Estimating TOA Reliability With Variational Autoencoders

Maximilian Stahlke,Felix Ott,Christopher Mutschler,Tobias Feigl,Sebastian Kram

doi:10.1109/jsen.2021.3101933

Maximilian Stahlke, Felix Ott + Show 3 more

Open Access

https://doi.org/10.1109/jsen.2021.3101933

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Abstract

Radio frequency (RF)-based localization yields centimeter-accurate positions under mild propagation conditions. However, propagation conditions predominant in indoor environments (e.g. industrial production) are often challenging as signal blockage, diffraction and dense multipath lead to errors in the time of flight (TOF) estimation and hence to a degraded localization accuracy. A major topic in high-precision RF-based localization is the identification of such anomalous signals that negatively affect the localization performance, and to mitigate the errors introduced by them. As such signal and error characteristics depend on the environment, data-driven approaches have shown to be promising. However, there is a trade-off to a bad generalization and a need for an extensive and time-consuming recording of training data associated with it. We propose to use generative deep learning models for out-of-distribution detection based on channel impulse responses (CIRs). We use a Variational Autoencoder (VAE) to predict an anomaly score for the channel of a TOF-based Ultra-wideband (UWB) system. Our experiments show that a VAE trained only on line-of-sight (LOS) training data generalizes well to new environments and detects non-line-of-sight CIRs with an accuracy of 85%. We also show that integrating our anomaly score into a TOF-based extended Kalman filter (EKF) improves tracking performance by over 25%.

Highlights

High precision radio frequency (RF) localization enables many indoor applications including the monitoring of production facilities or robot localization
Our experiments with real world channel impulse responses (CIRs) from a Ultra wideband (UWB)-system show that we outperform existing one-class and unsupervised approaches in the detection of NLOS CIRs but that we can considerably improve the tracking accuracy in a challenging mixed environment
We show that we enable both (1) an NLOS identification and (2) an estimation of error variance and bias to enhance the tracking performance of a TOF-based extended Kalman filter (EKF)

Summary

Introduction

High precision radio frequency (RF) localization enables many indoor applications including the monitoring of production facilities or robot localization Technologies such as Wi-Fi [1], Bluetooth [2], RFID [3], and Ultra wideband (UWB) have been developed and optimized over recent years [4] to achieve this. In contrast to most localization systems that yield localization accuracies in the meter or decimeter range, UWB uses a high bandwidth to estimate positions in the centimeter range. This requires optimal signal propagation conditions with a line of sight (LOS) between transmitters and receivers, which can only rarely be found in (industrial) environments. MPCs can overlap with the direct path and a lower signal to noise ratio

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