On Quasi-Interpolation and their associated shift-invariant space using a new class of generalized Thin Plate Splines and Inverse Multiquadrics

Abstract

A new generalization of shifted thin plate splines (x)=(c2d+||x||2d)(c2d+||x||2d), x∈Rn, d∈ N, c>0 is presented to increase the accuracy of quasi-interpolation further. With the restriction to Euclidean spaces of even dimensionality, the generalization can be used to generate a quasi-Lagrange operator that reproduces all polynomials of degree n+2d-1. It thus complements the case of the newly proposed generalized multiquadric (x)=c2d+||x||2d, x∈Rn, d∈ N, c>0, which is restricted to odd dimensions ortmann. This generalization improves the approximation order by a factor of O(h2(d-1)), where d=1 represents the classical thin plate spline. The results are then compared with the theoretical optimal approximation from the shift-invariant space generated by these functions. Moreover, we introduce a new class of inverse multiquadrics (x)=(cλ +||x||λ)β, x∈Rn, λ ∈R,β ∈ R, c>0. We provide an explicit representation of the generalized Fourier transform and discuss its asymptotic behaviour near the origin. Particular emphasis is placed on the case where λ and β are both negative. It is demonstrated that, in dimensions n≥3, it is possible to build a quasi-Lagrange operator that reproduces all polynomials of degree n-3 when n is even and of degree n-12 when n is odd. Furthermore, the uniform approximation error is given by O(hn-2(1/h)) for n even and O(hn-32) for n odd. Here, h>0 denotes the fill distance.