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一种具有新型解调电路和安全功能的超高频RFID标签芯片(英文) 被引量:3

A Security-Enhanced UHF RFID Transponder with Novel Demodulator
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摘要 设计一种具有新型解调电路和安全功能的超高频RFID标签芯片。该解调电路不需要单独的包络检测电路,而是利用标签芯片已有的整流器的第一级作为包络检测电路。同时还设计了一种特殊的均值检测电路,输出电压和包络信号之间有很大的电压差,使得比较器的设计更加容易。受标签和读写器距离的变化影响,包络信号的直流电压在很大范围内变化,因此还设计了具有轨到轨共模输入范围的比较器。为了保证标签和读写器之间通信的安全,在数字基带处理器中集成了128位的高级加密标准算法(AES)。整个标签芯片采用0.18μm工艺实现,芯片面积为880μm×950μm。测试结果表明,标签芯片可以解调出的射频输入信号最小幅度为100 mV,最大的数据率为160 kb/s。 The authors present a security-enhanced UHF RFID (radio-frequency identification) transponder with novel demodulator. The demodulator, which takes advantage of the rectifier's first stage as the envelop detector, dosen't need a separate envelop detector. A novel average detector is also designed, which generates an output voltage having large voltage difference with the envelop signal, making the design demand for the comparator less rigorous. Because the DC level of the envelop signals can vary significantly with the distance between transponder and reader, the comparator is designed to have rail-to-rail common mode input range. To ensure a security communication between transponder and reader, a 128-bit advanced encryption standard (AES) algorithm is employed in the baseband processor. The whole transponder chip is implemented in 0.18μm CMOS process with a die size of 880 μm×950μm. Measurement results show that the minimum input RF signal that can be demodulated is 100 mV and the maximum input data rate is 160 kb/s.
作者 沈劲鹏 王新安 刘珊 李守成 胡桐宁
机构地区 北京大学深圳研究生院集成微系统科学工程与应用重点实验室
出处 《北京大学学报(自然科学版)》 EI CAS CSCD 北大核心 2014年第2期214-220,共7页 Acta Scientiarum Naturalium Universitatis Pekinensis
基金 深圳市重点实验室提升计划(CXB201104210007A)资助
关键词 超高频RFID标签 解调电路 高级加密标准(AES) UHF RFID transponder demodulator AES
分类号 TP391.44 [自动化与计算机技术—计算机应用技术]
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参考文献12

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同被引文献21

  • 1Wang Li, Xu Lida, Bi Zhuming, et al. Data cleaning for RFID and WSN integration [ J ]. IEEE Transactions on In- dustrial Informatics, 2014,10( 1 ) :408-418.
  • 2Papetti P, Costa C, Antonucci F, et al. A RFID web-based infotracing system for the artisanal Italian cheese quality traceability[ J]. Food Control, 2012,27( 1 ) :234-241.
  • 3Jedermann R, Becker M, Gorg C, et al. Testing network protocols and signal attenuation in packed food transports [ J ]. International Journal of Sensor Networks, 2011,9 (3/ 4) :170-181.
  • 4Sumithra S, Victoire T A A. An efficient energy clustering by dynamic multi-chain model in WSN [ J ]. International Review on Computers and Software ( IRECOS), 2014,9 (8) :1392-1398.
  • 5Mortazavi S H, Salehe M, MacGregor M H. Maximum WSN coverage in environments of heterogeneous path loss [J]. International Journal of Sensor Networks, 2014, 16 (3) :185-198.
  • 6Ruiz-Garcia L, Lunadei L. The role of RFID in agricul- ture: Applications, limitations and challenges [ J ]. Com- puters and Electronics in Agriculture, 2011,79 ( 1 ) :42-50.
  • 7Kaushik A, Vasudev A, Arya S K, et al. Recent advances in cortisol sensing technologies for point-of-care application [ J]. Biosensors and Bioelectronics, 2014,53:499-512.
  • 8Gao Lei, Lan Yuandong. Energy saving application of data fusion algorithm in ZigBec networks [ J ]. International Journal of Applied Mathematics and Statistics, 2014,52 (2) :86-97.
  • 9Ruiz-Garcia L, Barreiro P, Robla J I. Performance of Zig- Bee-based wireless sensor nodes for real-time monitoring of fruit logistics [ J ]. Journal of Food Engineering, 2008,87 (3) :405-415.
  • 10Jedermann R, Geyer M, Praeger U, et al. Sea transport of bananas in containers: Parameter identification for a tem- perature model [ J ]. Journal of Food Engineering, 2013, 115 (3) :330-338.

引证文献3

北京大学学报(自然科学版)
2014年 第2期

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