A complete dichotomy theorem on the sparse $t$-Uniform Hypergraphicality Problem
Abstract
We prove a complete dichotomy theorem for the parameterized sparse -uniform hypergraphic degree sequence problem, . For any fixed , given parameters , the input consists of degree sequences of length with degrees between and . We show that the problem is NP-complete whenever , and solvable in linear time when . This establishes a sharp boundary between polynomial-time solvable and NP-complete instances, thereby characterizing the computational complexity across all degree exponent regimes. The result extends the earlier NP-completeness of dense hypergraphicality to a unified framework covering both sparse and dense regimes, revealing that even extremely sparse instances (with maximum degree but ) remain NP-complete. On the other hand, the -uniform hypergraphicality solvable in linear time when the maximum degree is . This dichotomy provides a comprehensive classification of the complexity landscape for hypergraphic degree sequences.
Cite
@article{arxiv.2512.15356,
title = {A complete dichotomy theorem on the sparse $t$-Uniform Hypergraphicality Problem},
author = {István Miklós and Miklós Ruszinkó and Bogdán Zavalnij},
journal= {arXiv preprint arXiv:2512.15356},
year = {2025}
}
Comments
18 pages