br />
|align=left|Wireless Communications<br />
|3A<br />
|2.5<br />
|-<br />
|[[MA331 Information Theory and Channel Coding|MA331]]<br />
|align=left|Information Theory and Channel Coding<br />
|3A<br />
|3<br />
|-<br />
|[[PX302 Introduction to STM32 micro-controllers|PX302]]<br />
|align=left|Introduction to STM32 micro-controllers<br />
|3A<br />
|3<br />
|-<br />
|[[PX212 Mini-Project|PX212]]<br />
|align=left|Mini-Project<br />
|2A<br />
|6<br />
|}<br />
<br />
==Research Activities==<br />
<br />
In the first part of my career, my research activities have been focused on chipless RFID.<br />
This technology allows one to reduce the cost of the tags since information can be embedded and transmitted to the reader<br />
without using a silicon chip. However, since these tags are Linear Time-Invariant (LTI) systems<br />
<ref>N. Barbot, O. Rance, and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/range.pdf "Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?,"]<br />
IEEE Transactions on Microwave Theory and Techniques, vol. 69, no. 9, pp. 4199-4208, Sept. 2021.</ref>, their backscattered power<br />
are also located in the same bandwidth as the one used by the reader making the reading difficult in non-free space environments.<br />
Consequently, significant limitations appears in term of read range, coding capacity and media access control for any chipless tag.<br />
In order to break these limitations, my research investigations now cover:<br />
* non-linear (or harmonic) transponders which can backscatter a power at <math>n f_0</math>. These transponders are base on a non-linear component (typically a Schottky diode).<br />
* linear time-variant transponders which can backscatter a power around <math>f_0</math> <ref>N. Barbot and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/nl.pdf "Linear time-variant chipless RFID sensor,"] IEEE Journal of Radio Frequency Identification, vol. 6, pp. 104-111, 2022.</ref>. These transponders can modulate the backscattered signal (classical UHF tags, micro-Doppler or more generally any moving scatterers).<br />
<br />
In these two cases, the tags cannot be described by LTI systems and are not bounded by the previous limitations. They<br />
are also characterized by a non zero [[Differential RCS|delta RCS]] <math>\sigma_d</math><ref>N. Barbot, O. Rance, and E. Perret, [https://nicolas-barbot.ovh/wiki/pool/rcs.pdf "Differential RCS of modulated tag,"] IEEE Transactions on Antennas and Propagation, vol. 69, no. 9, pp. 6128-6133, Sept. 2021.</ref>.<br />
<br />
Additional details can be found [[Research Activities|here]].<br />
<br />
PhD students:<br />
* '''Meng Yang''', "Non-linear Transponders for Identification and Sensing Applications," Directeur: Nicolas Barbot.<br />
<br />
* '''Ashkan Azarfar''', "Détection de tags sans puce basée sur l'effet Doppler pour les applications de reconnaissance de gestes," Directeur: Etienne Perret, Co-directeur: Nicolas Barbot.<br />
<br />
* '''Florian Requena''', "Conception de tags RIFD sans puce, robustes, pour applications capteur," Directeur: Etienne Perret, Co-directeur: Darine Kaddour, Nicolas Barbot.<br />
<br />
* '''Raymundo de Amorim Junior''', "Tags sans puce millimétriques pour applications sécurisées," Directeur: Etienne Perret, Co-directeur: Romain Siragusa, Nicolas Barbot.<br />
<br />
* '''Rahul Unnikrishnan''', "Reconnaissance de gestes avec des tags chipless," Directeur: Etienne Perret, Co-directeur: Nicolas Barbot.<br />
<br />
* '''Raphael Tavares de Alencar''', "Contribution à la conception et la réalisation de tags RFID sans puce compatibles avec des procédés industriels de fabrication," Directeur: Etienne Perret, Co-directeur: Marco Garbati, Nicolas Barbot.<br />
<br />
* '''Florent Bonnefoy''', "Authentification dans le domaine THz," Directeur: Frédéric Garet, Co-directeur: Maxime Bernier, Nicolas Barbot.<br />
<br />
See the complete [[List of Publications]].<br />
<br />
==CV==<br />
<br />
[https://nicolas-barbot.ovh/wiki/pool/cv_en.pdf English Version]<br />
<br />
[https://nicolas-barbot.ovh/wiki/pool/cv.pdf French Version]<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
==External links==<br />
[https://scholar.google.com/citations?user=mMhPOZYAAAAJ&hl=en&oi=ao Google Scholar]<br />
<br />
[https://orcid.org/0000-0001-6355-9109 ORCID ID]</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=List_of_Publications&diff=555List of Publications2025-03-14T11:22:36Z<p>Nico: </p>
<hr />
<div>__FORCETOC__<br />
<br />
==Journal Articles==<br />
*N. Barbot, I. Prodan and P. Nikitin, "A Practical Guide to Optimal Impedance Matching for UHF RFID Chip," in IEEE Journal of Radio Frequency Identification, Early access.<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot and E. Perret, “Chipless Image-Based System for Spatial-Frequency Data Encoding,” IEEE Transactions on Antennas and Propagation, vol. 72, no. 1, pp. 693-706, Jan. 2024.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Multistate Chipless RFID Tags for Robust Vibration Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 72, no. 2, pp. 1380-1391, Feb. 2024.<br />
<br />
*N. Barbot, “Non linear modulation of UHF RFID tag,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 38-44, 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Wireless Complex Permittivity Measurement Using Resonant Scatterers and a Radar Approach," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 10, pp. 4427-4436, Oct. 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Robustness Improvement for Chipless RFID Reading Using Polarization Separation," in IEEE Transactions on Microwave Theory and Techniques, vol. 71, no. 7, pp. 3173-3188, July 2023<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” IEEE Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Orientation Sensing With a Loop Resonator Based on Its Re-Radiation Pattern," in IEEE Sensors Journal, vol. 23, no. 3, pp. 3159-3172, 1 Feb.1, 2023<br />
<br />
*Azarfar, A., Barbot, N. & Perret, E. Directional amplitude backscatter modulation with suppressed Doppler based on rotating resonant loop. Sci Rep 12, 22032 (2022).<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Motion-Modulated Chipless RFID," in IEEE Journal of Microwaves, vol. 3, no. 1, pp. 256-267, Jan. 2023.<br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot and E. Perret, "Optimal Angle in Bi-static Measurement for Chipless Tag Detection Improvement," in IEEE Transactions on Antennas and Propagation, 2022, doi: 10.1109/TAP.2022.3209223.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Combined temperature and humidity chipless RFID sensor,” IEEE Sensors Journal, vol. 22, no. 16, pp. 16 098–16 110, 2022. doi: 10.1109/JSEN.2022.3189845.<br />
