English

Optimal Volume-Sensitive Bounds for Polytope Approximation

Computational Geometry 2026-01-26 v2

Abstract

Approximating convex bodies is a fundamental question in geometry, which has a wide variety of applications. Given a convex body KK in Rd\textbf{R}^d for fixed dd, the objective is to minimize the number of facets of an approximating polytope for a given Hausdorff error ε\varepsilon. It is known that O((diam(K)/ε)(d1)/2)O((\text{diam}(K)/\varepsilon)^{(d-1)/2}) facets suffice and are necessary for many instances, such as the Euclidean ball. However, this bound is far from optimal for ``skinny'' convex bodies. A natural way to characterize the skinniness of a convex object is in terms of its relationship to the Euclidean ball. Given a convex body KK, its \emph{volume diameter} Δd(K)\Delta_d(K) is defined to be the diameter of a Euclidean ball of the same volume as KK. The \emph{surface diameter} Δd1(K)\Delta_{d-1}(K) is defined analogously for surface area. It follows from generalizations of the isoperimetric inequality that diam(K)Δd1(K)Δd(K)\text{diam}(K) \geq \Delta_{d-1}(K) \geq \Delta_d(K). Arya, da Fonseca, and Mount proved that the diameter-based bound could be made sensitive to the surface diameter, improving the above bound to O((Δd1(K)/ε)(d1)/2)O((\Delta_{d-1}(K)/\varepsilon)^{(d-1)/2}). In this paper, we strengthen this by proving the existence of an approximation with O((Δd(K)/ε)(d1)/2)O((\Delta_d(K)/\varepsilon)^{(d-1)/2}) facets. As a function of volume alone, this bound is tight up to constant factors. Our improvements arise from a combination of new ideas. We exploit known properties of the original body and its polar dual. In order to obtain a volume-sensitive bound, we explore the problem of computing a low-complexity polytope that is sandwiched between two given convex bodies. We show that this problem can be reduced to a covering problem involving a natural intermediate body based on the harmonic mean. Our proof relies on a geometric analysis of a relative notion of fatness involving these bodies.

Keywords

Cite

@article{arxiv.2303.09586,
  title  = {Optimal Volume-Sensitive Bounds for Polytope Approximation},
  author = {Sunil Arya and David M. Mount},
  journal= {arXiv preprint arXiv:2303.09586},
  year   = {2026}
}

Comments

Accepted to Discrete and Computational Geometry. Prior version appeared in the 39th International Symposium on Computational Geometry (SoCG 2023)

R2 v1 2026-06-28T09:20:38.591Z