Computational imaging: The improved and the impossible

Andrew R. Harvey; Guillem Carles; Shouqian Chen; Gonzalo Muyo; James Downing; Nick Bustin; Andy Wood

doi:10.1117/12.2193769

Computational imaging: The improved and the impossible

Andrew R. Harvey
, Guillem Carles
, Shouqian Chen
, Gonzalo Muyo
, James Downing
, Nick Bustin
, Andy Wood

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

5 Scopus citations

Abstract

While the performance of optical imaging systems is fundamentally limited by diffraction, the design and manufacture of practical systems is intricately associated with the control of optical aberrations. The fundamental Shannon limit for the number of resolvable pixels by an optical aperture is generally therefore not achieved due to the presence of off-Axis aberrations or large detector pixels. We report how co-called computational-imaging (CI) techniques can enable an increase in imaging performance using more compact optical systems than are achievable with traditional optical design. We report how discontinuous lens elements, either near the pupil or close to the detector, yield complex and spatially variant PSFs that nevertheless provide enhanced transmission of information via the detector to enable imaging systems that are many times shorter and lighter than equivalent traditional imaging systems. Computational imaging has been made possible and attractive with the trend for advanced manufacturing of aspheric, asymmetric lens shapes at lower cost and by the exploitation of low-cost, high-performance digital computation. The continuation of these trends will continue to increase the importance of computational imaging.

Original language	English
Title of host publication	Optical Systems Design 2015
Subtitle of host publication	Optical Design and Engineering VI
Editors	Laurent Mazuray, Andrew P. Wood, Rolf Wartmann
Publisher	SPIE
ISBN (Electronic)	9781628418156
DOIs	https://doi.org/10.1117/12.2193769
State	Published - 2015
Externally published	Yes
Event	Optical Systems Design 2015: Optical Design and Engineering VI - Jena, Germany Duration: 7 Sep 2015 → 10 Sep 2015

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	9626
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Optical Systems Design 2015: Optical Design and Engineering VI
Country/Territory	Germany
City	Jena
Period	7/09/15 → 10/09/15

Keywords

Computational Imaging
multiple apertures

Access to Document

10.1117/12.2193769

Cite this

Harvey, A. R., Carles, G., Chen, S., Muyo, G., Downing, J., Bustin, N., & Wood, A. (2015). Computational imaging: The improved and the impossible. In L. Mazuray, A. P. Wood, & R. Wartmann (Eds.), Optical Systems Design 2015: Optical Design and Engineering VI Article 96260Q (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9626). SPIE. https://doi.org/10.1117/12.2193769

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abstract = "While the performance of optical imaging systems is fundamentally limited by diffraction, the design and manufacture of practical systems is intricately associated with the control of optical aberrations. The fundamental Shannon limit for the number of resolvable pixels by an optical aperture is generally therefore not achieved due to the presence of off-Axis aberrations or large detector pixels. We report how co-called computational-imaging (CI) techniques can enable an increase in imaging performance using more compact optical systems than are achievable with traditional optical design. We report how discontinuous lens elements, either near the pupil or close to the detector, yield complex and spatially variant PSFs that nevertheless provide enhanced transmission of information via the detector to enable imaging systems that are many times shorter and lighter than equivalent traditional imaging systems. Computational imaging has been made possible and attractive with the trend for advanced manufacturing of aspheric, asymmetric lens shapes at lower cost and by the exploitation of low-cost, high-performance digital computation. The continuation of these trends will continue to increase the importance of computational imaging.",

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year = "2015",

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Harvey, AR, Carles, G, Chen, S, Muyo, G, Downing, J, Bustin, N & Wood, A 2015, Computational imaging: The improved and the impossible. in L Mazuray, AP Wood & R Wartmann (eds), Optical Systems Design 2015: Optical Design and Engineering VI., 96260Q, Proceedings of SPIE - The International Society for Optical Engineering, vol. 9626, SPIE, Optical Systems Design 2015: Optical Design and Engineering VI, Jena, Germany, 7/09/15. https://doi.org/10.1117/12.2193769

Computational imaging: The improved and the impossible. / Harvey, Andrew R.; Carles, Guillem; Chen, Shouqian et al.
Optical Systems Design 2015: Optical Design and Engineering VI. ed. / Laurent Mazuray; Andrew P. Wood; Rolf Wartmann. SPIE, 2015. 96260Q (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9626).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Carles, Guillem

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AU - Downing, James

AU - Bustin, Nick

AU - Wood, Andy

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AB - While the performance of optical imaging systems is fundamentally limited by diffraction, the design and manufacture of practical systems is intricately associated with the control of optical aberrations. The fundamental Shannon limit for the number of resolvable pixels by an optical aperture is generally therefore not achieved due to the presence of off-Axis aberrations or large detector pixels. We report how co-called computational-imaging (CI) techniques can enable an increase in imaging performance using more compact optical systems than are achievable with traditional optical design. We report how discontinuous lens elements, either near the pupil or close to the detector, yield complex and spatially variant PSFs that nevertheless provide enhanced transmission of information via the detector to enable imaging systems that are many times shorter and lighter than equivalent traditional imaging systems. Computational imaging has been made possible and attractive with the trend for advanced manufacturing of aspheric, asymmetric lens shapes at lower cost and by the exploitation of low-cost, high-performance digital computation. The continuation of these trends will continue to increase the importance of computational imaging.

KW - Computational Imaging

KW - multiple apertures

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ER -

Computational imaging: The improved and the impossible

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Keywords

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