Programmable spatial coherence tomography: diffraction-limited three-dimensional reflection imaging under modulated monochromatic illumination
Abstract
Depth sectioning in reflection microscopy has predominantly relied on temporal coherence gating. Here we show that volumetric reflection tomography at diffraction-limited resolution can be achieved under monochromatic illumination by engineering spatial, rather than temporal, coherence. In programmable spatial coherence tomography (PSCT), a sequence of pupil-coded illumination patterns with angular-spectrum diversity generates measurement redundancy enabling the system to calibrate itself, jointly retrieving aberrations, illumination profiles, and sample motion without guide stars or modal priors. We demonstrate label-free volumetric imaging of thick human tissues, organoids, frequency-resolved dynamic contrast, and high-resolution in vivo brain imaging through a cranial window. These results position PSCT as an alternative to temporal coherence based reflection imaging in complex biological systems.
Cite
@article{arxiv.2605.05747,
title = {Programmable spatial coherence tomography: diffraction-limited three-dimensional reflection imaging under modulated monochromatic illumination},
author = {Herve Hugonnet and Jieun Choi and Gyoung Hwan Kim and Chulmin Oh and Jimin Cho and Chungha Lee and Su-Jin Shin and Sujin Park and Bon-Kyoung Koo and Wang-Yuhl Oh and Pilhan Kim and YongKeun Park},
journal= {arXiv preprint arXiv:2605.05747},
year = {2026}
}