单像素复光场成像研究进展

doi:10.3969/j.issn.1007-5461.2022.06.001

摘要/Abstract

摘要： 单像素成像通过时间变化的结构编码将高维度信息编码到一维探测序列中来，仅通过一个单像素探测器即可实现高维度的成像。得益于单像素成像对探测器极低的分辨率要求，在特殊波段成像、极弱光成像、激光雷达探测等领域有着重要的研究价值。复光场成像相较于传统强度成像可以同时获得光场的相位信息，在无标记显微成像、表面测量、晶体测量等领域发挥着巨大的作用。将单像素成像手段引入复光场成像领域，将有效降低复光场成像在弱光显微成像与测量等场景下的探测成本。从单像素成像以及复光场探测的基本原理出发，详细介绍了单像素复光场成像的研究现状及最新进展，对现有的问题做了具体分析，并对今后可能的发展方向做了展望。

Abstract: Single-pixel imaging achieves high-dimensional imaging with only a single-pixel detector, in which the high-dimensional information is encoded into a one-dimensional detection sequence through time-varying structured patterns. Due to its minimum requirement for detector’s resolution, single-pixel imaging has great research value in special waveband imaging, extremely low light imaging, and lidar detection. Compared with the traditional intensity imaging, the complex optical field imaging can obtain the phase information, therefore, performs a great value in label-free microscopy imaging, surface measurement, and crystal analysis. Combining with the advantages of both single-pixel imaging and complex optical imaging, single-pixel complex optical imaging has drawn widely attentions and can be applied in low-light microscopy imaging and measurement. Starting from the basic principles of single-pixel imaging and complex light field detection, we will review the basic principles of single-pixel imaging and complex optical field imaging, introduce some recent advances of single-pixel optical field imaging, the challenging problems as well as future research directions will also be discussed.

中图分类号:

O438.2

郭岩, 何忆康, 李显业∗ , 孙宝清. 单像素复光场成像研究进展[J]. 量子电子学报, 2022, 39(6): 817-834.

GUO Yan, HE Yikang, LI Xianye ∗ , SUN Baoqing. Recent advances in single-pixel complex optical field imaging[J]. Chinese Journal of Quantum Electronics, 2022, 39(6): 817-834.

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