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超声定位系统中用于位置估计的加权广义互相关相位变换(GCC-PHAT)的动态调整

Dynamic Adjustment of Weighted GCC-PHAT for Position Estimation in an Ultrasonic Local Positioning System.

作者信息

Villadangos José Manuel, Ureña Jesús, García-Domínguez Juan Jesús, Jiménez-Martín Ana, Hernández Álvaro, Pérez-Rubio Mª Carmen

机构信息

Department of Electronics, University of Alcalá, 28801 Madrid, Spain.

出版信息

Sensors (Basel). 2021 Oct 24;21(21):7051. doi: 10.3390/s21217051.

DOI:10.3390/s21217051
PMID:34770358
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8587089/
Abstract

Ultrasonic local positioning systems (ULPS) have been brought to the attention of researchers as one of the possibilities that can be used for indoor localization. Acoustic systems combine a suitable trade-off between precision, ease of development, and cost. This work proposes a method for measuring the time of arrival of encoded emissions from a set of ultrasonic beacons, which are used to implement an accurate ULPS. This method uses the generalized cross-correlation technique with PHAT filter and weighting factor (GCC-PHAT-). To improve the performance of the GCC-PHAT- in encoded emission detection, the employment is proposed of mixed-medium multiple-access techniques, based on code division and time division multiplexing of beacon emissions (CDMA and TDMA respectively), and to dynamically adjust the PHAT filter weighting factor. The receiver position is obtained by hyperbolic multilateration from the time differences of arrival (TDoA) between a reference beacon and the rest, thus avoiding the need for receiver synchronization. The results show how the dynamic adaptation of the weighting factor significantly reduces positioning errors from 20 cm to 2 cm in 80% of measurements. The simulated and real experiments prove that the proposed algorithms improve the performance of the ULPS in situations with lower signal-to-noise ratios (SNR) than 0 dB and in environments where the multipath effect makes it difficult to correctly detect the encoded ultrasonic emissions.

摘要

超声波定位系统(ULPS)作为可用于室内定位的一种可能性已引起研究人员的关注。声学系统在精度、易于开发和成本之间实现了适当的权衡。这项工作提出了一种测量来自一组超声信标的编码发射到达时间的方法,这些信标用于实现精确的ULPS。该方法使用带有PHAT滤波器和加权因子的广义互相关技术(GCC-PHAT-)。为了提高GCC-PHAT-在编码发射检测中的性能,建议采用基于信标发射的码分复用和时分复用(分别为CDMA和TDMA)的混合介质多址技术,并动态调整PHAT滤波器加权因子。通过参考信标与其他信标之间的到达时间差(TDoA)进行双曲线多边定位来获得接收器位置,从而避免了接收器同步的需要。结果表明,加权因子的动态调整在80%的测量中显著将定位误差从20厘米降低到2厘米。模拟和实际实验证明,所提出的算法在信噪比(SNR)低于0 dB的情况下以及在多径效应使得难以正确检测编码超声发射的环境中提高了ULPS的性能。

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