Single-Pixel Imaging and Its Application in Three-Dimensional Reconstruction: A Brief Review

Whereas modern digital cameras use a pixelated detector array to capture images, single-pixel imaging reconstructs images by sampling a scene with a series of masks and associating the knowledge of these masks with the corresponding intensity measured with a single-pixel detector. Though not perform...

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Vydané v:	Sensors (Basel, Switzerland) Ročník 19; číslo 3; s. 732
Hlavní autori:	Sun, Ming-Jie, Zhang, Jia-Min
Médium:	Journal Article
Jazyk:	English
Vydavateľské údaje:	Switzerland MDPI AG 11.02.2019 MDPI
Predmet:	Algorithms Arrays compressive sensing depth mapping Digital cameras ghost imaging Image retrieval Light Microscopy Photonics Review Sensors single-pixel imaging stereo vision three-dimensional imaging time-of-flight United States > US ghost imaging single-pixel imaging three-dimensional imaging time-of-flight depth mapping stereo vision compressive sensing
ISSN:	1424-8220, 1424-8220
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Abstract	Whereas modern digital cameras use a pixelated detector array to capture images, single-pixel imaging reconstructs images by sampling a scene with a series of masks and associating the knowledge of these masks with the corresponding intensity measured with a single-pixel detector. Though not performing as well as digital cameras in conventional visible imaging, single-pixel imaging has been demonstrated to be advantageous in unconventional applications, such as multi-wavelength imaging, terahertz imaging, X-ray imaging, and three-dimensional imaging. The developments and working principles of single-pixel imaging are reviewed, a mathematical interpretation is given, and the key elements are analyzed. The research works of three-dimensional single-pixel imaging and their potential applications are further reviewed and discussed.
AbstractList	Whereas modern digital cameras use a pixelated detector array to capture images, single-pixel imaging reconstructs images by sampling a scene with a series of masks and associating the knowledge of these masks with the corresponding intensity measured with a single-pixel detector. Though not performing as well as digital cameras in conventional visible imaging, single-pixel imaging has been demonstrated to be advantageous in unconventional applications, such as multi-wavelength imaging, terahertz imaging, X-ray imaging, and three-dimensional imaging. The developments and working principles of single-pixel imaging are reviewed, a mathematical interpretation is given, and the key elements are analyzed. The research works of three-dimensional single-pixel imaging and their potential applications are further reviewed and discussed. Whereas modern digital cameras use a pixelated detector array to capture images, single-pixel imaging reconstructs images by sampling a scene with a series of masks and associating the knowledge of these masks with the corresponding intensity measured with a single-pixel detector. Though not performing as well as digital cameras in conventional visible imaging, single-pixel imaging has been demonstrated to be advantageous in unconventional applications, such as multi-wavelength imaging, terahertz imaging, X-ray imaging, and three-dimensional imaging. The developments and working principles of single-pixel imaging are reviewed, a mathematical interpretation is given, and the key elements are analyzed. The research works of three-dimensional single-pixel imaging and their potential applications are further reviewed and discussed.Whereas modern digital cameras use a pixelated detector array to capture images, single-pixel imaging reconstructs images by sampling a scene with a series of masks and associating the knowledge of these masks with the corresponding intensity measured with a single-pixel detector. Though not performing as well as digital cameras in conventional visible imaging, single-pixel imaging has been demonstrated to be advantageous in unconventional applications, such as multi-wavelength imaging, terahertz imaging, X-ray imaging, and three-dimensional imaging. The developments and working principles of single-pixel imaging are reviewed, a mathematical interpretation is given, and the key elements are analyzed. The research works of three-dimensional single-pixel imaging and their potential applications are further reviewed and discussed.
Author	Zhang, Jia-Min Sun, Ming-Jie
AuthorAffiliation	School of Instrumentation Science and Optoelectronic Engineering, Beihang University, Beijing 100191, China; jiamin960505@163.com
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BackLink	https://www.ncbi.nlm.nih.gov/pubmed/30754728$$D View this record in MEDLINE/PubMed
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Snippet	Whereas modern digital cameras use a pixelated detector array to capture images, single-pixel imaging reconstructs images by sampling a scene with a series of...
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SubjectTerms	Algorithms Arrays compressive sensing depth mapping Digital cameras ghost imaging Image retrieval Light Microscopy Photonics Review Sensors single-pixel imaging stereo vision three-dimensional imaging time-of-flight
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Title	Single-Pixel Imaging and Its Application in Three-Dimensional Reconstruction: A Brief Review
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