Learning Belief Representations for Imitation Learning in POMDPs
This work addresses imitation learning for robotics or control systems in uncertain environments, representing an incremental advance by integrating belief learning more closely with policy objectives.
The paper tackles imitation learning in partially observable Markov decision processes (POMDPs) by jointly learning belief representations with the policy using task-aware imitation loss and regularization techniques, resulting in substantial performance improvements over baselines on continuous-control locomotion tasks.
We consider the problem of imitation learning from expert demonstrations in partially observable Markov decision processes (POMDPs). Belief representations, which characterize the distribution over the latent states in a POMDP, have been modeled using recurrent neural networks and probabilistic latent variable models, and shown to be effective for reinforcement learning in POMDPs. In this work, we investigate the belief representation learning problem for generative adversarial imitation learning in POMDPs. Instead of training the belief module and the policy separately as suggested in prior work, we learn the belief module jointly with the policy, using a task-aware imitation loss to ensure that the representation is more aligned with the policy's objective. To improve robustness of representation, we introduce several informative belief regularization techniques, including multi-step prediction of dynamics and action-sequences. Evaluated on various partially observable continuous-control locomotion tasks, our belief-module imitation learning approach (BMIL) substantially outperforms several baselines, including the original GAIL algorithm and the task-agnostic belief learning algorithm. Extensive ablation analysis indicates the effectiveness of task-aware belief learning and belief regularization.