Sparse graph limits, entropy maximization and transitive graphs
read the original abstract
In this paper we describe a triple correspondence between graph limits, information theory and group theory. We put forward a new graph limit concept called log-convergence that is closely connected to dense graph limits but its main applications are in the study of sparse graph sequences. We present an information theoretic limit concept for $k$-tuples of random variables that is based on the entropy maximization problem for joint distributions of random variables where a system of marginal distributions is prescribed. We give a fruitful correspondence between the two limit concepts that has a group theoretic nature. Our applications are in graph theory and information theory. We shows that if $H$ is a bipartite graph, $P_1$ is the edge and $t$ is the homomorphism density function then the supremum of $\log t(H,G)/\log t(P_1,G)$ in the set of all graphs $G$ is the same as in the set of graphs that are both edge and vertex transitive. This result gives a group theoretic approach to Sidorenko's famous conjecture. We obtain information theoretic inequalities regarding the entropy maximization problem. We investigate the limits of sparse random graphs and discuss quasi-randomness in our framework.
This paper has not been read by Pith yet.
Forward citations
Cited by 4 Pith papers
-
Sidorenko Inequalities for Two-Sided Group Correlation Kernels
A directed kernel C_f on finite groups satisfies t(F, C_f) ≥ (E f(g))^{2e(F)} for every finite directed graph F.
-
Spectral Sidorenko inequalities and edge-spectral supersaturation
Sidorenko's conjecture is equivalent to hom(H,G) ≥ λ(G)^{2e-v} M(G)^{v-e}, which yields asymptotically sharp supersaturation bounds for the number of K_{t,t} and C_{2t} in graphs with λ(G) > λ(S_{t-1,m}).
-
Tensor Amplification and Spectral Transfer for Sidorenko-Type Inequalities
Tensor-amplification framework proves equality regularization and spectral equivalence for C-Sidorenko graphs in admissible graphon classes.
-
Logarithmic convergence of finite projective planes
Incidence graphs of projective planes over finite fields log-converge to the limit of a specific random graph model.
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.