<br />
*Z. Ali, O. Rance, N. Barbot, and E. Perret, “Depolarizing chipless RFID tag made orientation insensitive by using ground plane interaction,” IEEE Transactions on Antennas and Propagation, pp. 1–1, 2022. doi: 10.1109/TAP.2022.3145479.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Chipless RFID based on micro-doppler effect,” IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 1, pp. 766–778, 2022. doi: 10.1109/TMTT.2021.3131593.<br />
<br />
*F. Requena et al., "Thermal Modeling of Resonant Scatterers and Reflectometry Approach for Remote Temperature Sensing," in IEEE Transactions on Microwave Theory and Techniques, vol. 69, no. 11, pp. 4720-4734, Nov. 2021, doi: 10.1109/TMTT.2021.3096986.<br />
<br />
*R. Unnikrishnan, O. Rance, N. Barbot, and E. Perret, “Chipless RFID Label with Identification and Touch-Sensing Capabilities,” Sensors, vol. 21, no. 14, p. 4862, Jul. 2021.<br />
<br />
*Z. Ali, E. Perret, N. Barbot and R. Siragusa, "Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID," in IEEE Sensors Journal, vol. 21, no. 5, pp. 6530-6542, 1 March, 2021, doi: 10.1109/JSEN.2020.3041574.<br />
<br />
*N. Barbot and E. Perret, “Linear time-variant chipless RFID sensor,” ''IEEE Transactions on Antennas and Propagation'', submitted.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, "Thermal Modeling of Resonant Scatterers and Reflectometry approach for Remote Temperature Sensing" IEEE Transactions on Microwave Theory and Techniques''.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Classical RFID vs. chipless RFID read range: Is linearity a friend or a foe?” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 69, no. 9, pp. 4199–4208, Sep. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Differential RCS of modulated tag,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 9, pp. 6128–6133, Sep. 2021, doi: 10.1109/TAP.2021.3060943.<br />
<br />
*R. De Amorim, R. Siragusa, N. Barbot, G. Fontgalland, and E. Perret, “Millimeter wave chipless RFID authentication based on spatial diversity and 2D-classification approach,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, 2021, early access. doi: 10.1109/TAP.2021.3060126.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, and R. Siragusa, “Extraction of Aspect-Independent Parameters Using Spectrogram Method for Chipless Frequency-Coded RFID,” ''IEEE Sensors Journal'', pp. 1–1, 2021. doi: 10.1109/JSEN.2020.3041574. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-03120442.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Contactless characterization of metals’ thermal expansion coefficient by a free-space RF measurement,” ''IEEE Transactions on Antennas and Propagation'', vol. 69, no. 2, pp. 1230–1234, 2021. doi: 10.1109/TAP.2020.3010982.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Chipless RFID reading method insensitive to tag orientation,” ''IEEE Transactions on Antennas and Propagation'', vol 69, no. 5, pp. 2896–2902, May 2021, doi: 10.1109/TAP.2020.3028187.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Design of planar resonant scatterer with roll-invariant cross polarization,” ''IEEE Transactions on Microwave Theory and Techniques'', vol. 68, no. 10, pp. 4305–4313, 2020. doi: 10.1109/TMTT.2020.3014376.<br />
<br />
*R. Tavares de Alencar, Z. Ali, N. Barbot, M. Garbati, and E. Perret, “Practical performance comparison of 1-D and 2-D decoding methods for a chipless RFID system in a real environment,” ''IEEE Journal of Radio Frequency Identification'', vol. 4, no. 4, pp. 532–544, 2020. doi: 10.1109/JRFID.2020.2997988.<br />
<br />
*D. Nastasiu, R. Scripcaru, A. Digulescu, C. Ioana, R. De Amorim, N. Barbot, R. Siragusa, E. Perret, and F. Popescu, “A New Method of Secure Authentication Based on Electromagnetic Signatures of Chipless RFID Tags and Machine Learning Approaches,” ''Sensors'', vol. 20, no. 21, p. 6385, Nov. 2020. doi: 10.3390/s20216385. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03035887.<br />
<br />
*M. M. Ahmed, E. Perret, D. Hely, R. Siragusa, and N. Barbot, “Guided electromagnetic wave technique for IC authentication,” ''Sensors'', vol. 20, no. 7, 2020, issn: 1424-8220. doi: 10.3390/s20072041. [Online]. Available: https://www.mdpi.com/1424-8220/20/7/2041.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Angle Sensor Based on Chipless RFID Tag,” ''IEEE Antennas and Wireless Propagation Letters'', 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02377065.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Authentication Using Metallic Inkjet-Printed Chipless RFID Tags,” ''IEEE Transactions on Antennas and Propagation'', pp. 1–1, Oct. 2019. doi: 10.1109/TAP.2019.2948740. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02337466.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and Noninvasive IC Authentication Using Radiated Electromagnetic Emissions,” Journal of Hardware and Systems Security, vol. 3, no. 3, pp. 273–288, Sep. 2019. doi: 10.1007/s41635-019-00072-y. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02296583.<br />
<br />
*Z. Ali, E. Perret, N. Barbot, R. Siragusa, D. Hely, M. Bernier, and F. Garet, “Detection of Natural Randomness by Chipless RFID Approach and Its Application to Authentication,” ''IEEE Transactions on Microwave Theory and Techniques'', pp. 1–15, May 2019. doi: 10.1109/TMTT.2019.2914102. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02132612.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Robust and noninvasive IC authentication using radiated electromagnetic emissions,” ''Journal of Hardware and Systems Security'', vol. 3, no. 3, pp. 273–288, Sep. 2019. <br />
<br />
*N. Barbot and E. Perret, “Accurate Positioning System Based on Chipless Technology,” ''Sensors'', Mar. 2019. doi: 10.3390/s19061341. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02064576.<br />
<br />
