RFID sensors based on ubiquitous passive 13.56-MHz RFID tags and complex impedance detection

被引:49
作者
Potyrailo, Radislav A. [1 ]
Morris, William G. [2 ]
Sivavec, Timothy [3 ]
Tomlinson, Harold W. [4 ]
Klensmeden, Staffan [5 ]
Lindh, Kenneth [6 ]
机构
[1] Gen Elect Global Res Ctr, Chem & Biol Sensing Lab, Niskayuna, NY USA
[2] Gen Elect Global Res Ctr, Mat Anal & Screening Lab, Niskayuna, NY USA
[3] Gen Elect Global Res Ctr, Pervas Decisioning Syst Lab, Niskayuna, NY USA
[4] Gen Elect Global Res Ctr, Signal Elect & Embedded Syst Lab, Niskayuna, NY USA
[5] GE Healthcare, Life Sci Bio Technol R&D LabSyst, Uppsala, Sweden
[6] GE Healthcare, Life Sci R&D Prot Sci & Bio Proc Instruments Lab, Uppsala, Sweden
关键词
radio frequency identification (RFID) tag; RFID sensor; physical sensing; chemical sensing; complex impedance; multivariate statistical analysis; RADIO-FREQUENCY IDENTIFICATION; RESONANT-CIRCUIT; WIRELESS; QUANTITATION; POLYANILINE; TRANSPONDER; DESIGN;
D O I
10.1002/wcm.711
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
Passive radio frequency identification (RFID) sensors are attractive in diverse applications where sensor performance is needed at a low cost and when battery-free operation is critical. We developed a general approach for adapting ubiquitous and cost-effective passive 13.56-MHz RFID tags for diverse sensing applications. In developed RFID sensors, the complex impedance of the RFID resonant antenna is measured and correlated to physical, chemical, or biological properties of interest. In contrast to known wireless sensors, developed RFID sensors combine several measured parameters from the resonant sensor antenna with multivariate data analysis and deliver unique capability for multianalyte sensing and rejection of environmental interferences with a single sensor. Theoretical calculations and experiments in an anechoic chamber demonstrate that the developed RFID sensors are immune to common electromagnetic interferences and the sensor/reader system operates within regulated emission levels. Performance of developed RFID sensors is illustrated in measurements of toxic industrial chemicals (TICs) in air with the detection limit (DL) of 80 parts per billion and in a non-invasive monitoring of milk spoilage. Sensors selectivity is demonstrated in the detection of different vapors with individual sensors. Copyright (C) 2008 John Wiley & Sons, Ltd.
引用
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页码:1318 / 1330
页数:13
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