Inverse scattering for reflection intensity phase microscopy
Abstract
Reflection phase imaging provides label-free, high-resolution characterization of biological samples, typically using interferometric-based techniques. Here, we investigate reflection phase microscopy from intensity-only measurements under diverse illumination. We evaluate the forward and inverse scattering model based on the first Born approximation for imaging scattering objects above a glass slide. Under this design, the measured field combines linear forward-scattering and height-dependent nonlinear back-scattering from the object that complicates object phase recovery. Using only the forward-scattering, we derive a linear inverse scattering model and evaluate this model's validity range in simulation and experiment using a standard reflection microscope modified with a programmable light source. Our method provides enhanced contrast of thin, weakly scattering samples that complement transmission techniques. This model provides a promising development for creating simplified intensity-based reflection quantitative phase imaging systems easily adoptable for biological research.
Keywords
Cite
@article{arxiv.1912.07709,
title = {Inverse scattering for reflection intensity phase microscopy},
author = {Alex Matlock and Anne Sentenac and Patrick C. Chaumet and Ji Yi and Lei Tian},
journal= {arXiv preprint arXiv:1912.07709},
year = {2019}
}
Comments
25 pages, 5 figures