Polynomial upper bounds on the number of differing columns of $\Delta$-modular integer programs

TL;DR

This paper establishes polynomial upper bounds on the number of differing columns in $ ext{Δ}$-modular integer programs, advancing understanding of their combinatorial structure and implications for solving such integer programs efficiently.

Contribution

It provides the first polynomial-in-determinants column bound for $ ext{Δ}$-modular matrices, extending Heller's work and improving bounds on related properties like $ ext{l}_1$-distance and Graver basis height.

Findings

Polynomial bounds on differing columns in $ ext{Δ}$-modular matrices.

First $ ext{l}_1$-distance bounds polynomial in determinants and equations.

Tight bound on differing columns in bimodular matrices.

Abstract

We study integer-valued matrices with bounded determinants. Such matrices appear in the theory of integer programs (IP) with bounded determinants. For example, Artmann et al. showed that an IP can be solved in strongly polynomial time if the constraint matrix is bimodular, that is, the determinants are bounded in absolute value by two. Determinants are also used to bound the $\ell_1$-distance between IP solutions and solutions of its linear relaxation. One of the first works to quantify the complexity of IPs with bounded determinants was that of Heller, who identified the maximum number of differing columns in a totally unimodular matrix. Each extension of Heller's bound to general determinants has been super-polynomial in the determinants or the number of equations. We provide the first column bound that is polynomial in both values. For integer programs with box constraints, our result gives the first $\ell_1$-distance bound that is polynomial in the determinants and the number of equations. Our result can also be used to derive a bound on the height of Graver basis elements that is polynomial in the determinants and the number of equations. Furthermore, we show a tight bound on the number of differing columns in a bimodular matrix; this is the first tight bound since Heller. Our analysis reveals combinatorial properties of bimodular IPs that may be of independent interest.