*N. Barbot and E. Perret, “A Chipless RFID Method of 2D Localization Based on Phase Acquisition,” ''Journal of Sensors'', vol. 2018, pp. 1–6, Jul. 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944679.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, E. Perret, D. Hély, M. Bernier, and F. Garet, “Detection of Minimum Geometrical Variation by Free-Space-Based Chipless Approach and its Application to Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 28, no. 4, pp. 323–325, Jan. 2018. doi: 10.1109/LMWC.2018.2805858. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800580.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Radiated Electromagnetic Emission for Integrated Circuit Authentication,” ''IEEE Microwave and Wireless Components Letters'', vol. 27, no. 11, pp. 1028–1030, Nov. 2017. doi: 10.1109/LMWC.2017.2750078. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01724143.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Low-density Parity-check and Fountain Code Performance over Mobile Wireless Optical Channels,” ''Transactions on emerging telecommunications technologies'', vol. 25, no. 6, pp. 638–647, Jun. 2014. doi: 10.1002/ett.2812. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01257508.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Transmission Power Analysis of Optical Wireless Based Mobile Healthcare Systems,” ''Int J Wireless Inf Networks'', vol. 19, no. 3, pp. 201–208, Jun. 2012, Springer Science+Business Media, doi: 10.1007/s10776-012-0177-1. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790442.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Maximal rate of mobile wireless optical link in indoor environment,” ''International Journal on Advanced in Telecommunications'', vol. 5, no. 3-4, pp. 274–283, 2012. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919839.<br />
<br />
==International Conferences==<br />
*M. Yang, N. Barbot. "Motion-modulated Harmonic Sensors," 2024 IEEE International Conference on RFID Technology and Applications (RFID-TA), Dec 2024, Daytona Beach (FL), United States.<br />
<br />
*S. Hemour, N. Barbot, F. Collin, J. . -L. Lachaud, S. Destor and J. Tomas, "The Great Microwave Education Opportunity of the Great Seal Bug (also known as "The Thing")," 2024 54th European Microwave Conference (EuMC), Paris, France, 2024, pp. 72-75<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Hand Motion-Modulated Chipless RFID for Gesture Recognition," 2024 IEEE/MTT-S International Microwave Symposium - IMS 2024, Washington, DC, USA, 2024, pp. 349-352.<br />
<br />
*N. Barbot and P. Nikitin, "Differential RCS of Dual-Port Tag Antenna with Synchronous Modulated Backscatter," 2024 IEEE International Conference on RFID (RFID), Cambridge, MA, USA, 2024, pp. 1-6<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "Chipless RFID Tag Imaging System based on Conveyor-Belt Radio Frequency Scanning," 2023 IEEE Conference on Antenna Measurements and Applications (CAMA), Genoa, Italy, 2023, pp. 636-639.<br />
<br />
*N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Time-efficient Reading Process for Motion-modulated Chipless RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 53-56.<br />
<br />
*F. Requena, D. Kaddour, N. Barbot and E. Perret, "Detection of water drop volume based on Chipless RFID radar approach," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 233-236.<br />
<br />
*S. Hemour and N. Barbot, "Backscattering modulation 101: VNA measurements," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 169-172.<br />
<br />
*R. Amorim, N. Barbot, R. Siragusa and E. Perret, "3D authentication approach to enhance the security level for millimeter-wave chipless tags," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 61-64.<br />
<br />
*N. Barbot and I. Prodan, "Optimal Impedance Matching for UHF RFID Chip," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 96-101.<br />
<br />
*N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83.<br />
<br />
*A. Azarfar, N. Barbot and E. Perret, "Long-Range Chipless RFID for Objects in Translation using Doppler-modulated Depolarizing Tags," 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023, San Diego, CA, USA, 2023, pp. 1073-1076.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour and E. Perret, "Increased Coding Capacity of Chipless RFID Tags Using Radiation Pattern Diversity," 2022 52nd European Microwave Conference (EuMC), 2022, pp. 868-871, doi: 10.23919/EuMC54642.2022.9924405.<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa and E. Perret, "Bistatic Configuration Reading for Sub-Millimeter Displacement Chipless Tag Sensor," 2023 17th European Conference on Antennas and Propagation (EuCAP), Florence, Italy, 2023, pp. 1-4.<br />
<br />
*N. Barbot, “Delta RCS expression of linear time-variant transponders based on polarization modulation,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*R. D. A. Junior, N. Barbot, R. Siragusa, C. Trehoult, L. Lyannaz, and E. Perret, “Design and manufacture of resonant chipless tags in millimeter-wave band,” in RFID-TA 2022, Cagliari, Italy,<br />
Sep. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Respiration monitoring using doppler-modulated depolarizing chipless tags,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022. '''Best Paper Award'''<br />
<br />
*D. Allane, N. Barbot, Y. Duroc, and S. Tedjini, “Exploitation of harmonic signals backscattered by UHF rfid tags: Hrfid project,” in RFID-TA 2022, Cagliari, Italy, Sep. 2022.<br />
<br />
*A. Voisin, A. Dumas, N. Barbot and S. Tedjini, “Differential RCS of Multi-State Transponder,” 2022 IEEE Wireless Power Week Conference (WPW 2022), Bordeaux, France, Jul. 2022, pp. 1–4.<br />
<br />
*N. Barbot and E. Perret, “Towards Identification for Harmonic Transponders,” ''in 3nd URSI AT-RASC'', Gran Canaria, Spain, May 2022.<br />
<br />
*N. Barbot, R. De Amorim Junior, and P. Nikitin, “Simple Low Cost Open Source UHF RFID Reader,” ''in 2022 IEEE RFID conference'', Las Vegas, ND, Apr. 2022 '''Best Poster Award'''<br />
<br />
*N. Barbot and Etienne Perret, "Impact of the Polarization over the Read Range in Chipless RFID", ''in 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA) (IEEE RFID-TA 2021)'', Oct. 2021.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, “Towards chipless RFID technology based on micro-doppler effect for long range applications,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', accepted, Jun. 2021.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, “Chipless RFID temperature and humidity sensing,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2021'', accepted, Jun. 2021.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Notes on differential RCS of modulated tag,” ''in 2021 IEEE RFID conference'', Atlanta, GA, Apr. 2021 '''Best Poster Award'''<br />
