Design of infrared afocal zoom system

Jun Chang; Zhicheng Weng; Yongtian Wang; Huilin Jiang; Xiaojie Cong

doi:10.1117/12.668175

Design of infrared afocal zoom system

Jun Chang^*, Zhicheng Weng, Yongtian Wang, Huilin Jiang, Xiaojie Cong

^*Corresponding author for this work

School of Optics and Photonics

Research output: Contribution to journal › Conference article › peer-review

8 Citations (Scopus)

Abstract

The design method and result are described for an infrared afocal zoom system. Its zoom ratio is 4, and the corresponding field of view is 3°-12°. The working waveband is from 7.5μm to 10.5μm, and its total length is required to be no more than 350mm. The final optical system consists of 7 elements, with aspheric surfaces and a diffractive optical element. It achieves diffraction-limited imaging at the far infrared waveband. Two conclusions can be drawn from the design. (1) Using diffractive optical elements in the design of an infrared optical system is an effective approach to control color aberrations, which eliminates the need to use exotic and expensive materials and helps to reduce the cost of the system; (2) Functions such as changing the field-of-view, focusing for objects at finite distances and athermalizing the system can be achieved by axially moving a single element in the system.

Original language	English
Article number	603420
Journal	Proceedings of SPIE - The International Society for Optical Engineering
Volume	6034
DOIs	https://doi.org/10.1117/12.668175
Publication status	Published - 2006
Event	ICO20: Optical Design and Fabrication - Changchun, China Duration: 21 Aug 2005 → 26 Aug 2005

Keywords

Diffractive optical element
Infrared system
Optical design

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10.1117/12.668175

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title = "Design of infrared afocal zoom system",

abstract = "The design method and result are described for an infrared afocal zoom system. Its zoom ratio is 4, and the corresponding field of view is 3°-12°. The working waveband is from 7.5μm to 10.5μm, and its total length is required to be no more than 350mm. The final optical system consists of 7 elements, with aspheric surfaces and a diffractive optical element. It achieves diffraction-limited imaging at the far infrared waveband. Two conclusions can be drawn from the design. (1) Using diffractive optical elements in the design of an infrared optical system is an effective approach to control color aberrations, which eliminates the need to use exotic and expensive materials and helps to reduce the cost of the system; (2) Functions such as changing the field-of-view, focusing for objects at finite distances and athermalizing the system can be achieved by axially moving a single element in the system.",

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journal = "Proceedings of SPIE - The International Society for Optical Engineering",

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TY - JOUR

T1 - Design of infrared afocal zoom system

AU - Chang, Jun

AU - Weng, Zhicheng

AU - Wang, Yongtian

AU - Jiang, Huilin

AU - Cong, Xiaojie

PY - 2006

Y1 - 2006

N2 - The design method and result are described for an infrared afocal zoom system. Its zoom ratio is 4, and the corresponding field of view is 3°-12°. The working waveband is from 7.5μm to 10.5μm, and its total length is required to be no more than 350mm. The final optical system consists of 7 elements, with aspheric surfaces and a diffractive optical element. It achieves diffraction-limited imaging at the far infrared waveband. Two conclusions can be drawn from the design. (1) Using diffractive optical elements in the design of an infrared optical system is an effective approach to control color aberrations, which eliminates the need to use exotic and expensive materials and helps to reduce the cost of the system; (2) Functions such as changing the field-of-view, focusing for objects at finite distances and athermalizing the system can be achieved by axially moving a single element in the system.

AB - The design method and result are described for an infrared afocal zoom system. Its zoom ratio is 4, and the corresponding field of view is 3°-12°. The working waveband is from 7.5μm to 10.5μm, and its total length is required to be no more than 350mm. The final optical system consists of 7 elements, with aspheric surfaces and a diffractive optical element. It achieves diffraction-limited imaging at the far infrared waveband. Two conclusions can be drawn from the design. (1) Using diffractive optical elements in the design of an infrared optical system is an effective approach to control color aberrations, which eliminates the need to use exotic and expensive materials and helps to reduce the cost of the system; (2) Functions such as changing the field-of-view, focusing for objects at finite distances and athermalizing the system can be achieved by axially moving a single element in the system.

KW - Diffractive optical element

KW - Infrared system

KW - Optical design

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SN - 0277-786X

VL - 6034

JO - Proceedings of SPIE - The International Society for Optical Engineering

JF - Proceedings of SPIE - The International Society for Optical Engineering

M1 - 603420

T2 - ICO20: Optical Design and Fabrication

Y2 - 21 August 2005 through 26 August 2005

ER -

Design of infrared afocal zoom system

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