A dichotomy theorem for counting problems due to Creignou and Hermann states that or any nite set S of logical relations, the counting problem #SAT(S) is either in FP, or #P-complete. In the present paper we show a dichotomy theorem for polynomial evaluation. That is, we show that for a given set S, either there exists a VNP-complete family of polynomials associated to S, or the associated families of polynomials are all in VP. We give a concise characterization of the sets S that give rise to "easy" and "hard" polynomials. We also prove that several problems which were known to be #P-complete under Turing reductions only are in fact #P-complete under many-one reductions
Bulatov (2008) and Dyer and Richerby (2010) have established the following dichotomy for the countin...
The complexity class Θ^P_2, which is the class of languages recognizable by deterministic Turing mac...
Jaeger, Vertigan, and Welsh [15] proved a dichotomy for the complexity of evaluating the Tutte polyn...
Abstract. A dichotomy theorem for counting problems due to Creignou and Hermann states that or any f...
A dichotomy theorem for counting problems due to Creignou and Hermann states that or any nite set S ...
The Counting Constraint Satisfaction Problem (#CSP) can be expressed as follows: given a set of vari...
The Counting Constraint Satisfaction Problem (#CSP) can be expressed as follows: given a set of vari...
AbstractThe class of generalized satisfiability problems, introduced in 1978 by Schaefer, presents a...
AbstractThe Counting Constraint Satisfaction Problem (#CSP) can be expressed as follows: given a set...
In Valiant developed an algebraic analogue of the theory of NP-completeness for computations of po...
We consider the complexity of two questions on polynomials given by arithmetic circuits: testing whe...
We give a complexity dichotomy theorem for the counting constraint satisfaction problem (#CSP in sho...
Jaeger et al. (Math Proc Camb Philos Soc 108(1):35–53, 1990) proved a dichotomy for the complexity o...
We prove a complexity dichotomy theorem for all non-negatively weighted counting Constraint Satisfac...
We prove that the counting problems #1-in-3Sat, #Not-All-Equal 3Sat and #3-Colorability, whose decis...
Bulatov (2008) and Dyer and Richerby (2010) have established the following dichotomy for the countin...
The complexity class Θ^P_2, which is the class of languages recognizable by deterministic Turing mac...
Jaeger, Vertigan, and Welsh [15] proved a dichotomy for the complexity of evaluating the Tutte polyn...
Abstract. A dichotomy theorem for counting problems due to Creignou and Hermann states that or any f...
A dichotomy theorem for counting problems due to Creignou and Hermann states that or any nite set S ...
The Counting Constraint Satisfaction Problem (#CSP) can be expressed as follows: given a set of vari...
The Counting Constraint Satisfaction Problem (#CSP) can be expressed as follows: given a set of vari...
AbstractThe class of generalized satisfiability problems, introduced in 1978 by Schaefer, presents a...
AbstractThe Counting Constraint Satisfaction Problem (#CSP) can be expressed as follows: given a set...
In Valiant developed an algebraic analogue of the theory of NP-completeness for computations of po...
We consider the complexity of two questions on polynomials given by arithmetic circuits: testing whe...
We give a complexity dichotomy theorem for the counting constraint satisfaction problem (#CSP in sho...
Jaeger et al. (Math Proc Camb Philos Soc 108(1):35–53, 1990) proved a dichotomy for the complexity o...
We prove a complexity dichotomy theorem for all non-negatively weighted counting Constraint Satisfac...
We prove that the counting problems #1-in-3Sat, #Not-All-Equal 3Sat and #3-Colorability, whose decis...
Bulatov (2008) and Dyer and Richerby (2010) have established the following dichotomy for the countin...
The complexity class Θ^P_2, which is the class of languages recognizable by deterministic Turing mac...
Jaeger, Vertigan, and Welsh [15] proved a dichotomy for the complexity of evaluating the Tutte polyn...