PTAS for sparse general-valued CSPs
| Autor: | Balázs F. Mezei, Marcin Wrochna, stanislav Živný |
|---|---|
| Jazyk: | angličtina |
| Rok vydání: | 2022 |
| Předmět: |
FOS: Computer and information sciences
Dense graph Discrete Mathematics (cs.DM) 68R10 05C75 68W25 Vertex cover G.2.2 0102 computer and information sciences Computer Science::Computational Complexity 01 natural sciences Combinatorics symbols.namesake Mathematics (miscellaneous) Computer Science::Discrete Mathematics Computer Science - Data Structures and Algorithms Data Structures and Algorithms (cs.DS) 0101 mathematics Computer Science::Data Structures and Algorithms Constraint satisfaction problem 010102 general mathematics F.2.2 Planar graph Linear programming relaxation 010201 computation theory & mathematics Independent set symbols Graph (abstract data type) Element (category theory) Computer Science - Discrete Mathematics |
| Zdroj: | LICS 2021 36th Annual ACM/IEEE Symposium on Logic in Computer Science (LICS) Logic in Computer Science |
| DOI: | 10.1145/3569956 |
| Popis: | We study polynomial-time approximation schemes (PTASes) for constraint satisfaction problems (CSPs) such as Maximum Independent Set or Minimum Vertex Cover on sparse graph classes. Baker's approach gives a PTAS on planar graphs, excluded-minor classes, and beyond. For Max-CSPs, and even more generally, maximisation finite-valued CSPs (where constraints are arbitrary non-negative functions), Romero, Wrochna, and \v{Z}ivn\'y [SODA'21] showed that the Sherali-Adams LP relaxation gives a simple PTAS for all fractionally-treewidth-fragile classes, which is the most general "sparsity" condition for which a PTAS is known. We extend these results to general-valued CSPs, which include "crisp" (or "strict") constraints that have to be satisfied by every feasible assignment. The only condition on the crisp constraints is that their domain contains an element which is at least as feasible as all the others (but possibly less valuable). For minimisation general-valued CSPs with crisp constraints, we present a PTAS for all Baker graph classes -- a definition by Dvo\v{r}\'ak [SODA'20] which encompasses all classes where Baker's technique is known to work, except possibly for fractionally-treewidth-fragile classes. While this is standard for problems satisfying a certain monotonicity condition on crisp constraints, we show this can be relaxed to diagonalisability -- a property of relational structures connected to logics, statistical physics, and random CSPs. Comment: Full version of a LICS 2021 paper |
| Databáze: | OpenAIRE |
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