The Geometry of Linear Program Compression: An Exact Characterization and Learning Algorithm
Abstract
We study how much a linear program (LP) can be compressed when solved repeatedly, given prior knowledge about its objective function. Existing data-driven projection methods learn low-dimensional surrogate LPs with approximate objective-value guarantees, but cannot provably identify the optimal projection for a prescribed compression budget. We instead ask a sharper question: how far can an LP be compressed into a lower-dimensional equivalent while \emph{exactly} preserving optimality, enabling faster repeated solves with no loss in solution quality? We provide an exact geometric characterization of such compressed LPs, together with a tractable sample-based learning algorithm that comes with fast-rate guarantees: the compressed LP recovers the optimal solution of an unseen instance with probability at least , where is the dimension of the decision-relevant subspace, and is the number of available historical LP samples. This dependence is sharper than the uniform-convergence rates of approximate projection methods. Our framework further exposes a tunable tradeoff between the dimension of the compressed LP and the probability of recovering the optimal solution, allowing the user to trade compression for accuracy.
Cite
@article{arxiv.2605.25635,
title = {The Geometry of Linear Program Compression: An Exact Characterization and Learning Algorithm},
author = {Yuhan Ye and Omar Bennouna},
journal= {arXiv preprint arXiv:2605.25635},
year = {2026}
}
Comments
27 pages, 11 figures