Recent zbMATH articles in MSC 41A55https://www.zbmath.org/atom/cc/41A552022-05-16T20:40:13.078697ZWerkzeugA probability estimate for the discrepancy of Korobov lattice pointshttps://www.zbmath.org/1483.111562022-05-16T20:40:13.078697Z"Illarionov, Andrei A."https://www.zbmath.org/authors/?q=ai:illarionov.andrei-aNear-minimal cubature formulae on the diskhttps://www.zbmath.org/1483.650372022-05-16T20:40:13.078697Z"Benouahmane, Brahim"https://www.zbmath.org/authors/?q=ai:benouahmane.brahim"Annie, Cuyt"https://www.zbmath.org/authors/?q=ai:annie.cuyt"Yaman, Irem"https://www.zbmath.org/authors/?q=ai:yaman.iremSummary: The construction of (near-)minimal cubature formulae on the disk is still a complicated subject on which many results have been published. We restrict ourselves to the case of radial weight functions and make use of a recent connection between cubature and the concept of multivariate spherical orthogonal polynomials to derive a new system of equations defining the nodes and weights of (near-)minimal rules for general degree \(m=2n-1\), \(n \ge 2\). The approach encompasses all previous derivations.
The new system is small and may consist of only \((n+1)^2/4\) equations when \(n\) is odd and \(n(n+2)/4\) equations when \(n\) is even. It is valid for general \(n\) and has a Prony-like structure. It may admit a unique solution (such as for \(n=3)\) or an infinity of solutions (such as for \(n=7)\). In Section 2, the new approach is described, whereas the new system is derived in Sections 3 and 4. All well-known (near-)minimal cubature rules can be reobtained. Some typical illustrations of how this works are given in Section 5.
We expect that this unifying theory will shed new light on the topic of cubature, in particular with respect to the discovery of new bounds on the number of nodes and their connection with the zeros of multivariate orthogonal polynomials.Cubature formulae for the Gaussian weight. Some old and new rules.https://www.zbmath.org/1483.650422022-05-16T20:40:13.078697Z"Orive, Ramón"https://www.zbmath.org/authors/?q=ai:orive-rodriguez.ramon-angel"Santos-León, Juan C."https://www.zbmath.org/authors/?q=ai:santos-leon.juan-carlos"Spalević, Miodrag M."https://www.zbmath.org/authors/?q=ai:spalevic.miodrag-mThe authors consider the numerical evaluation of the integral
\[
\int_{\mathbb{R}^n}e^{-x^Tx}f(x)dx,
\]
where \(x=(x_1,\dots,x_n)\in \mathbb{R}^n\), and derive some new rules with respect to the aim of taking of certain degree of algebraic precision and a reasonable small number of nodes and good stability. The theory is presented by computing of new and classical methods of several numerical experiments.
Reviewer: Josef Kofroň (Praha)