<br />
*R. de Amorim, N. Barbot, R. Siragusa, and E. Perret, “Millimeter-wave chipless RFID tag for authentication applications,” ''in 2020 50th European Microwave Conference (EuMC)'', 2021, pp. 800–803. doi: 10.23919/EuMC48046.2021.9338082.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Cross-Polarization Chipless Tag for Orientation Sensing,” ''in European Microwave Conference (EuMC)'', Utrecht, Netherlands, Jan. 2021. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03120671.<br />
<br />
*O. Rance, N. Barbot, and E. Perret, “Monte carlo simulation for chipless RFID orientation sensor,” ''in 2020 IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting'', 2020, pp. 1199–1200. doi: 10.1109/IEEECONF35879.2020.9329985.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, “Orientation Determination of a Scatterer Based on Polarimetric Radar Measurements,” ''in URSI GASS 2020'', Rome, Italy, Aug. 2020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02948679.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, D. Hély, F. Garet, N. Barbot, and M. Bernier, “Implementation of RF communication subsets on common low frequency clocked FPGA,” ''in 2019 49th European Microwave Conference (EuMC)'', Paris, France: IEEE, Oct. 2019, pp. 742–745. doi: 10.23919/EuMC.2019.8910837. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429327.<br />
<br />
*R. T. d. Alencar, N. Barbot, M. Garbati, and E. Perret, “Practical Comparison of Decoding Methods for Chipless RFID System in Real Environment,” ''in 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA)'', Pisa, Italy: IEEE, Sep. 2019, pp. 207–211. doi: 10.1109/RFID-TA.2019.8892020. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02429346.<br />
<br />
*R. T. de Alencar, N. Barbot, M. Garbati, and E. Perret, “Characterization of chipless RFID tag in a 3-dimensional reading zone,” ''in 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting'', 2019, pp. 639–640. doi: 10.1109/APUSNCURSINRSM.2019.8888559.<br />
<br />
*S. Salhi, F. Bonnefoy, S. Girard, M. Bernier, N. Barbot, R. Siragusa, E. Perret, and F. Garet, “Enhanced THz tags authentication using multivariate statistical analysis,” ''in IRMMW-THz 2019 - 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France, Sep. 2019, pp. 1–2. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02282841.<br />
<br />
*F. Bonnefoy, C. Ioana, M. Bernier, N. Barbot, R. Siragusa, E. Perret, P. Martinez, and F. Garet, “Identification Of Random Internal Structuring THz Tags Using Images Correlation And SIWPD Analysis,” ''in 44th International Conference on Infrared, Millimeter, and Terahertz Waves'', Paris, France: IEEE, Sep. 2019, pp. 1–1. doi: 10.1109/IRMMW-THz.2019.8873800. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02297202.<br />
<br />
*F. Bonnefoy, M. Bernier, F. Garet, N. Barbot, D. Hely, R. Siragusa, and E. Perret, “Diffraction grating tags structures dedicated to authentication in the THz,” ''in French-German THz Conference 2019'', Kaiserslautern, Germany, Apr. 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02436662.<br />
<br />
*M. Hamdi, F. Bonnefoy, M. Bernier, F. Garet, E. Perret, N. Barbot, R. Siragusa, and D. Hely, “Identification in the Terahertz Domain using Low Cost Tags with a Fast Spectrometer,” ''in ASID 2018: 12th IEEE International Conference on Anti-counterfeiting, Security, and Identification'', Xiamen, China, Nov. 2018. doi: 10.1109/ICASID.2018.8693209. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02015383.<br />
<br />
*M. M. Ahmed, D. Hely, E. Perret, N. Barbot, R. Siragusa, M. Bernier, and F. Garet, “Authentication of Microcontroller Board Using Non-Invasive EM Emission Technique,” ''in 2018 IEEE 3rd International Verification and Security Workshop (IVSW)'', Platja d’Aro, Spain: IEEE, Jul. 2018, pp. 25–30. doi: 10.1109/IVSW.2018.8494883. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02014214.<br />
<br />
*Z. Ali, N. Barbot, R. Siragusa, D. Hely, M. Bernier, F. Garet, and E. Perret, “Chipless RFID Tag Discrimination and the Performance of Resemblance Metrics to be used for it,” ''in IEEE/MTT-S International Microwave Symposium - IMS 2018'', Philadelphia, United States: IEEE, Jun. 2018. doi: 10.1109/MWSYM.2018.8439855. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01888533.<br />
<br />
*N. Barbot and E. Perret, “2D Localization using Phase Measurement of Chipless RFID Tags,” ''in 2nd URSI AT-RASC'', Gran Canaria, Spain, May 2018. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02066779.<br />
<br />
*S. Chollet, L. Pion, and N. Barbot, “Secure IoT for a Pervasive Platform,” ''in 2018 IEEE International Conference on Pervasive Computing and Communications Workshops, PerCom Workshops 2018'', Athènes, Greece, Mar. 2018. [Online]. Available: https://hal.archives- ouvertes.fr/hal-01898651.<br />
<br />
*M. M. Ahmed, D. Hely, N. Barbot, R. Siragusa, E. Perret, M. Bernier, and F. Garet, “Towards a robust and efficient EM based authentication of FPGA against counterfeiting and recycling,” ''in 19th International Symposium on Computer Architecture and Digital Systems (CADS)'', Kish Island, Iran: IEEE, Dec. 2017, pp. 1–6. doi: 10.1109/CADS.2017.8310673. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014230.<br />
<br />
*N. Barbot and E. Perret, “Gesture recognition with the chipless RIFD technology,” ''in 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)'', Montreal, Canada, Aug. 2017, pp. 19–26. doi: 10.23919/URSIGASS.2017.8104990. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-01944690.<br />
<br />
*F. Bonnefoy, M. Hamdi, M. Bernier, N. Barbot, R. Siragusa, D. Hely, E. Perret, and F. Garet, “Authentication in the THz domain: a new tool to fight couterfeiting,” ''in 9th THz days'', Dunkerque, France, Jun. 2017. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014053.<br />
<br />
*Z. Ali, F. Bonnefoy, R. Siragusa, N. Barbot, D. Hély, E. Perret, M. Bernier, and F. Garet, “Potential of chipless authentication based on randomness inherent in fabrication process for RF and THz,” ''in 11th European Conference on Antennas and Propagation (EUCAP)'', Paris, France, 2017. doi: 10.23919/EuCAP.2017.7928647. [Online]. Available: https://hal.archives-ouvertes.fr/hal-01800579.<br />
