Yongxin Yuan

Copyright © 2008 Yongxin Yuan. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

We first give the representation of the general solution of the following inverse quadratic eigenvalue problem (IQEP): given Λ=diag{λ1,…,λp}∈Cp×p , X=[x1,…,xp]∈Cn×p, and both Λ and X are closed under complex conjugation in the sense that λ2j=λ¯2j−1∈C, x2j=x¯2j−1∈Cn for j=1,…,l, and λk∈R, xk∈Rn for k=2l+1,…, p, find real-valued symmetric (2r+1)-diagonal matrices M, D and K such that MXΛ2+DXΛ+KX=0. We then consider an optimal approximation problem: given real-valued symmetric (2r+1)-diagonal matrices Ma,Da,Ka∈Rn×n, find (M^,D^,K^)∈SE such that ‖M^−Ma‖2+‖D^−Da‖2+‖K^−Ka‖2=inf⁡(M,D,K)∈SE(‖M−Ma‖2+‖D−Da‖2+‖K−Ka‖2), where SE is the solution set of IQEP. We show that the optimal approximation solution (M^,D^,K^) is unique and derive an explicit formula for it.