@article{de Berg_2023, title={A Note on Reachability and Distance Oracles for Transmission Graphs}, volume={2}, url={https://cgt-journal.org/index.php/cgt/article/view/25}, DOI={10.57717/cgt.v2i1.25}, abstractNote={<p>Let P be a set of n points in the plane, where each point p in P has a transmission radius r(p) &gt; 0. The transmission graph defined by P and the given radii, denoted by G_{tr}(P), is the directed graph whose nodes are the points in P and that contains the arcs (p,q) such that |pq|<strong>≤</strong> r(p).</p>
<p>An and Oh [Algorithmica 2022] presented a reachability oracle for transmission graphs. Their oracle uses O(n^<sup>5/3</sup>) storage and, given two query points s,t in P, can decide in O(n^<sup>2/3</sup>) time if there is a path from s to t in G_{tr}(P). We show that the clique-based separators introduced by De Berg et al. [SICOMP 2020] can be used to improve the storage of the oracle to O(n\sqrt{n}) and the query time to O(\sqrt{n}). Our oracle can be extended to approximate distance queries: we can construct, for a given parameter eps &gt; 0, an oracle that uses O((n/\eps)\sqrt{n}\log n) storage and that can report in O((\sqrt{n}/\eps)\log n) time a value d*_{hop}(s,t) satisfying d_{hop}(s,t) \leq d*_{hop}(s,t) &lt; (1+eps) d_{hop}(s,t) + 1, where d_{hop}(s,t) is the hop-distance from s to t. We also show how to extend the oracle to so-called continuous queries, where the target point t can be any point in the plane.</p>
<p>To obtain an efficient preprocessing algorithm, we show that a clique-based separator of a set F of convex fat objects in R<sup>d</sup> can be constructed in O(n log n) time.</p>}, number={1}, journal={Computing in Geometry and Topology}, author={de Berg, Mark}, year={2023}, month={May}, pages={4:1–4:15} }