<br />
*M. M. Ahmed, D. Hely, R. Siragusa, N. Barbot, E. Perret, M. Bernier, and F. Garet, “Authentication of IC based on Electromagnetic Signature,” ''in 6th Conference on Trustworthy Manufacturing and Utilization of Secure Devices (TRUDEVICE 2016)'', Barcelone, Spain, Nov. 2016. [Online]. Available: https://hal.univ-grenoble-alpes.fr/hal-02014251.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Outage capacity of mobile wireless optical link in indoor environment,” ''in Application of Information and Communication Technologies (AICT)'', Stuttgart, Germany, Oct. 2012, 5 pages. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790458.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Multiple Access Interference Impact on Outage Probability of Wireless Optical CDMA Systems,” ''in Photonics in Switching 2012'', Ajaccio - Corse, France, Sep. 2012, Session 1.5 OFDM, CDMA. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793162.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, “Performance of a Mobile Wireless Optical CDMA Monitoring System,” ''in The Ninth International Symposium on Wireless Communication Systems (ISWCS)'', ISSN : 2154-0217 E-ISBN : 978-1-4673-0760-4 Print ISBN: 978-1-4673-0761-1, Paris, France, Aug. 2012, pp.666–670. doi: 10.1109/ISWCS.2012.6328451. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00793183.<br />
<br />
*N. Barbot, S. S. Torkestani, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “LT codes performance over indoor mobile wireless optical channel,” ''in Communication Systems, Networks & Digital Signal Processing (CSNDSP)'', 2012 8th International Symposium on, Print ISBN: 978-1-4577-1472-6, Poznan, Germany, Jul. 2012, pp. 1–4. doi: 10.1109/CSNDSP.2012.6292657. [Online]. Available: https://hal.archives-ouvertes.fr/hal-00790453.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance and Transmission Power Bound Analysis for Optical Wireless based Mobile Healthcare Applications,” ''in 2011 IEEE 22nd International Symposium on'', Toronto, Canada, Sep. 2011, Inconnu. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650252.<br />
<br />
*N. Barbot, S. Sahuguede, A. Julien-Vergonjanne, and J.-P. Cances, “Performance Bound for LDPC Codes Over Mobile LOS Wireless Optical Channel,” ''in 2011 IEEE 73rd Vehicular Technology Conference: VTC2011-Spring'', Budapest, Hungary, May 2011, pp. 1–5. doi: 10.1109/VETECS.2011.5956176. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00649807.<br />
<br />
==National Conferences==<br />
<br />
*R. Amorim, R. Siragusa, N. Barbot, E. Perret. "Système d'imagerie sur un convoyeur pour l'augmentation de la capacité de codage des applications RFID sans puce". 23ème edition des Journées Nationales Microondes, Jun 2024, Antibes (France), France. <br />
<br />
*M. Yang, N. Barbot. "Modulation Non-Linéaire de Tag RFID UHF". 23ème edition des Journées Nationales Microondes (JNM), Jun 2024, Juan les Pins, Antibes, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "RFID sans puce longue portée pour des objets en translation à l'aide de tags dépolarisants modulés par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan Les Pins, France.<br />
<br />
*A. Azarfar, N. Barbot, E. Perret. "Système chipless de surveillance de la respiration basé sur une modulation par effet Doppler," 23ème édition des Journées Nationales Microondes (JNM), Jun 2024, Juan-Les-Pins, France. <br />
<br />
*N. Barbot and E. Perret, Capteur chipless basé sur la modulation de polarisation, Limoges, France, Jun. 2022.<br />
<br />
*A. Azarfar, N. Barbot, and E. Perret, RFID sans puce basée sur l’effet micro-doppler pour application longue portée, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot and E. Perret, Distance de lecture en technologie RFID sans puce, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*O. Rance, Z. Ali, N. Barbot, E. Perret, Diffuseur dépolarisant invariant par rotation, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*N. Barbot, O. Rance, and E. Perret, RCS différentiel de tags modulés, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*R. de Amorim Jr, R. Siragusa, N. Barbot, and E. Perret, Diversité spatiale pour l’augmentation de la robustesse de détection des tags RFID sans puce, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, Capteur RFID sans puce de température et d’humidité, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*F. Requena, N. Barbot, D. Kaddour, and E. Perret, Caractérisation sans contact du coefficient de dilatation thermique de métaux par approche RF, 22èmes Journées Nationales Microondes (JNM), Limoges, France, Jun. 2022.<br />
<br />
*M. M. Ahmed, E. Perret, R. Siragusa, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Développement d’une plateforme RF flexible et reconfigurable basée sur un FPGA," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02051698.<br />
<br />
*Z. Ali, R. Siragusa, E. Perret, N. Barbot, D. Hely, M. Bernier, and F. Garet, "Méthode d’authentification basée sur des tags RFID sans puce imprimés par jet d’encre conductrice," ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02017120.<br />
<br />
*N. Barbot and E. Perret, Localisation 2D par Mesures de Phase basée sur la Technologie Chipless, ''21èmes Journées Nationales Microondes (JNM)'', Caen, France, May 2019. [Online]. Available: https://hal.archives-ouvertes.fr/hal-02019490.<br />
<br />
*N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances du contrôle d’erreur d’une transmission optique sans fil dédiée à une application de télé-surveillance mobile, Brest, France, Sep. 2013. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00919862.<br />
<br />
*S. S. Torkestani, N. Barbot, S. Sahuguede, and A. Julien-Vergonjanne, Performances d’un système de transmission optique sans fil pour la télésurveillance médicale en milieu sensible confiné, Dijon, France, Sep. 2011. [Online]. Available: https://hal-unilim.archives-ouvertes.fr/hal-00650305.</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=554Simple Low Cost Open Source UHF RFID Reader2024-08-11T22:26:50Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 of the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obsolete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1.0''' RF signal generation is based on the Melexis chip (obsolete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1.1''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
