Approximation of Set-Valued Functions with images sets in Rd

Abstract

Given a finite number of samples of a continuous set-valued function F, mapping an interval to non-empty compact subsets of Rd, F: [a,b] K(Rd), we discuss the problem of computing good approximations of F. We also discuss algorithms for a direct high-order evaluation of the graph of F, namely, the set Graph(F)=\(t,y)\ | \ y∈ F(t),\ t∈ [a,b]\∈ K(Rd+1). A set-valued function can be continuous and yet have points where the topology of the image sets changes. The main challenge in set-valued function approximation is to derive high-order approximations near these points. In a previous paper, we presented with Q. Muzaffar, an algorithm for approximating set-valued functions with 1D sets (d=1) as images, achieving high approximation order near points of topology change. Here we build upon the results and algorithms in the d=1 case, first in more detail for the important case d=2, and later for approximating set-valued functions and their graphs in higher dimensions.