Reflected electro-material signatures for self-sensing passive RFID sensors

2011 IEEE International Conference on RFID Pub Date : 2011-04-12 DOI:10.1109/RFID.2011.5764638

Azhar Hasan, A. Peterson, G. Durgin

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引用次数: 9

Abstract

In this paper, we evaluate realizations for implementing an RFID reflected electro-material signature (REMS) sensor. REMS sensors allow passive measurement, recording, and reading of environmental data such as temperature in a small, low cost device. This paper presents results from two configurations: a three-section lossless microstrip transmission line and a monopole probe inserted into a lossy medium. A neural network is used to recover the permittivity profile in either case, based on the reflection coefficient of the wave backscattered from an RF tag. The neural network incorporating the Levenberg Marquardt back-propagation algorithm is evaluated in terms of average error, regression analysis and computational efficiency in the presence of realistic noise. A unique contribution of this paper is the exploration of REMS using a dissipative electro-material medium. In the lossy case, two real-valued neural networks are integrated together to reconstruct the complex permittivity from the measured reflection coefficient. The approach is verified over the frequency range 4.0–5.0 GHz and less than 4% error was observed in presence of white Gaussian noise with 10dB SNR.

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自感无源RFID传感器的反射电材料特征

在本文中，我们评估了实现RFID反射电材料签名(REMS)传感器的实现。REMS传感器允许无源测量，记录和读取环境数据，如温度在一个小的，低成本的设备。本文介绍了两种结构的结果:一种是三段无损微带传输线，另一种是插入有损介质的单极探针。基于射频标签反向散射波的反射系数，使用神经网络来恢复两种情况下的介电常数分布。结合Levenberg Marquardt反向传播算法的神经网络在实际噪声存在下的平均误差、回归分析和计算效率进行了评估。本文的一个独特贡献是利用耗散电材料介质探索REMS。在有损情况下，将两个实值神经网络整合在一起，从测量的反射系数重构复介电常数。该方法在4.0 ~ 5.0 GHz频率范围内进行了验证，在信噪比为10dB的高斯白噪声存在下，误差小于4%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2011 IEEE International Conference on RFID

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