<gallery widths=230px><br />
File:version0a.jpg|Version 0a<br />
File:version0b.jpg|Version 0b<br />
File:version1a.jpg|Version 1<math>\alpha</math><br />
File:version1a2.jpg|Version 1.0<br />
</gallery><br />
<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
'''Tag platform''' This board emulate a (basic) UHF RFID tag<ref>N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83</ref>. A modular architecture has been adopted to easily prototype the design. Firmware is also available on a [https://github.com/nicolas-barbot/SDR_UHF_RFID_tag Github repository]<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=553Simple Low Cost Open Source UHF RFID Reader2024-08-09T22:49:30Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obsolete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1.0''' RF signal generation is based on the Melexis chip (obsolete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1.1''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
<gallery widths=230px><br />
File:version0a.jpg|Version 0a<br />
File:version0b.jpg|Version 0b<br />
File:version1a.jpg|Version 1<math>\alpha</math><br />
File:version1a2.jpg|Version 1.0<br />
</gallery><br />
<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
'''Tag platform''' This board emulate a (basic) UHF RFID tag<ref>N. Barbot and P. Nikitin, "Simple Open-Source UHF RFID Tag Platform," 2023 IEEE International Conference on RFID (RFID), Seattle, WA, USA, 2023, pp. 78-83</ref>. A modular architecture has been adopted to easily prototype the design. Firmware is also available on a [https://github.com/nicolas-barbot/SDR_UHF_RFID_tag Github repository]<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=552Simple Low Cost Open Source UHF RFID Reader2024-08-09T22:42:07Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obsolete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1.0''' RF signal generation is based on the Melexis chip (obsolete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1.1''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
<gallery widths=230px><br />
File:version0a.jpg|Version 0a<br />
File:version0b.jpg|Version 0b<br />
File:version1a.jpg|Version 1<math>\alpha</math><br />
File:version1a2.jpg|Version 1.0<br />
</gallery><br />
<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=File:Version0b.jpg&diff=551File:Version0b.jpg2024-08-09T22:39:09Z<p>Nico: Nico uploaded a new version of File:Version0b.jpg</p>
<hr />
<div></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=550Simple Low Cost Open Source UHF RFID Reader2024-08-09T22:38:28Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1.0''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1.1''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
<gallery widths=230px><br />
File:version0a.jpg|Version 0a<br />
File:version0b.jpg|Version 0b<br />
File:version1a.jpg|Version 1<math>\alpha</math><br />
File:version1a2.jpg|Version 1.0<br />
</gallery><br />
<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=549Simple Low Cost Open Source UHF RFID Reader2024-08-09T16:16:29Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1.0''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1.0 b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
<gallery widths=230px><br />
File:version0a.jpg|Version 0a<br />
File:version0b.jpg|Version 0b<br />
File:version1a.jpg|Version 1<math>\alpha</math><br />
File:version1a2.jpg|Version 1a<br />
</gallery><br />
<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=548Simple Low Cost Open Source UHF RFID Reader2024-08-09T16:15:29Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
[[File:version0a.jpg|thumb|right|Version 0a]]<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
[[File:version0b.jpg|thumb|right|Version 0b]]<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
[[File:version1a.jpg|thumb|right|Version 1<math>\alpha</math>]]<br />
<br />
'''Version 1.0''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
[[File:version1a2.jpg|thumb|right|Version 1a]]<br />
<br />
'''Version 1.0 b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
<gallery widths=230px><br />
File:version0a.jpg|Version 0a<br />
File:version0b.jpg|Version 0b<br />
File:version1a.jpg|Version 1<math>\alpha</math><br />
File:version1a2.jpg|Version 1a<br />
</gallery><br />
<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=547Simple Low Cost Open Source UHF RFID Reader2024-08-09T16:10:01Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
[[File:version0a.jpg|thumb|right|Version 0a]]<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
[[File:version0b.jpg|thumb|right|Version 0b]]<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
[[File:version1a.jpg|thumb|right|Version 1<math>\alpha</math>]]<br />
<br />
'''Version 1.0''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
[[File:version1a2.jpg|thumb|right|Version 1a]]<br />
<br />
'''Version 1.0 b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=File:Version1a2.jpg&diff=546File:Version1a2.jpg2024-08-09T15:55:39Z<p>Nico: </p>
<hr />
<div></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=545Simple Low Cost Open Source UHF RFID Reader2024-08-09T15:51:23Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
[[File:version0a.jpg|thumb|right|Version 0a]]<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
[[File:version0b.jpg|thumb|right|Version 0b]]<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
[[File:version1a.jpg|thumb|right|Version 1<math>\alpha</math>]]<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
[[File:version1a2.jpg|thumb|right|Version 1a]]<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=544Simple Low Cost Open Source UHF RFID Reader2024-08-09T15:44:32Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
[[File:version0a.jpg|thumb|right|Version 0a]]<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
[[File:version0b.jpg|thumb|right|Version 0b]]<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
[[File:version0c.jpg]]<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
[[File:version1a.jpg|thumb|right|Version 1<math>\alpha</math>]]<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=File:Version0b.jpg&diff=543File:Version0b.jpg2024-08-09T15:43:45Z<p>Nico: </p>
