Well-posedness and instability of free electron quantum tomography
This addresses a foundational issue in quantum tomography for researchers in quantum imaging, highlighting an incremental theoretical analysis with practical implications for instability in state reconstruction.
The paper tackles the problem of reconstructing free-electron quantum states from energy spectrograms, showing that the constrained inverse problem is well-posed but lacks stability estimates, with any estimator converging arbitrarily slowly.
Recent advancements in photon induced near-field electron microscopy (PINEM) enable the preparation, coherent manipulation and characterization of free-electron quantum states. The available measurement consists of electron energy spectrograms and the goal is the reconstruction of a density matrix representing the quantum state. This requires the solution of a constrained linear inverse problem, where a positive semi-definite trace-class operator is reconstructed given its diagonal in different bases. We show the well-posedness of this problem by exploiting the regularizing effect of the positive semi-definiteness constraint. Unusually, well-posedness in this case does not imply any stability estimates. We show that no global stability estimates exist and any estimator converges arbitrarily slowly. We also provide further bounds on the instability generally complementing the analysis done in [arXiv:1907.03438]. Furthermore, we derive a decomposition of the discretized operator which allows us to study its injectivity and stability properties. It also leads to a faster implementation which we exploit in numerical experiments validating the instability estimates and the stability of the constrained problem.