Konsep Inti
The author addresses the challenge of heavy-tailed rewards in reinforcement learning using linear function approximation, proposing novel algorithms HEAVY-OFUL and HEAVY-LSVI-UCB.
Abstrak
The content discusses the challenges of heavy-tailed rewards in reinforcement learning, introducing algorithms HEAVY-OFUL and HEAVY-LSVI-UCB. These algorithms utilize adaptive Huber regression to handle heavy-tailed noise efficiently. Theoretical regret bounds and computational complexities are analyzed, demonstrating the effectiveness of these algorithms in handling heavy-tailed rewards.
Key points include:
- Introduction to the challenge of heavy-tailed rewards in reinforcement learning.
- Proposal of algorithms HEAVY-OFUL and HEAVY-LSVI-UCB for efficient handling of heavy-tailed rewards.
- Utilization of adaptive Huber regression for estimating reward functions and value functions.
- Theoretical analysis of regret bounds and computational complexities.
- Demonstration of minimax optimality in worst-case scenarios.
The results highlight the importance of addressing heavy-tailed rewards in reinforcement learning with efficient algorithms like HEAVY-OFUL and HEAVY-LSVI-UCB.
Statistik
HEAVY-OFUL achieves an instance-dependent T-round regret of eO(dT1−ϵ2(1+ϵ)qPTt=1 ν2t + dT1−ϵ2(1+ϵ).
HEAVY-LVSI-UCB achieves a K-episode regret scaling as eO(d√HU∗K11+ϵ + d√HV∗K).
Kutipan
"While numerous works have focused on devising efficient algorithms for reinforcement learning with uniformly bounded rewards, it remains an open question whether sample or time-efficient algorithms for RL with large state-action space exist when the rewards are heavy-tailed."
"Consequently, the performance of traditional algorithms may decline, emphasizing the need for the development of new, efficient algorithms specifically designed to handle heavy-tailed rewards."