Abstract
Phase recovery from a stack of through-focus intensity images is an effective non-interference quantitative phase imaging strategy. Nevertheless, the implementations of these methods are expensive and time-consuming because the distance between each through-focus plane has to be guaranteed by precision mechanical moving devices, and the multiple images must be acquired sequentially. In this article, we propose a single-shot through-focus intensity image stack acquisition strategy without any precision movement. Isolated LED units are used to illuminate the sample in different colors from different angles. Due to the chromatic aberration characteristics of the objective, the color-channel defocus images on the theoretical imaging plane are mutually laterally shifted. By calculating the shift amount of each sub-image area in each color channel, the distances between each through-focus image can be obtained, which is a critical parameter in transport of intensity equation (TIE) and alternating projection (AP). Lastly, AP is used to recover the phase distribution and realize the 3D localization of different defocus distances of the sample under test as an example. Both simulation and experiments are conducted to verify the feasibility of the proposed method.
Highlights
Quantitative phase imaging (QPI) [1] is crucial to label-free microscopic imaging in biomedical fields
We propose a single-shot phase retrieval method based on chromatic aberration and image lateral shift resulting from the multi-angle illuminations of the out-of-focus sample
Through-focus intensity image acquisition methods play a critical role in alternating projection (AP) and transport of intensity equation (TIE) phase retrieval approaches
Summary
Quantitative phase imaging (QPI) [1] is crucial to label-free microscopic imaging in biomedical fields. According to the above-mentioned illumination direction and the wavelength multiplexing strategy in section Oblique Illumination Model, we can obtain the defocus distances by calculating the lateral shifts between the red and green/blue channel images. By utilizing the axial chromatic aberration characteristics, we use two channels (green and blue) of the same planar sensor to record the intensity images corresponding to the different propagation distances with different illumination angles. We propagate the recovered object function to 200, 400, and 800 μm with the illumination angle, θrg, and obtain both the amplitude and phase of the sample corresponding to the different defocus distances, respectively.
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