The Spanning Ratio of the Directed 6-Graph is 5

Abstract

Given a finite set P⊂R2, the directed Theta-6 graph, denoted 6(P), is a well-studied geometric graph due to its close relationship with the Delaunay triangulation. The 6(P)-graph is defined as follows: the plane around each point u∈ P is partitioned into 6 equiangular cones with apex u, and in each cone, u is joined to the point whose projection on the bisector of the cone is closest. Equivalently, the 6(P)-graph contains an edge from u to v exactly when the interior of ∇uv is disjoint from P, where ∇uv is the unique equilateral triangle containing u on a corner, v on the opposite side, and whose sides are parallel to the cone boundaries. It was previously shown that the spanning ratio of the 6(P)-graph is between 4 and 7 in the worst case (Akitaya, Biniaz, and Bose Comput. Geom., 105-106:101881, 2022). We close this gap by showing a tight spanning ratio of 5. This is the first tight bound proven for the spanning ratio of any k(P)-graph. Our lower bound models a long path by mapping it to a converging series. Our upper bound proof uses techniques novel to the area of spanners. We use linear programming to prove that among several candidate paths, there exists a path satisfying our bound.

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