Open Access
MATEC Web Conf.
Volume 75, 2016
2016 International Conference on Measurement Instrumentation and Electronics (ICMIE 2016)
Article Number 10002
Number of page(s) 4
Section The Technology of Electronic Circuit
Published online 01 September 2016
  1. K. Souri, K. A. A. Makinwa. A 0.12 mm2 7.4μW micropower temperature sensor with an inaccuracy of ±0.2℃ (3σ) From -30℃ to 125℃[J]. IEEE J. Solid-State Circuits, 2011, 46(7): 1693–1700 [CrossRef]
  2. D. Yeager, F. Zhang, A. Zarrasvand, et al.. A 9.2μA gen 2 compatible UHF RFID sensing tag with -12dBm ensitivity and 1.25μVrms input-referred noise floor[C]. IEEE International Solid-State Circuits Conference Proceedings, San Francisco, 2010, 52–53
  3. Kong Jin’ou. Maxwell Equation. Beiing: Higher Education Press. 2004
  4. Y. Wang, G. Wen, W. Mao, et al.. Design of a passive UHF RFID tag for the ISO/IEC18000-6C protocol[J]. 2011, J. Semicond., 32(5): 055009 [CrossRef]
  5. Impinj,Inc.. Gen 2 tag clock rate—what you need to know[EB/OL]. .im in . n/a i ati ns/ Ta C ate 200 1001. d, Oct 1, 2005
  6. Wang Zheng. Studies on Air Interface Protocol and System Design for UHF RFID [D]. Tianjin: Tianjin University, 2011, 102–108
  7. G. De Vita, F. Marraccini, G. Iannaccone. Low-voltage low-power CMOS oscillator with low temperature and process sensitivity[C]. IEEE International Symposium on Circuits and Systems, New Orleans, 2007, 2152–2155
  8. R. Barnett, J. Liu. A 0.8V 1.52MHz MSVC relaxation oscillator with inverted mirror feedback reference for UHF RFID[C]. IEEE Custom Integrated Circuits Conference, San Jose, 2006, 769–772
  9. Y. Wang ,J. Liu, L. Xie, et al.. An ultra-low-power oscillator with temperature and process compensation for UHF RFID transponder[J]. Radioengineering, 2013, 22(2): 505–510
  10. B. Razavi. Design of analog CMOS integrated circuits[M]. New York: McGraw-Hill, 2000.
  11. K. Ueno, T. Hirose, T. Asai, et al.. A 300 nW, 15 ppm/℃, 20 ppm/V CMOS voltage reference circuit consisting of subthreshold MOSFETs[J]. IEEE J. Solid-State Circuits, 2009, 44(7): 2047–2054 [CrossRef]
  12. F. Aghlmand, M. Atarodi, S. Saeedi. Low phase noise on-chip oscillator for implantable biomedical applications [C]. IEEE International Symposium on Circuits and Systems Proceedings, Rio De Janeiro, 2011, 213–216
  13. S. Ayazian, V. A. Akhavan, E. Soenen. A photovoltaic-driven and energy-autonomous CMOS implantable sensor[J]. IEEE Transactions on Biomedical Circuits and Systems, 2012, 6(4): 336–343 [CrossRef]
  14. K. Choe, O. D. Bernal, D. Nuttman, et al.. A precision relaxation oscillator with a self-clocked offset-cancellation scheme for implantable biomedical SoCs[C]. IEEE International Solid-State Circuits Conference Proceedings, San Francisco, 2009, 402–403
  15. H. Okada, T. Itoh, T. Masuda. Development of custom CMOS LSI for ultra-low power wireless sensor node in health monitoring systems[C]. IEEE Sensors Proceedings, Limerick, 2011, 1197–1200
  16. Wangyao, Wangguangjun. Demodulation circuit for ultra high frequency radio frequency identification tag chip[P]. China, invention patent, ZL. 201010568305, April 30, 2012 Wang Yao, Wen Guangjun. Demodulation Circuit for Ultral High Frequency RFID Tag Chips [P]. China, Patent of Invention ZL. 201010568305, April 30, 2012.
  17. R.E. Barnett. High efficiency RF to DC conversion and ultra-low-power analog front end circuits for low-cost field-powered UHF RFID[D]. Dallas: University of Texas at Dallas, 2007, 30–36

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