Beamforming Feedback-Based Line-of-Sight Identification Toward Firmware-Agnostic WiFi Sensing

IF 5.3 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Open Journal of Vehicular Technology Pub Date : 2024-08-08 DOI:10.1109/OJVT.2024.3440400
Hiroki Shimomura;Koji Yamamoto;Takayuki Nishio;Akihito Taya
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Abstract

This study realizes firmware-agnostic line-of-sight (LOS) identification to extend the range of WiFi-sensing applications. We developed a beamforming feedback (BFF)-based LOS identification algorithm. BFF frames are transmitted for multiple-input multiple-output (MIMO) communications. They can be obtained by capturing frames without custom firmware or specific chipsets and contain a beamforming feedback matrix (BFM) and subcarrier-averaged stream gain (SSG). These provide partial channel state information (CSI), and there are two major calculation steps involved from the CSI to the BFF: unquantized BFF (UQBFF) calculation and quantization. Focusing on the relationship between singular value decomposition and principal component analysis, we numerically demonstrated that the first column vectors of the BFM reflect the LOS/NLOS conditions. Therefore, the proposed BFF-based method extracts features from the first-column vectors of the BFM. In addition, SSGs were leveraged to improve the accuracy. To demonstrate the feasibility of the proposed method, we conducted experiments using commodity off-the-shelf devices compliant with the IEEE 802.11ac standard. In the experimental evaluation, the proposed BFF-based method achieved an identification accuracy of 75.0%, whereas the CSI-based method achieved an accuracy of 81.2%. Accuracy comparisons revealed that the accuracy degradation of the BFF-based identification from the CSI-based identification was primarily caused by UQBFF calculations rather than quantization.
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基于波束成形反馈的视线识别,实现固件诊断式 WiFi 传感
本研究实现了与固件无关的视线(LOS)识别,以扩大 WiFi 传感应用的范围。我们开发了一种基于波束成形反馈(BFF)的 LOS 识别算法。BFF 帧是为多输入多输出(MIMO)通信而传输的。它们可以通过捕获帧获得,无需定制固件或特定芯片组,并包含波束成形反馈矩阵(BFM)和子载波平均流增益(SSG)。这些信息提供了部分信道状态信息(CSI),从 CSI 到 BFF 涉及两个主要计算步骤:未量化 BFF(UQBFF)计算和量化。针对奇异值分解和主成分分析之间的关系,我们用数值方法证明了 BFM 的第一列向量反映了 LOS/NLOS 条件。因此,所提出的基于 BFF 的方法可从 BFM 的第一列向量中提取特征。此外,还利用了 SSG 来提高精确度。为了证明所提方法的可行性,我们使用符合 IEEE 802.11ac 标准的现成商品设备进行了实验。在实验评估中,所提出的基于 BFF 的方法达到了 75.0% 的识别准确率,而基于 CSI 的方法达到了 81.2% 的准确率。准确度比较显示,与基于 CSI 的识别方法相比,基于 BFF 的识别方法的准确度下降主要是由 UQBFF 计算而非量化造成的。
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来源期刊
CiteScore
9.60
自引率
0.00%
发文量
25
审稿时长
10 weeks
期刊最新文献
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