Classes of graphs embeddable in order-dependent surfaces
Abstract
Given a function g=g(n) we let Eg be the class of all graphs G such that if G has order n (that is, has n vertices) then it is embeddable in some surface of Euler genus at most g(n), and let Eg be the corresponding class of unlabelled graphs. We give estimates of the sizes of these classes. For example we show that if g(n)=o(n/3n) then the class Eg has growth constant γ P, the (labelled) planar graph growth constant; and when g(n) = O(n) we estimate the number of n-vertex graphs in Eg and Eg up to a factor exponential in n. From these estimates we see that, if Eg has growth constant γ P then we must have g(n)=o(n/ n), and the generating functions for Eg and Eg have strictly positive radius of convergence if and only if g(n)=O(n/ n). Such results also hold when we consider orientable and non-orientable surfaces separately. We also investigate related classes of graphs where we insist that, as well as the graph itself, each subgraph is appropriately embeddable (according to its number of vertices); and classes of graphs where we insist that each minor is appropriately embeddable. In a companion paper [43], these results are used to investigate random n-vertex graphs sampled uniformly from Eg or from similar classes.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.