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Phase-aberration compensation via deep learning in digital holographic microscopy

Shujun Ma, Rui Fang, Yu Luo, Qi Liu, Shiliang Wang, Xu Zhou

2021Measurement Science and Technology40 citationsDOI

Abstract

Abstract Digital holographic microscopy (DHM), a quantitative phase-imaging technology, has been widely used in various applications. Phase-aberration compensation in off-axis DHM is vital to reconstruct topographical images with high precision, especially for microstructures with a small background or a dense phase distribution. We propose a numerical method based on deep learning combined with DHM. First, a convolutional neural network (CNN) recognizes and segments the sample and the background area of the hologram. Zernike polynomial fitting is then executed on the extracted background area. Finally, the whole process of phase-aberration compensation is automatically performed. To obtain a robust and accurate deep-learning model for hologram segmentation, we collected many holograms corresponding to several samples that had different morphological characteristics. The experimental results confirm that the trained CNN can accurately segment the sample from the background area of the hologram, and that this method is applicable and effective in off-axis DHM.

Topics & Concepts

Zernike polynomialsHolographyDigital holographic microscopyConvolutional neural networkComputer scienceArtificial intelligenceOpticsPhase (matter)Computer visionCompensation (psychology)SegmentationDigital holographyDeep learningSample (material)MicroscopyPhysicsWavefrontQuantum mechanicsPsychologyPsychoanalysisThermodynamicsDigital Holography and MicroscopyImage Processing Techniques and ApplicationsOptical measurement and interference techniques
Phase-aberration compensation via deep learning in digital holographic microscopy | Litcius