Interpolation by generalized exponential sums with equal weights

Abstract

Here we solve Pad\'e and Prony interpolation problems for the generalized exponential sums with equal weights: Hn(z; h)=μnΣk=1n h(λk z), where μ,λk∈ C, and h is a fixed analytic function under few natural assumptions. The interpolation of a function f by Hn is due to properly chosen μ and \λk\k=1n, which depend on f, h and n. The sums Hn are related to the h-sums and generalized exponential sums, i.e. to H*n(z; h)=Σk=1n λk h(λk z) andn(z; h):=Σk=1n μk h(λk z), where μk,λk∈ C, which generalize many classical approximants and whose properties are actively studied. As for the Pad\'e problem, we show that Hn and Hn* have similar constructions and rates of interpolation, whereas calculating Hn requires less arithmetic operations. Although the Pad\'e problem for Hn is known to have a doubled interpolation rate with respect to Hn* and thus to Hn, it can be however unsolvable in many useful cases and this may entirely eliminate the advantage of Hn. We show that, in contrast to Hn, the Pad\'e problem for Hn always has a unique solution. More importantly, we also obtain efficient estimates for μ and λk, valuable by themselves, and use them in further evaluating interpolation quality and in applications. The Pad\'e problem and estimates provide a basis for managing the more interesting Prony problem for exponential sums with equal weights Hn(z;), i.e. when h(z)=(z). We show that it is uniquely solvable and surprisingly μ and λk can be efficiently estimated. This is in sharp contrast to the case of well-known exponential sums Hn(z;).