Some properties of rank-2 lattice rules

Lyness, J. N.; Sloan, I. H.

doi:10.1090/S0025-5718-1989-0982369-6

Some properties of rank-$2$ lattice rules
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by J. N. Lyness and I. H. Sloan PDF

Math. Comp. 53 (1989), 627-637 Request permission

Abstract:

A rank-2 lattice rule is a quadrature rule for the (unit) s-dimensional hypercube, of the form \[ Qf = (1/{n_1}{n_2})\sum \limits _{{j_1} = 1}^{{n_1}} {\sum \limits _{{j_2} = 1}^{{n_2}} {\bar f({j_1}{{\mathbf {z}}_1}/{n_1} + {j_2}{{\mathbf {z}}_2}/{n_2}),} } \] which cannot be re-expressed in an analogous form with a single sum. Here $\bar f$ is a periodic extension of f, and ${{\mathbf {z}}_1}$, ${{\mathbf {z}}_2}$ are integer vectors. In this paper we discuss these rules in detail; in particular, we categorize a special subclass, whose leading one- and two-dimensional projections contain the maximum feasible number of abscissas. We show that rules of this subclass can be expressed uniquely in a simple tricycle form.

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