Leveraging Symmetry in RL-based Legged Locomotion Control
CoRR(2024)
Abstract
Model-free reinforcement learning is a promising approach for autonomously
solving challenging robotics control problems, but faces exploration difficulty
without information of the robot's kinematics and dynamics morphology. The
under-exploration of multiple modalities with symmetric states leads to
behaviors that are often unnatural and sub-optimal. This issue becomes
particularly pronounced in the context of robotic systems with morphological
symmetries, such as legged robots for which the resulting asymmetric and
aperiodic behaviors compromise performance, robustness, and transferability to
real hardware. To mitigate this challenge, we can leverage symmetry to guide
and improve the exploration in policy learning via equivariance/invariance
constraints. In this paper, we investigate the efficacy of two approaches to
incorporate symmetry: modifying the network architectures to be strictly
equivariant/invariant, and leveraging data augmentation to approximate
equivariant/invariant actor-critics. We implement the methods on challenging
loco-manipulation and bipedal locomotion tasks and compare with an
unconstrained baseline. We find that the strictly equivariant policy
consistently outperforms other methods in sample efficiency and task
performance in simulation. In addition, symmetry-incorporated approaches
exhibit better gait quality, higher robustness and can be deployed zero-shot in
real-world experiments.
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