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Inferring Distributions of Parameterized Controllers for Efficient Sampling-Based Locomotion of Underactuated Robots

Raghu Aditya Chavali, Nathan D. Kent, Michael E. Napoli, Thomas M. Howard, Matthew Travers

发表年份
2019
引用次数
3

摘要

Sampling-based motion planning algorithms provide a means to adapt the behaviors of autonomous robots to changing or unknown a priori environmental conditions. However, as the size of the space over which a sampling-based approach needs to search is increased (perhaps due to considering robots with many degree of freedom) the computational limits necessary for real-time operation are quickly exceeded. To address this issue, this paper presents a novel sampling-based approach to locomotion planning for highly-articulated robots wherein the parameters associated with a class of locomotive behaviors (e.g., inter-leg coordination, stride length, etc.) are inferred in real-time using a sample-efficient algorithm. More specifically, this work presents a data-based approach wherein offline-learned optimal behaviors, represented using central pattern generators (CPGs), are used to train a class of probabilistic graphical models (PGMs). The trained PGMs are then used to inform a sampling distribution of inferred walking gaits for legged hexapod robots. Simulated as well as hardware results are presented to demonstrate the successful application of the online inference algorithm.

关键词

HexapodRobotComputer scienceA priori and a posterioriSampling (signal processing)Motion planningKinematicsProbabilistic logicArtificial intelligenceParameterized complexity

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