English

On $\Delta$-Modular Integer Linear Problems In The Canonical Form And Equivalent Problems

Computational Complexity 2022-11-30 v6 Discrete Mathematics Data Structures and Algorithms

Abstract

Many papers in the field of integer linear programming (ILP, for short) are devoted to problems of the type max{cx ⁣:Ax=b,xZ0n}\max\{c^\top x \colon A x = b,\, x \in \mathbb{Z}^n_{\geq 0}\}, where all the entries of A,b,cA,b,c are integer, parameterized by the number of rows of AA and Amax\|A\|_{\max}. This class of problems is known under the name of ILP problems in the standard form, adding the word "bounded" if xux \leq u, for some integer vector uu. Recently, many new sparsity, proximity, and complexity results were obtained for bounded and unbounded ILP problems in the standard form. In this paper, we consider ILP problems in the canonical form max{cx ⁣:blAxbr,xZn},\max\{c^\top x \colon b_l \leq A x \leq b_r,\, x \in \mathbb{Z}^n\}, where blb_l and brb_r are integer vectors. We assume that the integer matrix AA has the rank nn, (n+m)(n + m) rows, nn columns, and parameterize the problem by mm and Δ(A)\Delta(A), where Δ(A)\Delta(A) is the maximum of n×nn \times n sub-determinants of AA, taken in the absolute value. We show that any ILP problem in the standard form can be polynomially reduced to some ILP problem in the canonical form, preserving mm and Δ(A)\Delta(A), but the reverse reduction is not always possible. More precisely, we define the class of generalized ILP problems in the standard form, which includes an additional group constraint, and prove the equivalence to ILP problems in the canonical form. We generalize known sparsity, proximity, and complexity bounds for ILP problems in the canonical form. Additionally, sometimes, we strengthen previously known results for ILP problems in the canonical form, and, sometimes, we give shorter proofs. Finally, we consider the special cases of m{0,1}m \in \{0,1\}. By this way, we give specialised sparsity, proximity, and complexity bounds for the problems on simplices, Knapsack problems and Subset-Sum problems.

Keywords

Cite

@article{arxiv.2002.01307,
  title  = {On $\Delta$-Modular Integer Linear Problems In The Canonical Form And Equivalent Problems},
  author = {D. V. Gribanov and I. A. Shumilov and D. S. Malyshev and P. M. Pardalos},
  journal= {arXiv preprint arXiv:2002.01307},
  year   = {2022}
}

Comments

J Glob Optim (2022)

R2 v1 2026-06-23T13:30:47.737Z