Approximate Sampling and Counting of Graphs with Near-Regular Degree Intervals

TL;DR

This paper introduces the first efficient algorithms for sampling and counting graphs with degree intervals close to a specified degree, extending existing methods from fixed degree sequences to more flexible degree interval constraints.

Contribution

It provides the first fully polynomial almost uniform sampler and approximation scheme for graphs with near-regular degree intervals, utilizing advanced Markov chain techniques and recent theoretical breakthroughs.

Findings

Developed a rapidly mixing Markov chain for near-regular degree intervals.

Achieved the first polynomial-time algorithms for sampling and counting such graphs.

Applied recent theoretical results to improve graph sampling methods.

Abstract

The approximate uniform sampling of graphs with a given degree sequence is a well-known, extensively studied problem in theoretical computer science and has significant applications, e.g., in the analysis of social networks. In this work we study an extension of the problem, where degree intervals are specified rather than a single degree sequence. We are interested in sampling and counting graphs whose degree sequences satisfy the degree interval constraints. A natural scenario where this problem arises is in hypothesis testing on social networks that are only partially observed. In this work, we provide the first fully polynomial almost uniform sampler (FPAUS) as well as the first fully polynomial randomized approximation scheme (FPRAS) for sampling and counting, respectively, graphs with near-regular degree intervals, in which every node $i$ has a degree from an interval not too far away from a given $d \in \N$. In order to design our FPAUS, we rely on various state-of-the-art tools from Markov chain theory and combinatorics. In particular, we provide the first non-trivial algorithmic application of a breakthrough result of Liebenau and Wormald (2017) regarding an asymptotic formula for the number of graphs with a given near-regular degree sequence. Furthermore, we also make use of the recent breakthrough of Anari et al. (2019) on sampling a base of a matroid under a strongly log-concave probability distribution. As a more direct approach, we also study a natural Markov chain recently introduced by Rechner, Strowick and M\"uller-Hannemann (2018), based on three simple local operations: Switches, hinge flips, and additions/deletions of a single edge. We obtain the first theoretical results for this Markov chain by showing it is rapidly mixing for the case of near-regular degree intervals of size at most one.