反褶积
稳健性(进化)
计算机科学
微分干涉显微术
正规化(语言学)
分割
人工智能
边缘检测
算法
迭代法
计算机视觉
先验概率
反问题
图像分割
噪音(视频)
迭代重建
点扩散函数
估计员
相(物质)
模式识别(心理学)
相位对比成像
GSM演进的增强数据速率
医学影像学
相位恢复
忠诚
图像处理
数学
降噪
光学
盲反褶积
作者
Hao Wu,Jiankang Wang,Xiaohao Ma,Xingnan Zhang,Tao Peng,Zeyu Ke,Meng Shao,Tos T. J. M. Berendschot,Shuhe Zhang,Jinhua Zhou
标识
DOI:10.1002/lpor.202502966
摘要
ABSTRACT Quantitative differential phase contrast (qDPC) microscopy enables high‐resolution, label‐free imaging of weakly absorbing samples by combining asymmetrical illumination with phase transfer function (PTF) deconvolution. However, conventional methods are limited by the ill‐posed nature of deconvolution and the band‐limited characteristics of the PTF, leading to poor robustness against noise and background fluctuations, particularly in thick or complex samples. To overcome these challenges, we propose a pupil‐driven differential phase contrast (PD‐DPC) framework that integrates system PTFs into both the data fidelity and regularization terms of the reconstruction model. The proposed model incorporates an edge‐sparsity‐promoting regularization to preserve structural detail and suppress noise, along with a Retinex‐inspired fidelity formulation to mitigate background fluctuations. The resulting non‐convex optimization problem is solved via an efficient Split Bregman algorithm with iterative reweighted soft‐thresholding. Simulations and experiments demonstrate that PD‐DPC outperforms L2‐DPC, Iso‐DPC, TV‐DPC, and Retinex‐DPC in terms of background suppression, phase fidelity, and edge preservation. The framework is compatible with diverse DPC modalities and enables automatic cell contour segmentation as well as high‐resolution imaging of absorbing tissues beyond the weak‐object approximation. By combining physics‐informed priors with a data‐adaptive reconstruction strategy, PD‐DPC offers a robust, broadly applicable solution that substantially enhances the accuracy and applicability of qDPC for biomedical imaging. The MATLAB code is available on GitHub .
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