English

Characterization of matrices with bounded Graver bases and depth parameters and applications to integer programming

Discrete Mathematics 2023-06-21 v4 Optimization and Control

Abstract

An intensive line of research on fixed parameter tractability of integer programming is focused on exploiting the relation between the sparsity of a constraint matrix AA and the norm of the elements of its Graver basis. In particular, integer programming is fixed parameter tractable when parameterized by the primal tree-depth and the entry complexity of AA, and when parameterized by the dual tree-depth and the entry complexity of AA; both these parameterization imply that AA is sparse, in particular, the number of its non-zero entries is linear in the number of columns or rows, respectively. We study preconditioners transforming a given matrix to a row-equivalent sparse matrix if it exists and provide structural results characterizing the existence of a sparse row-equivalent matrix in terms of the structural properties of the associated column matroid. In particular, our results imply that the 1\ell_1-norm of the Graver basis is bounded by a function of the maximum 1\ell_1-norm of a circuit of AA. We use our results to design a parameterized algorithm that constructs a matrix row-equivalent to an input matrix AA that has small primal/dual tree-depth and entry complexity if such a row-equivalent matrix exists. Our results yield parameterized algorithms for integer programming when parameterized by the 1\ell_1-norm of the Graver basis of the constraint matrix, when parameterized by the 1\ell_1-norm of the circuits of the constraint matrix, when parameterized by the smallest primal tree-depth and entry complexity of a matrix row-equivalent to the constraint matrix, and when parameterized by the smallest dual tree-depth and entry complexity of a matrix row-equivalent to the constraint matrix.

Keywords

Cite

@article{arxiv.2202.05299,
  title  = {Characterization of matrices with bounded Graver bases and depth parameters and applications to integer programming},
  author = {Marcin Brianski and Martin Koutecky and Daniel Kral and Kristyna Pekarkova and Felix Schroder},
  journal= {arXiv preprint arXiv:2202.05299},
  year   = {2023}
}
R2 v1 2026-06-24T09:31:01.066Z