Lane Detection Aided Online Dead Reckoning for GNSS Denied Environments

Jinhwan Jeon,Yoonjin Hwang,In So Kweon,Seibum B Choi,Sangdon Park,Yongseop Jeong

doi:10.3390/s21206805

Jinhwan Jeon, Yoonjin Hwang + Show 4 more

Open Access

https://doi.org/10.3390/s21206805

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Abstract

With the emerging interest of autonomous vehicles (AV), the performance and reliability of the land vehicle navigation are also becoming important. Generally, the navigation system for passenger car has been heavily relied on the existing Global Navigation Satellite System (GNSS) in recent decades. However, there are many cases in real world driving where the satellite signals are challenged; for example, urban streets with buildings, tunnels, or even underpasses. In this paper, we propose a novel method for simultaneous vehicle dead reckoning, based on the lane detection model in GNSS-denied situations. The proposed method fuses the Inertial Navigation System (INS) with learning-based lane detection model to estimate the global position of vehicle, and effectively bounds the error drift compared to standalone INS. The integration of INS and lane model is accomplished by UKF to minimize linearization errors and computing time. The proposed method is evaluated through the real-vehicle experiments on highway driving, and the comparative discussions for other dead-reckoning algorithms with the same system configuration are presented.

Highlights

Precise positioning and localization techniques for modern land vehicles have been widely implemented for the purpose of advanced driving assist system and autonomous driving capability
Since land vehicles are designed to be driven on the road, the positioning accuracy of Global Navigation Satellite System (GNSS) can be compensated with the road map from Geographic Information System (GIS) [1,2,3,4] for the conventional navigation purpose, and even with the real time kinematics (RTK) techniques [5,6], its positioning performance can be improved up to centimeter-level accuracy
We focus on the outdoor, especially highway situations because urban and indoor online vehicle localization can be achieved in high accuracy by existing visual odometry(VO) or SLAM methods

Summary

Introduction

Precise positioning and localization techniques for modern land vehicles have been widely implemented for the purpose of advanced driving assist system and autonomous driving capability. To overcome the environmental limitation of the GNSS measurement, several alternative navigation methods with other types of measurements are introduced to ensure the consistency of positional information and improve the minimum performance under a poor satellite signal condition [9,10,11]. Those methods, well known as dead-reckoning (DR), are based on the cumulative process of relative change in the speed and direction from the latest known position

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