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Combining Learning-Based Locomotion Policy With Model-Based Manipulation for Legged Mobile Manipulators

Yuntao Ma, Farbod Farshidian, Takahiro Miki, Joonho Lee, Marco Hutter

2022IEEE Robotics and Automation Letters76 citationsDOIOpen Access PDF

Abstract

Deep reinforcement learning produces robust locomotion policies for legged robots over challenging terrains. To date, few studies have leveraged model-based methods to combine these locomotion skills with the precise control of manipulators. Here, we incorporate external dynamics plans into learning-based locomotion policies for mobile manipulation. We train the base policy by applying a random wrench sequence on the robot base in simulation and add the noisified wrench sequence prediction to the policy observations. The policy then learns to counteract the partially-known future disturbance. The random wrench sequences are replaced with the wrench prediction generated with the dynamics plans from model predictive control to enable deployment. We show zero-shot adaptation for manipulators unseen during training. On the hardware, we demonstrate stable locomotion of legged robots with the prediction of the external wrench.

Topics & Concepts

WrenchTerrainReinforcement learningComputer scienceArtificial intelligenceRobotHexapodSequence (biology)Adaptation (eye)Base (topology)Software deploymentControl (management)Control theory (sociology)EngineeringMathematicsOpticsEcologyGeneticsBiologyMathematical analysisOperating systemMechanical engineeringPhysicsRobotic Locomotion and ControlReinforcement Learning in RoboticsSoftware Testing and Debugging Techniques
Combining Learning-Based Locomotion Policy With Model-Based Manipulation for Legged Mobile Manipulators | Litcius