Probing-Enhanced Stochastic Programming

TL;DR

This paper introduces a three-stage stochastic programming model with probing actions to acquire information about uncertain variables, proposing a solution method that scales better than existing MIP formulations and applies to continuous distributions.

Contribution

It develops a novel bounds-based branch-and-bound approach for probing-enhanced stochastic programming, extending applicability beyond finite support cases.

Findings

Method scales better than traditional MIP formulations on finite support instances.

Approach provides statistical bounds that improve upon perfect information bounds.

Effective for continuous distributions without requiring finite support.

Abstract

We consider a two-stage stochastic decision problem where the decision-maker has the opportunity to obtain information about the distribution of the random variables $\xi$ that appear in the problem through a set of discrete actions that we refer to as \emph{probing}. Probing components of a random vector $\eta$ that is jointly-distributed with $\xi$ allows the decision-maker to learn about the conditional distribution of $\xi$ given the observed components of $\eta$. We propose a three-stage optimization model for this problem, where in the first stage some components of $\eta$ are chosen to be observed, and decisions in subsequent stages must be consistent with the obtained information. In the case that $\eta$ and $\xi$ have finite support, Goel and Grossmann gave a mixed-integer programming (MIP) formulation of this problem whose size is proportional to the square of cardinality of the sample space of the random variables. We propose to solve the model using bounds obtained from an information-based relaxation, combined with a branching scheme that enforces the consistency of decisions with observed information. The branch-and-bound approach can naturally be combined with sampling in order to estimate both lower and upper bounds on the optimal solution value and does not require $\eta$ or $\xi$ to have finite support. We conduct a computational study of our method on instances of a stochastic facility location and sizing problem with the option to probe customers to learn about their demands before building facilities. We find that on instances with finite support, our approach scales significantly better than the MIP formulation and also demonstrate that our method can compute statistical bounds on instances with continuous distributions that improve upon the perfect information bounds.