We study geometric set cover problems in dynamic settings, allowing insertions and deletions of points and objects. We present the first dynamic data structure that can maintain an O(1)-approximation in sublinear update time for set cover for axis-aligned squares in 2D. More precisely, we obtain randomized update time O(n2/3+δ) for an arbitrarily small constant δ>0. Previously, a dynamic geometric set cover data structure with sublinear update time was known only for unit squares by Agarwal, Chang, Suri, Xiao, and Xue [SoCG 2020]. If only an approximate size of the solution is needed, then we can also obtain sublinear amortized update time for disks in 2D and halfspaces in 3D. As a byproduct, our techniques for dynamic set cover also yield an optimal randomized O(nlogn)-time algorithm for static set cover for 2D disks and 3D halfspaces, improving our earlier O(nlogn(loglogn)O(1)) result [SoCG 2020].
@article{arxiv.2103.07857,
title = {More Dynamic Data Structures for Geometric Set Cover with Sublinear Update Time},
author = {Timothy M. Chan and Qizheng He},
journal= {arXiv preprint arXiv:2103.07857},
year = {2021}
}