Contrastive Variational Model-Based Reinforcement Learning for Complex Observations

Deep model-based reinforcement learning (MBRL) has achieved great sample-efficiency and generalization in decision making for sophisticated simulated tasks, such as Atari games. However, real-world robot decision making requires reasoning with complex natural visual observations. This paper presents Contrastive Variational Reinforcement Learning (CVRL), an MBRL framework for complex natural observations. In contrast to the commonly used generative world models, CVRL learns a contrastive variational world model by maximizing the mutual information between latent states and observations discriminatively by contrastive learning. Contrastive learning avoids modeling the complex observation space and is significantly more robust than the standard generative world models. For decision making, CVRL discovers long-horizon behavior by online search guided by an actor-critic. CVRL achieves comparable performance with the state-of-the-art (SOTA) generative MBRL approaches on a series of Mujoco tasks, and significantly outperforms SOTAs on Natural Mujoco tasks, a new, more challenging continuous control RL benchmark with complex observations introduced in this paper.