Coincidence imaging for Jones matrix with a deep-learning approach

npj Nanophotonics Pub Date : 2024-03-06 DOI:10.1038/s44310-024-00002-z

Jiawei Xi, Tsz Kit Yung, Hong Liang, Tan Li, Wing Yim Tam, Jensen Li

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Abstract

Coincidence measurement has become an emerging technique for optical imaging. Based on measuring the second-order coherence g2, sample features such as reflection/transmission amplitude and phase delay can be extracted with developed algorithms pixel-by-pixel. However, an accurate measurement of g2 requires a substantial number of collected photons which becomes difficult under low-light conditions. Here, we propose a deep-learning approach for Jones matrix imaging using photon arrival data directly. A variational autoencoder (β-VAE) is trained using numerical data in an unsupervised manner to obtain a minimal data representation, which can be transformed into an image with little effort. We demonstrate as few as 88 photons collected per pixel on average to extract a Jones matrix image, with accuracy surpassing previous semi-analytic algorithms derived from g2. Our approach not only automates formulating imaging algorithms but can also assess the sufficiency of information from a designed experimental procedure, which can be useful in equipment or algorithm designs for a wide range of imaging applications.

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采用深度学习方法对琼斯矩阵进行重合成像

相干测量已成为光学成像的一项新兴技术。在测量二阶相干性 g2 的基础上，可以利用开发的算法逐像素提取反射/透射振幅和相位延迟等样本特征。然而，精确测量 g2 需要收集大量光子，这在弱光条件下变得十分困难。在这里，我们提出了一种直接使用光子到达数据进行琼斯矩阵成像的深度学习方法。使用数值数据以无监督的方式训练变异自动编码器（β-VAE），以获得最小的数据表示，只需很少的努力就能将其转换为图像。我们展示了平均每个像素只需收集 88 个光子就能提取出琼斯矩阵图像，其准确性超过了以前从 g2 衍生出的半解析算法。我们的方法不仅能自动制定成像算法，还能评估从设计的实验程序中获得的信息是否充分，这对各种成像应用的设备或算法设计非常有用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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npj Nanophotonics

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