Directed Exploration in Reinforcement Learning with Transferred Knowledge

Experimental results suggest that transfer learning (TL), compared to learning from scratch, can decrease exploration by reinforcement learning (RL) algorithms. Most existing TL algorithms for RL are heuristic and may result in worse performance than learning from scratch (i.e., negative transfer). We introduce a theoretically grounded and flexible approach that transfers action-values via an intertask mapping and, based on those, explores the target task systematically. We characterize positive transfer as (1) decreasing sample complexity in the target task compared to the sample complexity of the base RL algorithm (without transferred action-values) and (2) guaranteeing that the algorithm converges to a near-optimal policy (i.e., negligible optimality loss). The sample complexity of our approach is no worse than the base algorithm's, and our analysis reveals that positive transfer can occur even with highly inaccurate and partial intertask mappings. Finally, we empirically test directed exploration with transfer in a multijoint reaching task, which highlights the value of our analysis and the robustness of our approach under imperfect conditions.