Better Diameter Algorithms for Bounded VC-dimension Graphs and Geometric Intersection Graphs

We develop a framework for algorithms finding diameter in graphs of bounded distance Vapnik-Chervonenkis dimension, in (parametrized) sub-quadratic time complexity. The class of bounded distance VC-dimension graphs is wide, including, e.g. all minor-free graphs. We build on the work of Ducoffe et al., improving their technique. With our approach the algorithms become simpler and faster, working in $\widetilde{\mathcal{O}}(k \cdot V^{1-1/d} \cdot E)$ time complexity, where $k$ is the diameter, $d$ is the VC-dimension. Furthermore, it allows us to use the technique in more general setting. In particular, we use this framework for geometric intersection graphs, i.e. graphs where vertices are identical geometric objects on a plane and the adjacency is defined by intersection. Applying our approach for these graphs, we answer a question posed by Bringmann et al., finding a $\widetilde{\mathcal{O}}(n^{7/4})$ parametrized diameter algorithm for unit square intersection graph of size $n$, as well as a more general algorithm for convex polygon intersection graphs.