Fixed-Height Weyl--Schur Sampling for Free-Tail Canonical Systems

Abstract

We study the finite sampling map H (vH,(xk + iη))k=1M for trace-normed canonical systems on [0,] with free tail H(s)=12I for s , where vH, is the Schur transform of the Weyl coefficient. At the free Hamiltonian H0 12I, we obtain an explicit first-order expansion with quadratic remainder; the linearization is a weighted Fourier--Laplace transform. This yields quantitative local identifiability and local inversion on finite-dimensional families for which the free Jacobian is injective. In the block model, the free Jacobian factors into a row factor, a Fourier sampling matrix, and exponential depth weights, giving explicit singular-value bounds and an exponential depth-conditioning barrier. By contrast, on the full free-tail class every finite sample set has nontrivial first-order invisible directions at H0, so no local inverse-Lipschitz estimate can hold near H0 in L1(0,;op).