<hr />
<div></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=542Simple Low Cost Open Source UHF RFID Reader2024-08-09T15:40:14Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
[[File:version0a.jpg|thumb|right|Version 0a]]<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
[[File:version0b.jpg]]<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
[[File:version0c.jpg]]<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
[[File:version1a.jpg|thumb|right|Version 1<math>\alpha</math>]]<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=File:Version0a.jpg&diff=541File:Version0a.jpg2024-08-09T15:39:03Z<p>Nico: </p>
<hr />
<div></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=540Simple Low Cost Open Source UHF RFID Reader2024-08-09T15:36:13Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
[[File:version0a.jpg]]<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
[[File:version0b.jpg]]<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
[[File:version0c.jpg]]<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
[[File:version1a.jpg|thumb|right|Version 1<math>\alpha</math>]]<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=File:Version1a.jpg&diff=539File:Version1a.jpg2024-08-09T15:29:40Z<p>Nico: </p>
<hr />
<div></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=538Simple Low Cost Open Source UHF RFID Reader2024-08-09T15:27:33Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
[[File:version0a.jpg]]<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
[[File:version0b.jpg]]<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
[[File:version0c.jpg]]<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
[[File:version1a.jpg]]<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=537Simple Low Cost Open Source UHF RFID Reader2024-08-09T14:30:04Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=536Simple Low Cost Open Source UHF RFID Reader2024-08-09T14:28:05Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
</syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
If you are interested by this project, the more valuable option is to build the reader yourself. All design files are available (PCB, BOM, firmware).<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=535Simple Low Cost Open Source UHF RFID Reader2024-08-09T14:27:17Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable (the "ON" led on the Arduino board should switch on)<br />
* On the computer, open Arduino IDE<br />
* Download the latest version of the firmware on the [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository] and copy paste it in the Arduino IDE<br />
* Build the firmware, output message should look like:<br />
<syntaxhighlight><br />
Sketch uses 8586 bytes (26%) of program storage space. Maximum is 32256 bytes.<br />
Global variables use 1368 bytes (66%) of dynamic memory, leaving 680 bytes for local variables. Maximum is 2048 bytes.<br />
<syntaxhighlight><br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<syntaxhighlight><br />
RFID Reader V1.0<br />
TARI = 20<br />
PW = 10<br />
L0 = 20<br />
L1 = 40<br />
RTCAL = 60<br />
TRCAL = 180<br />
PIE Rate = 33.33 kb/s<br />
BLF = 44 kb/s<br />
</syntaxhighlight><br />
<br />
Do not worry about the parameters that you see, these are related to the RFID protocol and can be fully modified in the firmware. The most important thing is that your reader is working. From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<syntaxhighlight><br />
T1 (RN16) = 256.00 us<br />
RN16[] = 1 1 0 1 1 1 1 0 0 0 0 0 0 1 1 1 <br />
T2 (approx) = 238.64 us<br />
T1 (EPC) = 6.00 us<br />
PC[] = 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 <br />
L = 96<br />
EPC[] = 0 0 1 1 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 1 0 1 1 1 0 1 1 0 0 1 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 <br />
CRC[] = 0 1 0 0 0 0 1 0 1 1 1 0 0 1 1 1 <br />
CRC 0K<br />
Tpri (theo) = 22.73 us<br />
Tpri0 min/avg/max = 21.00/22.34/22.44 us<br />
Tpri1 min/avg/max = 20.37/22.33/24.44 us<br />
Tpri min/avg/max = 20.37/22.34/24.44 us<br />
BLF (exp) = 44.77 kb/s<br />
</syntaxhighlight><br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
If you are interested by this project, the more valuable option is to build the reader yourself. All design files are available (PCB, BOM, firmware).<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=534Simple Low Cost Open Source UHF RFID Reader2024-08-09T14:08:40Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
Before we begin, let's ensure you have:<br />
* A personal computer with a USB port<br />
* An Arduino Uno board<br />
* An RFID Reader Shield (version 1a or 1b)<br />
* A 915 MHz antenna (SMA connector)<br />
* A cable USB-A to USB-B<br />
<br />
== Instructions ==<br />
<br />
* Connect the RFID Reader Shield to the Arduino Uno<br />
* Connect the antenna to the RFID Reader Shield<br />
* Connect the Arduino to the computer using the cable<br />
* "ON" led should switch on<br />
* On the computer, open Arduino IDE<br />
* Copy paste the code of the firmware in the IDE (you can download the latest version on GitHub)<br />
* Build the firmware, output message should look like:<br />
* Flash the firmware on the Arduino<br />
* Open a serial monitor to check the state of the reader, you should see something like:<br />
<br />
From now, your RFID reader is sending some "Query" commands and trying to detect a tag reply.<br />
* Put a UHF tag close to the reader antenna<br />
* Check the serial monitor, you should see something like:<br />
<br />
If you see this output, congratulation, you just read your first tag!<br />
<br />
== Troubleshooting ==<br />
<br />
The best way to debug (or understand) the behavior of the reader is to probe the digital pin 8 or the Arduino. All figures presented in the journal paper have been obtained by this method.<br />
<br />
If you are interested by this project, the more valuable option is to build the reader yourself. All design files are available (PCB, BOM, firmware).<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=533Simple Low Cost Open Source UHF RFID Reader2024-08-09T13:33:41Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
