Positive 1-in-3-SAT admits a non-trivial Kernel

Abstract

We illustrate the strength of Algebraic Methods, adapting Gaussian Elimination and Substitution to the problem of Exact Boolean Satisfiability. For 1-in-3 SAT with non-negated literals we are able to obtain considerably smaller equivalent instances of 0/1 Integer Programming restricted to Equality only. Both Gaussian Elimination and Substitution may be used in a processing step, followed by a type of brute-force approach on the kernel thus obtained. Our method shows that Positive instances of 1-in-3 SAT may be reduced to significantly smaller instances of I.P.E. in the following sense. Any such instance of |V| variables and |C| clauses can be polynomial-time reduced to an instance of 0/1 Integer Programming with Equality, of size at most 2/3|V| variables and at most |C| clauses. We obtain an upper bound for the complexity of counting, O(2 r 2(1-) r) for number of variables r and clauses to variables ratio . We proceed to define formally the notion of a non-trivial kernel, defining the problems considered as Constraint Satisfaction Problems. We conclude showing the methods presented here, giving a non-trivial kernel for positive 1-in-3 SAT, imply the existence of a non-trivial kernel for 1-in-3 SAT.