English

Quantitative Dynamic Phase Mapping via Single-Arm Field-Correlation Ghost Imaging

Optics 2026-03-24 v1

Abstract

We demonstrate a single-arm optical platform for phase-retrieval-free, quantitative dynamic phase mapping of continuous transparent media via field-correlation ghost imaging. By modeling the medium as a dynamic pure-phase object, we spatially encode and compress its two-dimensional (2D) complex transmittance into a single bucket detector. Balanced heterodyne detection downconverts the optical frequencies for direct digitization. Crucially, by mapping spatial information into the temporal domain, this single-pixel architecture exploits high-speed digitization to continuously resolve 2D phase dynamics, effectively bypassing the frame-rate bottlenecks of traditional array sensors. Coupled with intermediate-frequency spectral analysis, this establishes a direct linear mapping from the recorded signal to the physical phase. The complex amplitude is thus deterministically extracted via field-correlation, enabling the spatial reconstruction of 2D acoustic pressure distributions using a pseudo-inverse algorithm. Experimental validations in an acoustic levitator confirm that the optically extracted acoustic wavelengths strictly match theoretical dispersion models, exhibiting a robust linear correlation between the retrieved phase shift and local sound pressure levels. This deterministic methodology provides a real-time-capable metrological tool for characterizing rapidly evolving phenomena, including transient aeroacoustic flows, shockwaves, and microfluidic biological dynamics.

Keywords

Cite

@article{arxiv.2603.21648,
  title  = {Quantitative Dynamic Phase Mapping via Single-Arm Field-Correlation Ghost Imaging},
  author = {Chaoran Wang and Jinquan Qi and Shuang Liu and Xingzhao Jiang and Shensheng Han},
  journal= {arXiv preprint arXiv:2603.21648},
  year   = {2026}
}

Comments

9 pages, 4 figures

R2 v1 2026-07-01T11:32:50.192Z