Trees in Random Sparse Graphs with a Given Degree Sequence

Abstract

Let GD be the set of graphs G(V,\, E) with |V|=n, and the degree sequence equal to D=(d1,\, d2,\,…,\, dn). In addition, for 12<a<1, we define the set of graphs with an almost given degree sequence D as follows, \[ GaD:=\,GD, \] where the union is over all degree sequences D such that, for 1≤ i≤ n, we have |di-di|<dia. Now, if we chose random graphs Gg(D) and Ga(D) uniformly out of the sets GD and GaD, respectively, what do they look like? This has been studied when Gg(D) is a dense graph, i.e. |E|=(n2), in the sense of graphons, or when Gg(D) is very sparse, i.e. dn2=o(|E|). In the case of sparse graphs with an almost given degree sequence, we investigate this question, and give the finite tree subgraph structure of Ga(D) under some mild conditions. For the random graph Gg(D) with a given degree sequence, we re-derive the finite tree structure in dense and very sparse cases to give a continuous picture. Moreover, for a pair of vectors (D1,D2)∈Zn1×Zn2, we let Gb(D1,D2) be the random bipartite graph that is chosen uniformly out of the set GD1,D2, where GD1,D2 is the set of all bipartite graphs with the degree sequence (D1,D2). We are able to show the result for Gb(D1,D2) without any further conditions.