Maximum Entropy Behavior Exploration for Sim2Real Zero-Shot Reinforcement Learning
This work addresses the problem of poor downstream performance in sim2real zero-shot RL for robotics, though it is incremental as it builds on existing methods.
The paper tackled the challenge of collecting diverse datasets for zero-shot reinforcement learning in quadrupedal control by introducing FB-MEBE, an algorithm that maximizes behavior entropy and uses a regularization critic, resulting in improved performance in simulated tasks and seamless hardware deployment without finetuning.
Zero-shot reinforcement learning (RL) algorithms aim to learn a family of policies from a reward-free dataset, and recover optimal policies for any reward function directly at test time. Naturally, the quality of the pretraining dataset determines the performance of the recovered policies across tasks. However, pre-collecting a relevant, diverse dataset without prior knowledge of the downstream tasks of interest remains a challenge. In this work, we study $\textit{online}$ zero-shot RL for quadrupedal control on real robotic systems, building upon the Forward-Backward (FB) algorithm. We observe that undirected exploration yields low-diversity data, leading to poor downstream performance and rendering policies impractical for direct hardware deployment. Therefore, we introduce FB-MEBE, an online zero-shot RL algorithm that combines an unsupervised behavior exploration strategy with a regularization critic. FB-MEBE promotes exploration by maximizing the entropy of the achieved behavior distribution. Additionally, a regularization critic shapes the recovered policies toward more natural and physically plausible behaviors. We empirically demonstrate that FB-MEBE achieves and improved performance compared to other exploration strategies in a range of simulated downstream tasks, and that it renders natural policies that can be seamlessly deployed to hardware without further finetuning. Videos and code available on our website.