Abstract

Localization using ultra-wide band (UWB) signals gives accurate position results for indoor localization. The penetrating characteristics of UWB pulses reduce the multipath effects and identify the user position with precise accuracy. In UWB-based localization, the localization accuracy depends on the distance estimation between anchor nodes (ANs) and the UWB tag based on the time of arrival (TOA) of UWB pulses. The TOA errors in the UWB system, reduce the distance estimation accuracy from ANs to the UWB tag and adds the localization error to the system. The position accuracy of a UWB system also depends on the line of sight (LOS) conditions between the UWB anchors and tag, and the computational complexity of localization algorithms used in the UWB system. To overcome these UWB system challenges for indoor localization, we propose a deep learning approach for UWB localization. The proposed deep learning model uses a long short-term memory (LSTM) network for predicting the user position. The proposed LSTM model receives the distance values from TOA-distance model of the UWB system and predicts the current user position. The performance of the proposed LSTM model-based UWB localization system is analyzed in terms of learning rate, optimizer, loss function, batch size, number of hidden nodes, timesteps, and we also compared the mean localization accuracy of the system with different deep learning models and conventional UWB localization approaches. The simulation results show that the proposed UWB localization approach achieved a 7 cm mean localization error as compared to conventional UWB localization approaches.

Highlights

  • Recent advancements in indoor localization technologies [1] give accurate position results when the GPS signals are unable to detect user position in an indoor scenario

  • The anchors and the tag communicate through ultra-wide band (UWB) signals and the time of arrival (TOA) [2] of UWB signals are used to estimate the distance of the user from anchors

  • The best parameters for long short-term memory (LSTM) networks are identified through several simulation results and we compare the proposed model prediction results with conventional UWB localization approaches such as linearized least square estimation (LLSE), fingerprint estimation (FPE), maximum likelihood estimation (MLE)

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Summary

Introduction

Recent advancements in indoor localization technologies [1] give accurate position results when the GPS signals are unable to detect user position in an indoor scenario. Sci. 2020, 10, 6290 channel conditions between anchors and tag, and the UWB signal shapes affect the distance estimation accuracy. This leads to a high position error in the UWB localization systems. To reduce the user position errors in the UWB system, we propose a deep learning approach to UWB localization. The proposed model uses a two layer long short-term memory (LSTM) network [4] which identifies the accurate user positions. The best parameters for LSTM networks are identified through several simulation results and we compare the proposed model prediction results with conventional UWB localization approaches such as linearized least square estimation (LLSE), fingerprint estimation (FPE), maximum likelihood estimation (MLE).

Related Work
The Conventional and Proposed UWB Localization Approaches
UWB Model
Trilateration Approach for UWB Localization
LSTM Based UWB Localization
Simulation Results and Analysis
Conclusions

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