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Main Author: Wei, Ningji
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.12437
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author Wei, Ningji
author_facet Wei, Ningji
contents Covering and elimination inequalities are central to combinatorial optimization, yet their role has largely been studied in problem-specific settings or via no-good cuts. This paper introduces a unified perspective that treats these inequalities as primitives for set system approximation in binary integer programs (BIPs). We show that arbitrary set systems admit tight inner and outer monotone approximations, exactly corresponding to covering and elimination inequalities. Building on this, we develop a toolkit that both recovers classical structural correspondences (e.g., paths vs. cuts, spanning trees vs. cycles) and extends polyhedral tools from set covering to general BIPs, including facet conditions and lifting methods. We also propose new reformulation techniques for nonlinear and latent monotone systems, such as auxiliary-variable-free bilinear linearization, bimonotone cuts, and interval decompositions. A case study on distributionally robust network site selection illustrates the framework's flexibility and computational benefits. Overall, this unified view clarifies inner/outer approximation criteria, extends classical polyhedral analysis, and provides broadly applicable reformulation strategies for nonlinear BIPs.
format Preprint
id arxiv_https___arxiv_org_abs_2511_12437
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Set System Approximation for Binary Integer Programs: Reformulations and Applications
Wei, Ningji
Optimization and Control
Covering and elimination inequalities are central to combinatorial optimization, yet their role has largely been studied in problem-specific settings or via no-good cuts. This paper introduces a unified perspective that treats these inequalities as primitives for set system approximation in binary integer programs (BIPs). We show that arbitrary set systems admit tight inner and outer monotone approximations, exactly corresponding to covering and elimination inequalities. Building on this, we develop a toolkit that both recovers classical structural correspondences (e.g., paths vs. cuts, spanning trees vs. cycles) and extends polyhedral tools from set covering to general BIPs, including facet conditions and lifting methods. We also propose new reformulation techniques for nonlinear and latent monotone systems, such as auxiliary-variable-free bilinear linearization, bimonotone cuts, and interval decompositions. A case study on distributionally robust network site selection illustrates the framework's flexibility and computational benefits. Overall, this unified view clarifies inner/outer approximation criteria, extends classical polyhedral analysis, and provides broadly applicable reformulation strategies for nonlinear BIPs.
title Set System Approximation for Binary Integer Programs: Reformulations and Applications
topic Optimization and Control
url https://arxiv.org/abs/2511.12437