We prove that integer programming with three alternating quantifiers is NP-complete, even for a fixed number of variables. This complements earlier results by Lenstra and Kannan, which together say that integer programming with at most two alternating quantifiers can be done in polynomial time for a fixed number of variables. As a byproduct of the proof, we show that for two polytopes P, Q in R^4, counting the projection of integer points in QP is #P-complete. This contrasts the 2003 result by Barvinok and Woods, which allows counting in polynomial time the projection of integer points in P and Q separately
Many fundamental NP-hard problems can be formulated as integer linear programs (ILPs). A famous algo...
AbstractRecently I. Jensen published a novel transfer-matrix algorithm for computing the number of p...
We complete the complexity classification by degree of minimizing a polynomial in two variables over...
Quantified integer programming is the problem of deciding assertions of the form Q_k x_k ... forall ...
Quantified integer programming is the problem of deciding assertions of the form Q_k x_k ... forall ...
We study the general integer programming problem where the number of variables $n$ is a variable par...
Powerful results from the theory of integer programming have recently led to substantial advances in...
A wide variety of problems in Discrete Optimization and Integer Programming can be naturally phrased...
Summary form only given. Integer programming is the problem of maximizing a linear function over the...
AbstractIn this article we study a broad class of integer programming problems in variable dimension...
P versus NP is considered as one of the most important open problems in computer science. This consi...
We apply the algebraic approach for Constraint Satisfaction Problems (CSPs) with counting quantifier...
We study the theoretical complexity of mixed integer programming algorithms. We first discuss the re...
We show that a 2-variable integer program, defined by m constraints involving coefficients with at m...
Proof complexity provides a promising approach aimed at resolving the P versus NP question by establ...
Many fundamental NP-hard problems can be formulated as integer linear programs (ILPs). A famous algo...
AbstractRecently I. Jensen published a novel transfer-matrix algorithm for computing the number of p...
We complete the complexity classification by degree of minimizing a polynomial in two variables over...
Quantified integer programming is the problem of deciding assertions of the form Q_k x_k ... forall ...
Quantified integer programming is the problem of deciding assertions of the form Q_k x_k ... forall ...
We study the general integer programming problem where the number of variables $n$ is a variable par...
Powerful results from the theory of integer programming have recently led to substantial advances in...
A wide variety of problems in Discrete Optimization and Integer Programming can be naturally phrased...
Summary form only given. Integer programming is the problem of maximizing a linear function over the...
AbstractIn this article we study a broad class of integer programming problems in variable dimension...
P versus NP is considered as one of the most important open problems in computer science. This consi...
We apply the algebraic approach for Constraint Satisfaction Problems (CSPs) with counting quantifier...
We study the theoretical complexity of mixed integer programming algorithms. We first discuss the re...
We show that a 2-variable integer program, defined by m constraints involving coefficients with at m...
Proof complexity provides a promising approach aimed at resolving the P versus NP question by establ...
Many fundamental NP-hard problems can be formulated as integer linear programs (ILPs). A famous algo...
AbstractRecently I. Jensen published a novel transfer-matrix algorithm for computing the number of p...
We complete the complexity classification by degree of minimizing a polynomial in two variables over...