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Fixed-Horizon Temporal Difference Methods for Stable Reinforcement Learning

Machine Learning 2020-02-12 v2 Artificial Intelligence

Abstract

We explore fixed-horizon temporal difference (TD) methods, reinforcement learning algorithms for a new kind of value function that predicts the sum of rewards over a fixed\textit{fixed} number of future time steps. To learn the value function for horizon hh, these algorithms bootstrap from the value function for horizon h1h-1, or some shorter horizon. Because no value function bootstraps from itself, fixed-horizon methods are immune to the stability problems that plague other off-policy TD methods using function approximation (also known as "the deadly triad"). Although fixed-horizon methods require the storage of additional value functions, this gives the agent additional predictive power, while the added complexity can be substantially reduced via parallel updates, shared weights, and nn-step bootstrapping. We show how to use fixed-horizon value functions to solve reinforcement learning problems competitively with methods such as Q-learning that learn conventional value functions. We also prove convergence of fixed-horizon temporal difference methods with linear and general function approximation. Taken together, our results establish fixed-horizon TD methods as a viable new way of avoiding the stability problems of the deadly triad.

Keywords

Cite

@article{arxiv.1909.03906,
  title  = {Fixed-Horizon Temporal Difference Methods for Stable Reinforcement Learning},
  author = {Kristopher De Asis and Alan Chan and Silviu Pitis and Richard S. Sutton and Daniel Graves},
  journal= {arXiv preprint arXiv:1909.03906},
  year   = {2020}
}

Comments

AAAI 2020

R2 v1 2026-06-23T11:09:50.209Z