Terrain-Dependent Slip Risk Prediction for Planetary Exploration Rovers-Reference-Cited by-同舟云学术

Terrain-Dependent Slip Risk Prediction for Planetary Exploration Rovers

Published:2021-02-23 Issue:10 Volume:39 Page:1883-1896
ISSN:0263-5747
Container-title:Robotica
language:en
Short-container-title:Robotica

Author:

Endo Masafumi^ORCID,Endo Shogo,Nagaoka Kenji,Yoshida Kazuya

Abstract

SUMMARYWheel slip prediction on rough terrain is crucial for secure, long-term operations of planetary exploration rovers. Although rough, unstructured terrain hampers mobility, prediction by modeling wheel–terrain interactions remains difficult owing to unclear terrain conditions and complexities of terramechanics models. This study proposes a vision-based approach with machine learning for predicting wheel slip risk by estimating the slope from 3D information and classifying terrain types from image information. It considers the slope estimation accuracy for risk prediction under sharp increases in wheel slip due to inclined ground. Experimental results obtained with a rover testbed on several terrain types validate this method.

Publisher

Cambridge University Press (CUP)

Subject

Computer Science Applications,General Mathematics,Software,Control and Systems Engineering

Reference25 articles.

1. [10] Schilling, F. , Chen, X. , Folkesson, J. and Jensfelt, P. , “Geometric and Visual Terrain Classfication for Autonomous Mobile Navigation,” Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems, Vancouver, BC, Canada (2017) pp. 2678–2684.

2. Slippage prediction for off-road mobile robots via machine learning regression and proprioceptive sensing

3. Self-supervised terrain classification for planetary surface exploration rovers

4. Slope traversal controls for planetary exploration rover on sandy terrain

5. Vehicle Detection Based on Perspective Transformation Using Rear-View Camera

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