Abstract
Provably sample-efficient Reinforcement Learning (RL) with rich observations and function approximation has witnessed tremendous recent progress, particularly when the underlying function approximators are linear. In this linear regime, computationally and statistically efficient methods exist where the potentially infinite state and action spaces can be captured through a known feature embedding, with the sample complexity scaling with the (intrinsic) dimension of these features. When the action space is finite, significantly more sophisticated results allow non-linear function approximation under appropriate structural constraints on the underlying RL problem, permitting for instance, the learning of good features instead of assuming access to them. In this work, we present the first result for non-linear function approximation which holds for general action spaces under a linear embeddability condition, which generalizes all linear and finite action settings. We design a novel optimistic posterior sampling strategy, TS3 for such problems. We further show worst case sample complexity guarantees that scale with a rank parameter of the RL problem, the linear embedding dimension introduced here and standard measures of function class complexity.
Original language | English (US) |
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Pages (from-to) | 2776-2814 |
Number of pages | 39 |
Journal | Proceedings of Machine Learning Research |
Volume | 178 |
State | Published - 2022 |
Externally published | Yes |
Event | 35th Conference on Learning Theory, COLT 2022 - London, United Kingdom Duration: Jul 2 2022 → Jul 5 2022 |
Keywords
- Exploration
- Low-rank MDPs
- Posterior sampling
- Reinforcement Learning
ASJC Scopus subject areas
- Artificial Intelligence
- Software
- Control and Systems Engineering
- Statistics and Probability