English

Fractional coloring via entropy

Combinatorics 2026-04-15 v2 Discrete Mathematics

Abstract

In recent work, Martinsson and Steiner showed that every K3K_3-free dd-degenerate graph GG has fractional chromatic number χf(G)=O(dlogd)\chi_f(G) = O\left(\frac{d}{\log d}\right). In this paper, we extend the result in two ways, employing an approach rooted in the analysis of the entropy of certain probability distributions. Our argument provides a template to tackle other problems, so it is of independent interest. First, we consider locally rr-colorable graphs GG, i.e., where χ(G[N(v)])r\chi(G[N(v)]) \leq r for each vertex vv. We show that dd-degenerate locally rr-colorable graphs GG satisfy χf(G)=O(dlog(2r)logd)\chi_f(G) = O\left(\frac{d\log (2r)}{\log d}\right), strengthening a result of Alon (1996) on the independence number of such graphs. Second, we extend Martinsson and Steiner's result to rr-uniform dd-degenerate hypergraphs HH of girth at least 44. We show that such hypergraphs satisfy χf(H)cr(dlogd)1r1\chi_f(H) \leq c_r\left(\frac{d}{\log d}\right)^{\frac{1}{r-1}}, implying a strict generalization of a seminal result of Ajtai, Koml\'os, Pintz, Spencer, and Szemer\'edi (1982) on the independence number of uncrowded hypergraphs. As a corollary, we obtain the same growth rate for the fractional chromatic number of dd-degenerate linear hypergraphs. Our approach is constructive, yielding efficient algorithms to sample independent sets in each of the settings we consider.

Keywords

Cite

@article{arxiv.2603.17730,
  title  = {Fractional coloring via entropy},
  author = {Abhishek Dhawan},
  journal= {arXiv preprint arXiv:2603.17730},
  year   = {2026}
}

Comments

19 pages plus references

R2 v1 2026-07-01T11:26:11.335Z