A Unified Approach for Multi-step Temporal-Difference Learning with Eligibility Traces in Reinforcement Learning

Abstract

Recently, a new multi-step temporal learning algorithm, called Q(σ), unifies n-step Tree-Backup (when σ=0) and n-step Sarsa (when σ=1) by introducing a sampling parameter σ. However, similar to other multi-step temporal-difference learning algorithms, Q(σ) needs much memory consumption and computation time. Eligibility trace is an important mechanism to transform the off-line updates into efficient on-line ones which consume less memory and computation time. In this paper, we further develop the original Q(σ), combine it with eligibility traces and propose a new algorithm, called Q(σ ,λ), in which λ is trace-decay parameter. This idea unifies Sarsa(λ) (when σ =1) and Qπ(λ) (when σ =0). Furthermore, we give an upper error bound of Q(σ ,λ) policy evaluation algorithm. We prove that Q(σ,λ) control algorithm can converge to the optimal value function exponentially. We also empirically compare it with conventional temporal-difference learning methods. Results show that, with an intermediate value of σ, Q(σ ,λ) creates a mixture of the existing algorithms that can learn the optimal value significantly faster than the extreme end (σ=0, or 1).