ManyQuadrupeds: Learning a Single Locomotion Policy for Diverse Quadruped Robots

TL;DR

This paper presents a novel approach to train a single locomotion policy for diverse quadruped robots by mimicking animal motor control, enabling effective control across different morphologies, masses, and sizes with successful sim-to-real transfer.

Contribution

We introduce a biologically inspired locomotion policy that generalizes across various quadruped robots with different morphologies and masses, reducing the need for retraining for each robot.

Findings

Single policy controls diverse robots effectively

Robust sim-to-real transfer demonstrated on Unitree robots

Policy maintains performance with added payloads

Abstract

Learning a locomotion policy for quadruped robots has traditionally been constrained to a specific robot morphology, mass, and size. The learning process must usually be repeated for every new robot, where hyperparameters and reward function weights must be re-tuned to maximize performance for each new system. Alternatively, attempting to train a single policy to accommodate different robot sizes, while maintaining the same degrees of freedom (DoF) and morphology, requires either complex learning frameworks, or mass, inertia, and dimension randomization, which leads to prolonged training periods. In our study, we show that drawing inspiration from animal motor control allows us to effectively train a single locomotion policy capable of controlling a diverse range of quadruped robots. The robot differences encompass: a variable number of DoFs, (i.e. 12 or 16 joints), three distinct morphologies, a broad mass range spanning from 2 kg to 200 kg, and nominal standing heights ranging from 18 cm to 100 cm. Our policy modulates a representation of the Central Pattern Generator (CPG) in the spinal cord, effectively coordinating both frequencies and amplitudes of the CPG to produce rhythmic output (Rhythm Generation), which is then mapped to a Pattern Formation (PF) layer. Across different robots, the only varying component is the PF layer, which adjusts the scaling parameters for the stride height and length. Subsequently, we evaluate the sim-to-real transfer by testing the single policy on both the Unitree Go1 and A1 robots. Remarkably, we observe robust performance, even when adding a 15 kg load, equivalent to 125% of the A1 robot's nominal mass.