Add to ORKGThis paper starts by settling the computational complexity of the problem of integrating a polynomial function f over a rational simplex. We prove that the problem is NP-hard for arbitrary polynomials via a generalization of a theorem of Motzkin and Straus. On the other hand, if the polynomial depends only on a fixed number of variables, while its degree and the dimension of the simplex are allowed to vary, we prove that integration can be done in polynomial time. As a consequence, for polynomials of fixed total degree, there is a polynomial time algorithm as well. We explore our algorithms with some experiments. We conclude the article with extensions to other polytopes and discussion of other available methods. 1
We are interested in the fast computation of the exact value of integrals of polynomial fun...
We are interested in the fast computation of the exact value of integrals of polynomial functions ov...
We are interested in the fast computation of the exact value of integrals of polynomial fun...
This paper starts by settling the computational complexity of the problem of integrating a polynomia...
This paper starts by settling the computational complexity of the problem of integrating a polynomia...
This paper settles the computational complexity of the problem of integrating a polynomial ...
International audienceThis paper settles the computational complexity of the problem of integrating ...
International audienceThis paper settles the computational complexity of the problem of integrating ...
International audienceThis paper settles the computational complexity of the problem of integrating ...
We show that integrating a polynomial of degree t on an arbitrary simplex (with respect to Lebesgue ...
International audienceWe show that integrating a polynomial of degree t on an arbitrary simplex (wit...
International audienceWe show that integrating a polynomial of degree t on an arbitrary simplex (wit...
We complete the complexity classification by degree of minimizing a polynomial in two variables over...
(eng) We show that the integer roots of of a univariate polynomial with integer coefficients can be ...
We show that the integer roots of of a univariate polynomial with integer coefficients can be comput...
We are interested in the fast computation of the exact value of integrals of polynomial fun...
We are interested in the fast computation of the exact value of integrals of polynomial functions ov...
We are interested in the fast computation of the exact value of integrals of polynomial fun...
This paper starts by settling the computational complexity of the problem of integrating a polynomia...
This paper starts by settling the computational complexity of the problem of integrating a polynomia...
This paper settles the computational complexity of the problem of integrating a polynomial ...
International audienceThis paper settles the computational complexity of the problem of integrating ...
International audienceThis paper settles the computational complexity of the problem of integrating ...
International audienceThis paper settles the computational complexity of the problem of integrating ...
We show that integrating a polynomial of degree t on an arbitrary simplex (with respect to Lebesgue ...
International audienceWe show that integrating a polynomial of degree t on an arbitrary simplex (wit...
International audienceWe show that integrating a polynomial of degree t on an arbitrary simplex (wit...
We complete the complexity classification by degree of minimizing a polynomial in two variables over...
(eng) We show that the integer roots of of a univariate polynomial with integer coefficients can be ...
We show that the integer roots of of a univariate polynomial with integer coefficients can be comput...
We are interested in the fast computation of the exact value of integrals of polynomial fun...
We are interested in the fast computation of the exact value of integrals of polynomial functions ov...
We are interested in the fast computation of the exact value of integrals of polynomial fun...