Hardness of approximation of centered convex bodies by polytopes

Abstract

The distance between convex bodies \(K, L ⊂eq n\) is defined as \[ d(K,L)= ∈f \ λ 1: \ L-x ⊂eq T (K-y) ⊂eq λ (L-x) \, \] where the infimum is taken over all \(x,y ∈ n\) and all invertible linear operators \(T: n n\). If both bodies are centrally symmetric, then the shifts x and y can be chosen to be 0. In this case, any convex symmetric body K can be approximated by a polytope P with at most N ∈ (n, ecn) vertices so that \[ P ⊂eq K ⊂eq λ P \] where \(λ= O (n N )\) up to logarithmic factors. We prove that approximating a general centered convex body by a polytope requires a significantly larger number of vertices compared to the symmetric case. More precisely, there exists a convex body \(K ⊂eq n\) whose barycenter coincides with the origin, such that any polytope P satisfying \[ P ⊂eq K ⊂eq c \, n N P \] must have at least \(N\) vertices, provided that \(N ∈ (Cn2, ecn)\). Moreover, we prove that the same bound holds for approximating a centered convex body with a polytope having N facets instead of N vertices.