Tridiagonal kernels and left-invertible operators with applications to Aluthge transforms

Abstract

Given scalars an (≠ 0) and bn, n ≥ 0, the tridiagonal kernel or band kernel with bandwidth 1 is the positive definite kernel k on the open unit disc D defined by \[ k(z, w) = Σn=0∞ ((an + bn z)zn) ((an + bn w) wn ) (z, w ∈ D). \] This defines a reproducing kernel Hilbert space Hk (known as tridiagonal space) of analytic functions on D with \(an + bnz) zn\n=0∞ as an orthonormal basis. We consider shift operators Mz on Hk and prove that Mz is left-invertible if and only if \|an/an+1|\n≥ 0 is bounded away from zero. We find that, unlike the case of weighted shifts, Shimorin's models for left-invertible operators fail to bring to the foreground the tridiagonal structure of shifts. In fact, the tridiagonal structure of a kernel k, as above, is preserved under Shimorin model if and only if b0=0 or that Mz is a weighted shift. We prove concrete classification results concerning invariance of tridiagonality of kernels, Shimorin models, and positive operators. We also develop a computational approach to Aluthge transforms of shifts. Curiously, in contrast to direct kernel space techniques, often Shimorin models fails to yield tridiagonal Aluthge transforms of shifts defined on tridiagonal spaces.