English

Unrolling Dynamic Programming via Graph Filters

Artificial Intelligence 2025-07-30 v1

Abstract

Dynamic programming (DP) is a fundamental tool used across many engineering fields. The main goal of DP is to solve Bellman's optimality equations for a given Markov decision process (MDP). Standard methods like policy iteration exploit the fixed-point nature of these equations to solve them iteratively. However, these algorithms can be computationally expensive when the state-action space is large or when the problem involves long-term dependencies. Here we propose a new approach that unrolls and truncates policy iterations into a learnable parametric model dubbed BellNet, which we train to minimize the so-termed Bellman error from random value function initializations. Viewing the transition probability matrix of the MDP as the adjacency of a weighted directed graph, we draw insights from graph signal processing to interpret (and compactly re-parameterize) BellNet as a cascade of nonlinear graph filters. This fresh look facilitates a concise, transferable, and unifying representation of policy and value iteration, with an explicit handle on complexity during inference. Preliminary experiments conducted in a grid-like environment demonstrate that BellNet can effectively approximate optimal policies in a fraction of the iterations required by classical methods.

Keywords

Cite

@article{arxiv.2507.21705,
  title  = {Unrolling Dynamic Programming via Graph Filters},
  author = {Sergio Rozada and Samuel Rey and Gonzalo Mateos and Antonio G. Marques},
  journal= {arXiv preprint arXiv:2507.21705},
  year   = {2025}
}
R2 v1 2026-07-01T04:23:49.313Z