On the Vertices of Delta-modular Polyhedra

Abstract

Let P be a polytope defined by the system A x ≤ b, where A ∈ Rm × n, b ∈ Rm, and rank(A) = n. We give a short geometric proof of the following tight upper bound on the number of vertices of P: n! · average · vol(B2) 1π n · (2 πe)n/2 · nn/2 · average, where is the maximum absolute value of n × n subdeterminants of A, and average is the average absolute value of subdeterminants of A corresponding to a triangulation of P's normal fan. Assuming that A is integer, such polyhedra are called -modular polyhedra. Note that in the integer case, the bound can be simplified via the inequality average ≥ ≥ 1, where is the minimum absolute value of subdeterminants of A corresponding to feasible bases of A x ≤ b. For this, we prove and use a symmetric variant of Macbeath's theorem. Additionally, we give a direct argument based on prior results in the field, showing that the graph diameter of P is bounded by O(n3 · · (n ) ). Thus, both characteristic of P are linear in /. From an algorithmic perspective, we demonstrate that: Given A ∈ Qm × n, b ∈ Qm, and an initial feasible solution to A x ≤ b, the convex hull of P can be constructed in O(n)n/2 · m2 · average operations. For simple polyhedra, the dependence on m reduces to linear; Given A ∈ Zm × n and b ∈ Qm, the number |P Zn| can be computed in O(n)n · 4average arithmetic operations.