Hardware implementations of the WG-5 cipher for passive RFID tags

2013 IEEE International Symposium on Hardware-Oriented Security and Trust (HOST) Pub Date : 2013-06-02 DOI:10.1109/HST.2013.6581561

M. Aagaard, G. Gong, Rajesh K. Mota

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引用次数: 19

Abstract

This paper presents two versions of a Welch-Gong cipher designed for use in passive RFID tags. The low-cost and low-power requirements for passive RFID tags impose stringent design constraints for the chips used in the tags. The WG5-80(x) cipher operates over the finite field F25, and has an 80-bit secret key and 80-bit initialization vector. WG5-80(x11) is the same as WG5-80(x), but includes a decimation function of x11, which increases the linear complexity at the cost of losing the 1-order resiliency property that is inherent in the WG-transform. Both ciphers can be implemented using parallel LFSRs to provide throughputs ranging from one to twenty-five bits per clock cycle. On a 130 nm fabrication process with a clockspeed of 100 kHz and a throughput of 100 kbps, WG5-80(x) has an area of 1229 GE (gate equivalents) and a power consumption of 0.78 μW. The linear complexity of the cipher is 217. The corresponding numbers for WG5-80(x11) are 1235GE, 0.79 μW, and 222. This paper presents results for a 130 nm and a 180 nm process, and data rates of 100 kbps and 200 kbps. The combined area and power results for the WG5 ciphers are approximately 5% better than previous results for low-data-rate ciphers. In addition, WG-ciphers offer mathematically guaranteed randomness and cryptographic properties not provided by other ciphers.

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无源RFID标签的WG-5密码的硬件实现

本文提出了用于无源RFID标签的两个版本的Welch-Gong密码。无源RFID标签的低成本和低功耗要求对标签中使用的芯片施加了严格的设计约束。WG5-80(x)密码在有限域F25上运行，并具有80位密钥和80位初始化向量。WG5-80(x11)与WG5-80(x)相同，但包含了x11的抽取函数，它以失去wg变换中固有的1阶弹性属性为代价增加了线性复杂性。这两种密码都可以使用并行lfsr来实现，以提供每个时钟周期1到25位的吞吐量。在时钟速度为100 kHz、吞吐量为100 kbps的130 nm制造工艺下，WG5-80(x)的面积为1229 GE(栅极当量)，功耗为0.78 μW。该密码的线性复杂度为217。WG5-80(x11)对应的编号为1235GE、0.79 μW和222。本文介绍了在130 nm和180 nm工艺下的结果，数据速率分别为100 kbps和200 kbps。WG5密码的综合面积和功率结果比以前的低数据速率密码的结果大约好5%。此外，wg密码提供数学上保证的随机性和其他密码不提供的加密特性。

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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来源期刊

2013 IEEE International Symposium on Hardware-Oriented Security and Trust (HOST)

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