Bounds on Walsh coefficients by dyadic difference and a new Koksma-Hlawka type inequality for Quasi-Monte Carlo integration

Abstract

In this paper we give a new Koksma-Hlawka type inequality for Quasi-Monte Carlo (QMC) integration. QMC integration of a function f[0,1)s→ R by a finite point set P⊂ [0,1)s is the approximation of the integral I(f):=∫[0,1)sf(x)\,dx by the average IP(f):=1|P|Σx ∈ Pf(x). We treat a certain class of point sets P called digital nets. A Koksma-Hlawka type inequality is an inequality bounding the integration error Err(f;P):=I(f)-IP(f) by a bound of the form |Err(f;P)| C· \|f\|· D(P). We can obtain a Koksma-Hlawka type inequality by estimating bounds on |f(k)|, where f(k) is a generalized Fourier coefficient with respect to the Walsh system. In this paper we prove bounds on Walsh coefficients f(k) by introducing an operator called `dyadic difference' ∂i,n. By converting dyadic differences ∂i,n to derivatives ∂ ∂ xi, we get a new bound on |f(k)| for a function f whose mixed partial derivatives up to order α in each variable are continuous. This new bound is smaller than the known bound on |f(k)| under some condition. The new Koksma-Hlawka inequality is derived using this new bound on the Walsh coefficients.