Approximation Schemes for Geometric Knapsack for Packing Spheres and Fat Objects
Abstract
We study the geometric knapsack problem in which we are given a set of -dimensional objects (each with associated profits) and the goal is to find the maximum profit subset that can be packed non-overlappingly into a given -dimensional (unit hypercube) knapsack. Even if and all input objects are disks, this problem is known to be \textsf{NP}-hard [Demaine, Fekete, Lang, 2010]. In this paper, we give polynomial time -approximation algorithms for the following types of input objects in any constant dimension : - disks and hyperspheres, - a class of fat convex polygons that generalizes regular -gons for (formally, polygons with a constant number of edges, whose lengths are in a bounded range, and in which each angle is strictly larger than ), - arbitrary fat convex objects that are sufficiently small compared to the knapsack. We remark that in our \textsf{PTAS} for disks and hyperspheres, we output the computed set of objects, but for a of them, we determine their coordinates only up to an exponentially small error. However, it is unclear whether there always exists a -approximate solution that uses only rational coordinates for the disks' centers. We leave this as an open problem that is related to well-studied geometric questions in the realm of circle packing.
Cite
@article{arxiv.2404.03981,
title = {Approximation Schemes for Geometric Knapsack for Packing Spheres and Fat Objects},
author = {Pritam Acharya and Sujoy Bhore and Aaryan Gupta and Arindam Khan and Bratin Mondal and Andreas Wiese},
journal= {arXiv preprint arXiv:2404.03981},
year = {2024}
}
Comments
A preliminary version of the work appeared in the proceedings of the 51st EATCS International Colloquium on Automata, Languages, and Programming (ICALP) 2024