Arnoldi-Enhanced Multivariate Hermite Interpolation of Manifold-Valued Data

Abstract

This paper presents a robust enhancement of the Tangent space Hermite Interpolation (THI) method for manifold-valued data by integrating the multivariate Arnoldi process. To circumvent the inherent numerical instability of multivariate confluent Vandermonde matrices, we use a G-Arnoldi-based recurrence to construct a discrete orthogonal polynomial basis directly on the tangent space. The method generates better numerical conditioning for high-order approximations. We analyze the convergence rates for both C0 and C1 errors in the multivariate setting. When only function values are used, the C0 approximation error decays as O(M n-m). For the C1 error without derivative data, the rate becomes O(M h-1 n-m), where h is the fill distance of the sampling set. When derivative data are additionally available, the C1 error is O(M n-(m-1)). In all cases, n is the polynomial degree, m denotes the regularity of the target function, and M is the number of sampling points. Importantly, as n increases, the required number of points M must also increase. This reveals the interplay among approximation order, sampling density (M), fill distance (h), dimension (d), and the regularity (m) of the target function. Extensive numerical experiments conducted on the special orthogonal group SO(3) and the unit sphere S2 show that the Arnoldi-enhanced THI method outperforms the Kriging-based approaches in terms of both computational efficiency and accuracy.