English

Sequential decision problems, dependent types and generic solutions

Logic in Computer Science 2023-06-22 v5

Abstract

We present a computer-checked generic implementation for solving finite-horizon sequential decision problems. This is a wide class of problems, including inter-temporal optimizations, knapsack, optimal bracketing, scheduling, etc. The implementation can handle time-step dependent control and state spaces, and monadic representations of uncertainty (such as stochastic, non-deterministic, fuzzy, or combinations thereof). This level of genericity is achievable in a programming language with dependent types (we have used both Idris and Agda). Dependent types are also the means that allow us to obtain a formalization and computer-checked proof of the central component of our implementation: Bellman's principle of optimality and the associated backwards induction algorithm. The formalization clarifies certain aspects of backwards induction and, by making explicit notions such as viability and reachability, can serve as a starting point for a theory of controllability of monadic dynamical systems, commonly encountered in, e.g., climate impact research.

Keywords

Cite

@article{arxiv.1610.07145,
  title  = {Sequential decision problems, dependent types and generic solutions},
  author = {Nicola Botta and Patrik Jansson and Cezar Ionescu and David R. Christiansen and Edwin Brady},
  journal= {arXiv preprint arXiv:1610.07145},
  year   = {2023}
}

Comments

23 pages, 2 figures

R2 v1 2026-06-22T16:28:46.122Z