Single‐Shot Ultraviolet Compressed Ultrafast Photography

Compressed ultrafast photography (CUP) is an emerging potent technique that allows imaging a nonrepeatable or difficult‐to‐produce transient event in a single shot. Despite many recent advances, existing CUP techniques operate only at visible and near‐infrared wavelengths. In addition, spatial encod...

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Published inLaser & photonics reviews Vol. 14; no. 10
Main Authors Lai, Yingming, Xue, Yujia, Côté, Christian‐Yves, Liu, Xianglei, Laramée, Antoine, Jaouen, Nicolas, Légaré, François, Tian, Lei, Liang, Jinyang
Format Journal Article
LanguageEnglish
Published Weinheim Wiley Subscription Services, Inc 01.10.2020
Subjects
Algorithms
compressed ultrafast photography
Field of view
Frames (data processing)
Frames per second
Image enhancement
Image quality
Image reconstruction
image reconstruction techniques
Photocathodes
Photography
plug‐and‐play alternating direction method of multipliers algorithm
single‐shot ultrafast imaging
Streak cameras
ultraviolet
Online AccessGet full text
ISSN1863-8880
1863-8899
DOI10.1002/lpor.202000122

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Abstract Compressed ultrafast photography (CUP) is an emerging potent technique that allows imaging a nonrepeatable or difficult‐to‐produce transient event in a single shot. Despite many recent advances, existing CUP techniques operate only at visible and near‐infrared wavelengths. In addition, spatial encoding via a digital micromirror device (DMD) in CUP systems often limits its field of view and imaging speeds. Finally, conventional reconstruction algorithms have limited control of the reconstruction process to further improve the image quality in the recovered (x,y,t) datacubes of the scene. To overcome these limitations, this article reports a single‐shot UV‐CUP that exhibits a sequence depth of up to 1500 frames with a size of 1750 × 500 (x,y) pixels at an imaging speed of 0.5 trillion frames per second. A patterned photocathode is integrated into a streak camera, which overcomes the previous restrictions in DMD‐based spatial encoding and improves the system's compactness. Meanwhile, the plug‐and‐play alternating direction method of multipliers algorithm is implemented to CUP's image reconstruction to enhance reconstructed image quality. UV‐CUP's single‐shot ultrafast imaging ability is demonstrated by recording UV pulses transmitting through various spatial patterns. UV‐CUP is expected to find many applications in both fundamental and applied science. Single‐shot UV compressed ultrafast photography (UV‐CUP) is developed by integrating a patterned photocathode into a streak camera and by implementing the plug‐and‐play alternating direction method of multipliers algorithm in image reconstruction. UV‐CUP, exhibiting as the world's fastest single‐shot UV camera, has imaged dynamics of spatially modulated ultra‐short UV pulses at 0.5 trillion frames per second in real time.
AbstractList Compressed ultrafast photography (CUP) is an emerging potent technique that allows imaging a nonrepeatable or difficult‐to‐produce transient event in a single shot. Despite many recent advances, existing CUP techniques operate only at visible and near‐infrared wavelengths. In addition, spatial encoding via a digital micromirror device (DMD) in CUP systems often limits its field of view and imaging speeds. Finally, conventional reconstruction algorithms have limited control of the reconstruction process to further improve the image quality in the recovered (x,y,t) datacubes of the scene. To overcome these limitations, this article reports a single‐shot UV‐CUP that exhibits a sequence depth of up to 1500 frames with a size of 1750 × 500 (x,y) pixels at an imaging speed of 0.5 trillion frames per second. A patterned photocathode is integrated into a streak camera, which overcomes the previous restrictions in DMD‐based spatial encoding and improves the system's compactness. Meanwhile, the plug‐and‐play alternating direction method of multipliers algorithm is implemented to CUP's image reconstruction to enhance reconstructed image quality. UV‐CUP's single‐shot ultrafast imaging ability is demonstrated by recording UV pulses transmitting through various spatial patterns. UV‐CUP is expected to find many applications in both fundamental and applied science. Single‐shot UV compressed ultrafast photography (UV‐CUP) is developed by integrating a patterned photocathode into a streak camera and by implementing the plug‐and‐play alternating direction method of multipliers algorithm in image reconstruction. UV‐CUP, exhibiting as the world's fastest single‐shot UV camera, has imaged dynamics of spatially modulated ultra‐short UV pulses at 0.5 trillion frames per second in real time.
Compressed ultrafast photography (CUP) is an emerging potent technique that allows imaging a nonrepeatable or difficult‐to‐produce transient event in a single shot. Despite many recent advances, existing CUP techniques operate only at visible and near‐infrared wavelengths. In addition, spatial encoding via a digital micromirror device (DMD) in CUP systems often limits its field of view and imaging speeds. Finally, conventional reconstruction algorithms have limited control of the reconstruction process to further improve the image quality in the recovered (x,y,t) datacubes of the scene. To overcome these limitations, this article reports a single‐shot UV‐CUP that exhibits a sequence depth of up to 1500 frames with a size of 1750 × 500 (x,y) pixels at an imaging speed of 0.5 trillion frames per second. A patterned photocathode is integrated into a streak camera, which overcomes the previous restrictions in DMD‐based spatial encoding and improves the system's compactness. Meanwhile, the plug‐and‐play alternating direction method of multipliers algorithm is implemented to CUP's image reconstruction to enhance reconstructed image quality. UV‐CUP's single‐shot ultrafast imaging ability is demonstrated by recording UV pulses transmitting through various spatial patterns. UV‐CUP is expected to find many applications in both fundamental and applied science.
Compressed ultrafast photography (CUP) is an emerging potent technique that allows imaging a nonrepeatable or difficult‐to‐produce transient event in a single shot. Despite many recent advances, existing CUP techniques operate only at visible and near‐infrared wavelengths. In addition, spatial encoding via a digital micromirror device (DMD) in CUP systems often limits its field of view and imaging speeds. Finally, conventional reconstruction algorithms have limited control of the reconstruction process to further improve the image quality in the recovered datacubes of the scene. To overcome these limitations, this article reports a single‐shot UV‐CUP that exhibits a sequence depth of up to 1500 frames with a size of 1750 × 500 pixels at an imaging speed of 0.5 trillion frames per second. A patterned photocathode is integrated into a streak camera, which overcomes the previous restrictions in DMD‐based spatial encoding and improves the system's compactness. Meanwhile, the plug‐and‐play alternating direction method of multipliers algorithm is implemented to CUP's image reconstruction to enhance reconstructed image quality. UV‐CUP's single‐shot ultrafast imaging ability is demonstrated by recording UV pulses transmitting through various spatial patterns. UV‐CUP is expected to find many applications in both fundamental and applied science.
Author Liang, Jinyang
Côté, Christian‐Yves
Liu, Xianglei
Légaré, François
Tian, Lei
Laramée, Antoine
Lai, Yingming
Xue, Yujia
Jaouen, Nicolas
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Snippet Compressed ultrafast photography (CUP) is an emerging potent technique that allows imaging a nonrepeatable or difficult‐to‐produce transient event in a single...
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SubjectTerms Algorithms
compressed ultrafast photography
Field of view
Frames (data processing)
Frames per second
Image enhancement
Image quality
Image reconstruction
image reconstruction techniques
Photocathodes
Photography
plug‐and‐play alternating direction method of multipliers algorithm
single‐shot ultrafast imaging
Streak cameras
ultraviolet
Title Single‐Shot Ultraviolet Compressed Ultrafast Photography
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Flpor.202000122
https://www.proquest.com/docview/2449103520
Volume 14
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