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Zero-One Laws for Random Feasibility Problems

Probability 2024-07-25 v3 Discrete Mathematics Combinatorics

Abstract

We introduce a general random model of a combinatorial optimization problem with geometric structure that encapsulates both linear programming and integer linear programming. Let QQ be a bounded set called the feasible set, EE be an arbitrary set called the constraint set, and AA be a random linear transform. We define and study the q\ell^q-margin, Mq:=dq(AQ,E)M_q := d_q(AQ, E). The margin quantifies the feasibility of finding yAQy \in AQ satisfying the constraint yEy \in E. Our contribution is to establish strong concentration of the margin for any q(2,]q \in (2,\infty], assuming only that EE has permutation symmetry. The case of q=q = \infty is of particular interest in applications -- specifically to combinatorial ``balancing'' problems -- and is markedly out of the reach of the classical isoperimetric and concentration-of-measure tools that suffice for q2q \le 2. Generality is a key feature of this result: we assume permutation symmetry of the constraint set and nothing else. This allows us to encode many optimization problems in terms of the margin, including random versions of: the closest vector problem, integer linear feasibility, perceptron-type problems, q\ell^q-combinatorial discrepancy for 2q2 \le q \le \infty, and matrix balancing. Concentration of the margin implies a host of new sharp threshold results in these models, and also greatly simplifies and extends some key known results.

Keywords

Cite

@article{arxiv.2309.13133,
  title  = {Zero-One Laws for Random Feasibility Problems},
  author = {Dylan J. Altschuler},
  journal= {arXiv preprint arXiv:2309.13133},
  year   = {2024}
}

Comments

Revisions. Typos fixed. Discussion around theorems 5 and 6 reworked

R2 v1 2026-06-28T12:29:55.713Z