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A Tapered Whisker-Based Physical Reservoir Computing System for Mobile Robot Terrain Identification in Unstructured Environments

Zhenhua Yu, Shehara Perera, Helmut Häuser, Peter Childs, Thrishantha Nanayakkara

2022IEEE Robotics and Automation Letters25 citationsDOI

Abstract

In this letter, we present for the first time the use of tapered whisker-based reservoir computing (TWRC) system mounted on a mobile robot for terrain classification and roughness estimation of unknown terrain. Hall effect sensors captured the oscillations at different locations along a tapered spring that served as a reservoir to map time-domain vibrations signals caused by the interaction perturbations from the ground to frequency domain features directly. Three hall sensors are used to measure the whisker reservoir outputs and these temporal signals could be processed efficiently by the proposed TWRC system which can provide morphological computation power for data processing and reduce the model training cost compared to the convolutional neural network (CNN) approaches. To predict the unknown terrain properties, an extended TWRC method including a novel detector is proposed based on the Mahalanobis distance in the Eigen space, which has been experimentally demonstrated to be feasible and sufficiently accurate. We achieved a prediction success rate of 94.3% for six terrain surface classification experiments and 88.7% for roughness estimation of the unknown terrain surface.

Topics & Concepts

TerrainComputer scienceMahalanobis distanceArtificial intelligenceMobile robotDetectorConvolutional neural networkSurface roughnessComputer visionRemote sensingRobotGeologyTelecommunicationsPhysicsBiologyEcologyQuantum mechanicsNeural Networks and Reservoir ComputingNeural Networks and ApplicationsModel Reduction and Neural Networks
A Tapered Whisker-Based Physical Reservoir Computing System for Mobile Robot Terrain Identification in Unstructured Environments | Litcius