English

Differential source-basis encoding for superresolved parameter estimation in a time-reversed Young interferometer

Optics 2026-04-14 v2 Applied Physics Quantum Physics

Abstract

We develop a differential source-encoding protocol for local parameter estimation in a time-reversed Young interferometer, where the source plane is used not merely as a scan coordinate but as a programmable measurement basis. Two sequential positive-only source patterns implement an antisymmetric differential probe about a chosen operating point, converting the deterministicc source-coordinate response into a derivative-gradient sensing channel. In the local regime, the differential signal separates naturally into an envelope-gradient term, which is also present in noninterferometric differential sensing, and an interference-gradient term, which is specific to the time-reversed Young fringe law. This decomposition identifies the physical origin of the interferometric advantage and clarifies why it is regime dependent rather than universal. Using a shot-noise-limited Poisson model, we derive the corresponding Fisher information and Cram\'er--Rao bounds and compare the protocol with raster sampling in the same geometry and with a matched noninterferometric differential baseline. Representative numerical examples show a strong and robust gain over raster sampling, while the additional improvement from the time-reversed Young interference is parameter dependent but can be substantial in favorable regimes. The results establish the time-reversed Young geometry as a practically simple platform for programmable differential interferometric metrology.

Keywords

Cite

@article{arxiv.2603.27407,
  title  = {Differential source-basis encoding for superresolved parameter estimation in a time-reversed Young interferometer},
  author = {Jianming Wen},
  journal= {arXiv preprint arXiv:2603.27407},
  year   = {2026}
}

Comments

correct some references information which were previously messed up with other manuscripts under preparation

R2 v1 2026-07-01T11:42:29.931Z