Multivariate Polynomial Integration and Derivative Are Polynomial Time Inapproximable unless P=NP

Abstract

We investigate the complexity of integration and derivative for multivariate polynomials in the standard computation model. The integration is in the unit cube [0,1]d for a multivariate polynomial, which has format f(x1,·s, xd)=p1(x1,·s, xd)p2(x1,·s, xd)·s pk(x1,·s, xd), where each pi(x1,·s, xd)=Σj=1d qj(xj) with all single variable polynomials qj(xj) of degree at most two and constant coefficients. We show that there is no any factor polynomial time approximation for the integration ∫[0,1]df(x1,·s,xd)dx1·s dxd unless P=NP. For the complexity of multivariate derivative, we consider the functions with the format f(x1,·s, xd)=p1(x1,·s, xd)p2(x1,·s, xd)·s pk(x1,·s, xd), where each pi(x1,·s, xd) is of degree at most 2 and 0,1 coefficients. We also show that unless P=NP, there is no any factor polynomial time approximation to its derivative ∂ f(d)(x1,·s, xd) ∂ x1·s ∂ xd at the origin point (x1,·s, xd)=(0,·s,0). Our results show that the derivative may not be easier than the integration in high dimension. We also give some tractable cases of high dimension integration and derivative.