A criterion for finite rank $λ$-Toeplitz operators (1404.2700v1)

Abstract: Let $\lambda$ be a complex number in the closed unit disc $\overline{\Bbb D}$, and $\cal H$ be a separable Hilbert space with the orthonormal basis, say, ${\cal E}={e_n:n=0,1,2,\cdots}$. A bounded operator $T$ on $\cal H$ is called a $\lambda$-Toeplitz operator if $$ \langle Te_{m+1},e_{n+1}\rangle=\lambda\langle Te_m,e_n\rangle $$ (where $\langle\cdot,\cdot\rangle$ is the inner product on $\cal H$). The subject arises naturally from a special case of the operator equation [ S^*AS=\lambda A+B,\ \mbox{where $S$ is a shift on $\cal H$}, ] which plays an essential role in finding bounded matrix $(a_{ij})$ on $l^2(\Bbb Z)$ that solves the system of equations $$ \left{\begin{array}{lcc} a_{2i,2j}&=&p_{ij}+aa_{ij}\ a_{2i,2j-1}&=&q_{ij}+ba_{ij}\ a_{2i-1,2j}&=&v_{ij}+ca_{ij}\ a_{2i-1,2j-1}&=&w_{ij}+da_{ij} \end{array}\right. $$ for all $i,j\in\Bbb Z$, where $(p_{ij})$, $(q_{ij})$, $(v_{ij})$, $(w_{ij})$ are bounded matrices on $l^2(\Bbb Z)$ and $a,b,c,d\in\Bbb C$. It is also clear that the well-known Toeplitz operators are precisely the solutions of $S^*AS=A$, when $S$ is the unilateral shift. In this paper we verify some basic issues, such as boundedness and compactness, for $\lambda$-Toeplitz operators and, our main result is to give necessary and sufficient conditions for finite rank $\lambda$-Toeplitz operators.