OFDMA-Enabled Wi-Fi Backscatter

The 25th Annual International Conference on Mobile Computing and Networking Pub Date : 2019-08-05 DOI:10.1145/3300061.3300121

R. Zhao, Fengyuan Zhu, Yuda Feng, Siyu Peng, Xiaohua Tian, Hui Yu, Xinbing Wang

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引用次数: 61

Abstract

In this paper, we for the first time demonstrate how to enable OFDMA in Wi-Fi backscatter for capacity and concurrency enhancement. With our approach, the excitation signal is reflected, modulated and shifted to lie in the frequency band of the OFDM subcarrier by the tag; OFDMA is realized by coordinating tags to convey information to the receiver with orthogonal subcarriers concurrently through backscatter. The crux of the design is to achieve strict synchronization among communication components, which is more challenging than in regular OFDMA systems due to the more prominent hardware diversity and uncertainty for backscattering. We reveal how the subtle asychnronization scenarios particularly for backscattering can incur system offsets, and present a series of novel designs for the excitation signal transmitter, tag, and receiver to address the issue. We build a prototype in 802.11g OFDM framework to validate our design. Experimental results show that our system can achieve 5.2-16Mbps aggregate throughput by allowing 48 tags to transmit concurrently, which is 1.45-5x capacity and 48x concurrency compared with the existing design respectively. We also design an OFDMA tag IC, and the simulation and numerical analysis results show that the tag's power consumption is in tens of μW.

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启用ofdma的Wi-Fi反向散射

在本文中，我们首次演示了如何在Wi-Fi反向散射中启用OFDMA以增强容量和并发性。利用我们的方法，激励信号被标签反射、调制和移位到OFDM子载波的频带中;OFDMA是通过协调标签，通过反向散射将正交子载波的信息并发地传递给接收机来实现的。设计的关键是通信组件之间的严格同步，由于硬件多样性和后向散射的不确定性更为突出，这比常规OFDMA系统更具挑战性。我们揭示了微妙的不同步场景，特别是后向散射如何引起系统偏移，并提出了一系列新的设计，用于激励信号发射器，标签和接收器来解决这个问题。我们在802.11g OFDM框架中构建了一个原型来验证我们的设计。实验结果表明，在允许48个标签同时传输的情况下，我们的系统可以达到5.2-16Mbps的总吞吐量，与现有设计相比，容量和并发度分别提高了1.45-5倍和48倍。设计了一种OFDMA标签IC，仿真和数值分析结果表明，该标签的功耗在几十μW以内。

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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The 25th Annual International Conference on Mobile Computing and Networking

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