Abstract

This research proposes an algorithm that improves the position accuracy of indoor pedestrian dead reckoning, by compensating the position error with a magnetic field map-matching technique, using multiple magnetic sensors and an outlier mitigation technique based on roughness weighting factors. Since pedestrian dead reckoning using a zero velocity update (ZUPT) does not use position measurements but zero velocity measurements in a stance phase, the position error cannot be compensated, which results in the divergence of the position error. Therefore, more accurate pedestrian dead reckoning is achievable when the position measurements are used for position error compensation. Unfortunately, the position information cannot be easily obtained for indoor navigation, unlike in outdoor navigation cases. In this paper, we propose a method to determine the position based on the magnetic field map matching by using the importance sampling method and multiple magnetic sensors. The proposed method does not simply integrate multiple sensors but uses the normalization and roughness weighting method for outlier mitigation. To implement the indoor pedestrian navigation algorithm more accurately than in existing indoor pedestrian navigation, a 15th-order error model and an importance-sampling extended Kalman filter was utilized to correct the error of the map-matching-aided pedestrian dead reckoning (MAPDR). To verify the performance of the proposed indoor MAPDR algorithm, many experiments were conducted and compared with conventional pedestrian dead reckoning. The experimental results show that the proposed magnetic field MAPDR algorithm provides clear performance improvement in all indoor environments.

Highlights

  • A position is an important piece of information for personal navigation, and various methods have been used to obtain the position

  • We propose an ambiguity mitigation algorithm based on multiple-sensors and roughness weighting, in order to reduce outliers that are caused by similar magnetic fields

  • The results show that the outliers are reduced by the maximum of 62%, owing maximum of 62%, owing to the proposed technique, and overall position error is reduced by 40–86%

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Summary

Introduction

A position is an important piece of information for personal navigation, and various methods have been used to obtain the position. Finding a person’s indoor position is important because it can be used for workers with special duties, to improve work efficiency. Analyses of the positions of pedestrians can be used in various indoor applications, such as location-based services for marketing. In the case of the outdoors, the location information can be obtained by using the global navigation satellite system (GNSS), as well as other precision-navigation technologies that fuse GNSS and sensor data with map information. There is a limitation in using accurate position information for indoor cases because the GNSS signal is not available in general. Many research studies have been conducted to obtain accurate position information indoors, especially for robotics and personal navigation

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