Ultimate Precision of Direct Tomography of Wave Functions

TL;DR

This paper extends direct quantum wave function tomography by applying quantum metrology techniques, proposing optimal measurement schemes that approach the Heisenberg limit using entanglement and time-reversal, enhancing precision in quantum state estimation.

Contribution

It generalizes direct wave function tomography through quantum metrology, introducing two measurement schemes that optimize estimation precision near the Heisenberg limit.

Findings

Proposed measurement schemes approach the Heisenberg limit.

Utilized entangled states and time-reversal transformations.

Enhanced efficiency in quantum wave function estimation.

Abstract

In contrast to the standard quantum state tomography, the direct tomography seeks the direct access to the complex values of the wave function at particular positions (i.e., the expansion coefficient in a fixed basis). Originally put forward as a special case of weak measurement, it can be extended to arbitrary measurement setup. We generalize the idea of "quantum metrology," where a real-valued phase is estimated, to the estimation of complex-valued phase, and apply it for the direct tomography of the wave function. It turns out that the reformulation can help us easily find the optimal measurements for efficient estimation. We further propose two different measurement schemes that eventually approach the Heisenberg limit. In the first scheme, the ensemble of measured system is duplicated and the replica ensemble is time-reversal transformed before the start of the measurement. In the other method, the pointers are prepared in special entangled states, either GHZ-like maximally entangled state or the symmetric Dicke state. In both methods, the real part of the parameter is estimated with a Ramsey-type interferometry while the imaginary part is estimated by amplitude measurements.