Home /Research /GLiDE: Generalizable Quadrupedal Locomotion in Diverse Environments with a Centroidal Model
LOCOMOTION

GLiDE: Generalizable Quadrupedal Locomotion in Diverse Environments with a Centroidal Model

Zhaoming Xie, Xingye Da, B. N. Babich, Animesh Garg, Michiel van de Panne

Year
2021
Citations
11
Access
Open access

Abstract

Model-free reinforcement learning (RL) for legged locomotion commonly relies on a physics simulator that can accurately predict the behaviors of every degree of freedom of the robot. In contrast, approximate reduced-order models are commonly used for many model predictive control strategies. In this work we abandon the conventional use of high-fidelity dynamics models in RL and we instead seek to understand what can be achieved when using RL with a much simpler centroidal model when applied to quadrupedal locomotion. We show that RL-based control of the accelerations of a centroidal model is surprisingly effective, when combined with a quadratic program to realize the commanded actions via ground contact forces. It allows for a simple reward structure, reduced computational costs, and robust sim-to-real transfer. We show the generality of the method by demonstrating flat-terrain gaits, stepping-stone locomotion, two-legged in-place balance, balance beam locomotion, and direct sim-to-real transfer.

Keywords

QuadrupedalismFidelityGeneralityComputer scienceHexapodReinforcement learningRobotTerrainRobot locomotionLegged robot

Related papers

Browse all LOCOMOTION papers