GHz Optical Time-Stretch Microscopy by Compressive Sensing

Optical time-stretch microscopy has recently attracted intensive attention for its capability of acquiring images at an ultrahigh frame rate. Unfortunately, its achievable frame rate is limited by the requirement of having no overlap between consecutive frames, which leads to a tradeoff between the...

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Bibliographic Details
Published inIEEE photonics journal Vol. 9; no. 2; pp. 1 - 8
Main Authors Cheng Lei, Yi Wu, Sankaranarayanan, Aswin C., Shih-Min Chang, Baoshan Guo, Sasaki, Naoto, Kobayashi, Hirofumi, Chia-Wei Sun, Ozeki, Yasuyuki, Goda, Keisuke
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 01.04.2017
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Classification
Compressive sensing (CS)
Digital cameras
Digital imaging
Digitization
Dispersion
Image acquisition
Image coding
image processing
Microscopy
Optical imaging
Optical microscopy
Optical pulses
Optical sensors
Pulse repetition rate
Spatial resolution
Time compression
time-stretch microscopy
Tradeoffs
Ultrafast optics
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Summary:Optical time-stretch microscopy has recently attracted intensive attention for its capability of acquiring images at an ultrahigh frame rate. Unfortunately, its achievable frame rate is limited by the requirement of having no overlap between consecutive frames, which leads to a tradeoff between the frame rate (pulse repetition rate) and the amount of the temporal dispersion used for optical image serialization. In this paper, we demonstrate compressive sensing on the platform of optical time-stretch microscopy to overcome the tradeoff between frame rate and temporal dispersion (time stretch) and achieve 50 times higher frame rate than conventional optical time-stretch microscopy. Specifically, we computationally perform compressed optical time-stretch microscopy with an experimental dataset acquired by conventional optical time-stretch microscopy and demonstrate its effects in terms of spatial resolution and cell classification accuracy. Our results indicate that the spatial resolution and cell classification accuracy reach 780 nm and 95% at a line scan rate of 675 MHz and 6.75 GHz, respectively, which correspond to five times and 50 times higher frame rates than what conventional optical time-stretch microscopy can achieve with the same dispersion amount and digitizer sampling rate.
ISSN:1943-0655
1943-0655
1943-0647
DOI:10.1109/JPHOT.2017.2676349