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In situ slip estimation for mobile robots in outdoor environments

Payam Nourizadeh, Fiona Stevens McFadden, Will N. Browne

Year
2022
Citations
13
Access
Open access

Abstract

Abstract Accounting for wheel–terrain interaction is crucial for navigation and traction control of mobile robots in outdoor environments and rough terrains. Wheel slip is one of the surface hazards that needs to be detected to mitigate against the risk of losing the robot's controllability or mission failure occurring. The open problems in the Terramechanics field addressed are (1) the need for in situ wheel‐slippage estimation in harsh environments using low‐cost/power and easy to integrate sensors, and (2) removing the need for prior information of the soil, which is not always available. This paper presents a novel slip estimation method that utilizes only two proprioceptive sensors (IMU and wheel encoder) to estimate the wheel slip using deep learning methods. It is experimentally shown to be real‐world feasible in outdoor, uneven terrains without prior soil information assumptions. Comparison with previously used machine learning algorithms for continuous and discrete slip estimation problems show more than 9% and 14% improvement in estimation performance, respectively.

Keywords

SlippageTerrainSlip (aerodynamics)RobotControllabilityMobile robotInertial measurement unitComputer scienceEncoderArtificial intelligence

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