If you are interested by this project, the more valuable option is to build the reader yourself. All design files are available (PCB, BOM, firmware).<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=File:SampleVideo.mp4&diff=532File:SampleVideo.mp42024-08-09T13:20:04Z<p>Nico: </p>
<hr />
<div></div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=531Simple Low Cost Open Source UHF RFID Reader2024-08-09T13:19:13Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
If you are interested by this project, the more valuable option is to build the reader yourself. All design files are available (PCB, BOM, firmware).<br />
<br />
[[File:SampleVideo.mp4]]<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=530Simple Low Cost Open Source UHF RFID Reader2024-08-07T09:53:52Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
If you are interested by this project, the more valuable option is to build the reader yourself. All design files are available (PCB, BOM, firmware).<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' This version was based on a bistatic setup (2 antennas are required). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB.<br />
<br />
'''Version 0b''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was designed using a custom PCB. Tx and Rx paths were connected using a circulator (from Voyantic).<br />
<br />
'''Version 0c''' This version was based on a monostatic setup (single antenna). The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1<math>\alpha</math>''' RF signal generation is based on the Melexis chip (obselete). This version was based on a monostatic setup (single antenna). Tx and Rx paths were connected using a circulator. Only one board have been designed and built at LCIS. A picture of the prototype can be seen in the journal article.<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider (which is much cheaper than a circulator). Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz<ref> N. Barbot, "Hands-on 2.4 GHz RFID," 2023 IEEE 13th International Conference on RFID Technology and Applications (RFID-TA), Aveiro, Portugal, 2023, pp. 245-247</ref>. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=529Simple Low Cost Open Source UHF RFID Reader2024-08-05T18:31:26Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
If you are interested by this project, the more valuable option is to build the reader yourself. All design files are available (PCB, BOM, firmware).<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. This version was based on a bistatic setup (2 antennas are required).<br />
<br />
'''Version 0b''' The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. This version was based on a monostatic setup (single antenna).<br />
Tx and Rx paths were connected using a circulator.<br />
<br />
'''Version 0c''' The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. This version was based on a monostatic setup (single antenna).<br />
Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider. Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== Awards ==<br />
<br />
The journal article article received the CRFID James Clerk Maxwell Best Journal Paper Award 2024 during the IEEE RFID conference in Boston.<br />
<br />
== References ==</div>Nicohttps://nicolas-barbot.ovh/wiki/index.php?title=Simple_Low_Cost_Open_Source_UHF_RFID_Reader&diff=528Simple Low Cost Open Source UHF RFID Reader2024-08-05T18:28:20Z<p>Nico: </p>
<hr />
<div>This page presents a simple low-cost SDR RFID UHF reader capable of reading a tag in real time. This work is a direct continuation of the initial design proposed in<ref> P. V. Nikitin, S. Ramamurthy, and R. Martinez, “Simple Low Sost UHF RFID Reader,” in 2013 IEEE International Conference on RFID (RFID), Orlando, FL, USA, Apr. 2013, pp. 1–2.</ref>. This reader is designed around a simple asynchronous OOK modulator<br />
in transmission and an envelope detector in reception. All tasks specific to the RFID protocol including clock recovery, data recovery and frame detection are handled in software by a Arduino Uno micro-controller. <br />
This reader is able to generate any RFID command supported by the protocol and to decode any message backscattered by the tag in real time. The details of hardware and software associated with this reader are released in open source for the community.<br />
<br />
Information presented in this page has been directly extracted from <ref>N. Barbot, R. De Amorim Junior and P. Nikitin, [https://nicolas-barbot.ovh/wiki/pool/reader.pdf “Simple Low Cost Open Source UHF RFID Reader,”] in Journal of Radio Frequency Identification, vol. 7, pp. 20-26, 2023</ref>. Source code of this project is included in a [https://github.com/nicolas-barbot/SDR_UHF_RFID_reader Github repository]. This page also included some additional information added by other researchers.<br />
<br />
== Getting Started ==<br />
<br />
If you are interested by this project, the more valuable option is to build the reader yourself. All design files are available (PCB, BOM, firmware).<br />
<br />
== Official Versions ==<br />
<br />
'''Version 0a''' The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. This version was based on a bistatic setup (2 antennas are required).<br />
<br />
'''Version 0b''' The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. This version was based on a monostatic setup (single antenna).<br />
Tx and Rx paths were connected using a circulator.<br />
<br />
'''Version 0c''' The Melexis evaluation board was used for transmitting the RFID signal. The receiver was a custom PCB. This version was based on a monostatic setup (single antenna).<br />
Tx and Rx paths were connected using a power divider.<br />
<br />
'''Version 1a''' RF signal generation is based on the Melexis chip (obselete). Tx and Rx paths were connected using a power divider. Four boards have been designed and built at University of Washington during a visit in May 2024. These boards will be used for RFID-TA 2025 conference.<br />
<br />
'''Version 1b''' RF signal generation is based on the Atmel ATA8403 chip. This chip offers a lower Tx power (compared to the Melexis one). Tx and Rx paths were connected using a power divider.<br />
<br />
== Unofficial Versions ==<br />
<br />
'''Reader at 2.4 GHz''' This modification allows one to operate the RFID reader at 2.4 GHz. Since tags at this frequency can not easily be found, the modification of a 915 MHz is also proposed.<br />
<br />
== References ==</div>Nico