Zap Q-Learning with Nonlinear Function Approximation
Abstract
Zap Q-learning is a recent class of reinforcement learning algorithms, motivated primarily as a means to accelerate convergence. Stability theory has been absent outside of two restrictive classes: the tabular setting, and optimal stopping. This paper introduces a new framework for analysis of a more general class of recursive algorithms known as stochastic approximation. Based on this general theory, it is shown that Zap Q-learning is consistent under a non-degeneracy assumption, even when the function approximation architecture is nonlinear. Zap Q-learning with neural network function approximation emerges as a special case, and is tested on examples from OpenAI Gym. Based on multiple experiments with a range of neural network sizes, it is found that the new algorithms converge quickly and are robust to choice of function approximation architecture.
Cite
Text
Chen et al. "Zap Q-Learning with Nonlinear Function Approximation." Neural Information Processing Systems, 2020.Markdown
[Chen et al. "Zap Q-Learning with Nonlinear Function Approximation." Neural Information Processing Systems, 2020.](https://mlanthology.org/neurips/2020/chen2020neurips-zap/)BibTeX
@inproceedings{chen2020neurips-zap,
title = {{Zap Q-Learning with Nonlinear Function Approximation}},
author = {Chen, Shuhang and Devraj, Adithya M and Lu, Fan and Busic, Ana and Meyn, Sean},
booktitle = {Neural Information Processing Systems},
year = {2020},
url = {https://mlanthology.org/neurips/2020/chen2020neurips-zap/}
}