Title :
An application of matroid theory to the SAT problem
Author :
Kullmann, Oliver
Author_Institution :
Dept. of Comput. Sci., Toronto Univ., Ont., Canada
Abstract :
We consider the deficiency δ(F):=c(F)-n(F) and the maximal deficiency δ*(F):=maxF´⊆Fδ(F) of a clause-set F (a conjunctive normal form), where c(F) is the number of clauses in F and n(F) is the number of variables. Combining ideas from matching and matroid theory with techniques from the area of resolution refutations, we prove that for clause-sets F with δ*(F)⩽k, where k is considered as a constant, the SAT problem, the minimally unsatisfiability problem and the MAXSAT problem are decidable in polynomial time (previously, only poly-time decidability of the minimally unsatisfiability problem was known, and that only for k=1)
Keywords :
computational complexity; computational geometry; decidability; MAXSAT problem; SAT problem; clause-set; conjunctive normal form; matroid theory; maximal deficiency; minimally unsatisfiability problem; poly-time decidability; polynomial time; Application software; Computer science; Councils; Information technology; Polynomials; Upper bound; World Wide Web;
Conference_Titel :
Computational Complexity, 2000. Proceedings. 15th Annual IEEE Conference on
Conference_Location :
Florence
Print_ISBN :
0-7695-0674-7
DOI :
10.1109/CCC.2000.856741
