Kinematic State Abstraction and Provably Efficient Rich-Observation Reinforcement Learning
- Dipendra Misra ,
- Mikael Henaff ,
- Akshay Krishnamurthy ,
- John Langford
We present an algorithm, HOMER, for exploration and reinforcement learning in rich observation environments that are summarizable by an unknown latent state space. The algorithm interleaves representation learning to identify a new notion of kinematic state abstraction with strategic exploration to reach new states using the learned abstraction. The algorithm provably explores the environment with sample complexity scaling polynomially in the number of latent states and the time horizon, and, crucially, with no dependence on the size of the observation space, which could be infinitely large. This exploration guarantee further enables sample-efficient global policy optimization for any reward function. On the computational side, we show that the algorithm can be implemented efficiently whenever certain supervised learning problems are tractable. Empirically, we evaluate HOMER on a challenging exploration problem, where we show that the algorithm is exponentially more sample efficient than standard reinforcement learning baselines.
Foundations of Real-World Reinforcement Learning
Reinforcement learning (RL) is an approach to sequential decision making under uncertainty which formalizes the principles for designing an autonomous learning agent. The broad goal of a reinforcement learning agent is to find an optimal policy which maximizes its long-term rewards over time. Its list of applications is growing as the technology advances and continues to be further integrated into many areas, such as education, health, advertising, autonomous systems, and gaming. By starting from the perspective of an agent which interacts with and affects its environment, RL provides an improvement upon supervised learning in situations requiring decisions, and not just predictions. In particular, it motivates exploratory actions to discover novel rewarding behavior in the environment, a hallmark of intelligent agents. In this webinar—led by Microsoft…