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Computing eigenvalues of semi-infinite quasi-Toeplitz matrices

A quasi-Toeplitz (QT) matrix is a semi-infinite matrix of the form $A=T(a)+E$ where $T(a)$ is the Toeplitz matrix with entries $(T(a))_{i,j}=a_{j-i}$, for $a_{j-i}\in\mathbb C$, $i,j\ge 1$, while $E$ is a matrix representing a compact operator in $\ell^2$. The matrix $A$ is finitely representable if $a_k=0$ for $k<-m$ and for $k>n$, given $m,n>0$, and if $E$ has a finite number of nonzero entries. The problem of numerically computing eigenpairs of a finitely representable QT matrix is investigated, i.e., pairs $(λ,{\bf v})$ such that $A{\bf v}=λ{\bf v}$, with $λ\in\mathbb C$, ${\bf v}=(v_j)_{j\in\mathbb Z^+}$, ${\bf v}\ne 0$, and $\sum_{j=1}^\infty |v_j|^2<\infty$. It is shown that the problem is reduced to a finite nonlinear eigenvalue problem of the kind $ WU(λ){\pmb β}=0$, where $W$ is a constant matrix and $U$ depends on $λ$ and can be given in terms of either a Vandermonde matrix or a companion matrix. Algorithms relying on Newton&#39;s method applied to the equation $\det WU(λ)=0$ are analyzed. Numerical experiments show the effectiveness of this approach. The algorithms have been included in the CQT-Toolbox [Numer. Algorithms 81 (2019), no. 2, 741--769].