TY - JOUR
T1 - Ultrahigh-throughput single-pixel complex-field microscopy with frequency-comb acousto-optic coherent encoding (FACE)
AU - Wu, Daixuan
AU - Shen, Yuecheng
AU - Zhu, Zhongzheng
AU - Li, Tijian
AU - Luo, Jiawei
AU - Wang, Zhengyang
AU - Liang, Jiaming
AU - Zhang, Zhiling
AU - Yao, Yunhua
AU - Qi, Dalong
AU - Deng, Lianzhong
AU - Sun, Zhenrong
AU - Liu, Meng
AU - Luo, Zhi Chao
AU - Zhang, Shian
N1 - Publisher Copyright:
© The Author(s) 2025.
PY - 2025/12
Y1 - 2025/12
N2 - Single-pixel imaging (SPI) is a promising technology for optical imaging beyond the visible spectrum, where commercial cameras are expensive or unavailable. However, limitations such as slow pattern projection rates and time-consuming reconstruction algorithms hinder its throughput for real-time imaging. Consequently, conventional SPI is inadequate for high-speed, high-resolution tasks. To address these challenges, we developed an ultrahigh-throughput single-pixel complex-field microscopy (SPCM) system utilizing frequency-comb acousto-optic coherent encoding (FACE). This system enables real-time complex-field monitoring in the non-visible domain. Operating at 1030 nm, our system achieves a record-high space-bandwidth-time product (SBP-T) of 1.3 × 107, surpassing previous SPCM (~104), SPI (~105), and even certain types of commercial near-infrared cameras (~106). It supports real-time streaming at 1000 Hz with a frame size of 80 × 81 pixels and a lateral resolution of 3.76 μm across an approximately 300 μm field of view. We validated the system by imaging dynamic transparent scenes, including microfluidics, live microorganisms, chemical reactions, as well as imaging through scattering media. This advancement offers a superior solution for high-speed, high-resolution complex-field imaging beyond the visible spectrum, significantly enhancing SPI performance across various applications.
AB - Single-pixel imaging (SPI) is a promising technology for optical imaging beyond the visible spectrum, where commercial cameras are expensive or unavailable. However, limitations such as slow pattern projection rates and time-consuming reconstruction algorithms hinder its throughput for real-time imaging. Consequently, conventional SPI is inadequate for high-speed, high-resolution tasks. To address these challenges, we developed an ultrahigh-throughput single-pixel complex-field microscopy (SPCM) system utilizing frequency-comb acousto-optic coherent encoding (FACE). This system enables real-time complex-field monitoring in the non-visible domain. Operating at 1030 nm, our system achieves a record-high space-bandwidth-time product (SBP-T) of 1.3 × 107, surpassing previous SPCM (~104), SPI (~105), and even certain types of commercial near-infrared cameras (~106). It supports real-time streaming at 1000 Hz with a frame size of 80 × 81 pixels and a lateral resolution of 3.76 μm across an approximately 300 μm field of view. We validated the system by imaging dynamic transparent scenes, including microfluidics, live microorganisms, chemical reactions, as well as imaging through scattering media. This advancement offers a superior solution for high-speed, high-resolution complex-field imaging beyond the visible spectrum, significantly enhancing SPI performance across various applications.
UR - https://www.scopus.com/pages/publications/105012925689
U2 - 10.1038/s41377-025-01931-w
DO - 10.1038/s41377-025-01931-w
M3 - 文章
AN - SCOPUS:105012925689
SN - 2047-7538
VL - 14
JO - Light: Science and Applications
JF - Light: Science and Applications
IS - 1
M1 - 266
ER -