双通道成像光谱仪共用离轴三反射光学系统的设计

姚波; 袁立银; 亓洪兴; 舒嵘

红外技术, 2013, 35 (7): 419, 网络出版: 2013-08-05

双通道成像光谱仪共用离轴三反射光学系统的设计

Optical Design of a Dual-channel Imaging Spectrometer Sharing the Off-axis TMA System

论文大纲

姚波 ^*袁立银亓洪兴舒嵘

作者单位

中国科学院上海技术物理研究所空间主动光电技术重点实验室, 上海 20083

光学系统设计双通道成像光谱仪离轴三反射棱镜-全息透射光栅-棱镜 optical design imaging spectrometer off-axis three-mirror system Prism Grating-Prism(PGP)

摘要

提出了一种双通道共用一个主光学的推帚式高光谱成像仪光学系统，该系统由离轴三反射主光学系统、狭缝、准直镜及分色镜、可见近红外光谱仪后光学和短波红外光谱仪后光学组成，设计中采用双通道共用离轴三反射主光学系统，不仅满足了成像仪大视场、宽谱段的要求，而且提高了系统的光学效率，使系统结构更加紧凑，双通道光谱仪均采用棱镜 -全息透射光栅 -棱镜分光组件分光，实现了宽光谱分光，提高了衍射效率，系统实现光谱范围覆盖 450～2500 nm，全视场达 23.9°。

Abstract

This paper presents an optical system for a dual-channel pushbroom hyperspectral imaging spectrometer which shared a main optics. This optical system consists of the main optics, slit, collimator, dichroic mirror and the optical components of VISNIR and SWIR. The two channels sharing off-axis Three-Mirror Anastigmatic (TMA) telescope system is designed, which is not only to meet the requirements of the imager about field of view, wide spectra, but also to improve the optical efficiency and make the system more compact. Prism Grating-Prism (PGP) components are used to achieve a wide spectrum spectrophotometry and high diffraction efficiency, whose response covers the range from 450 to 2500 nm with a 23.9° field of view.

参考文献

[1] 郭华东. 对地观测技术与可持续发展 [M].1版. 北京: 科学出版社, 2001.

[2] Macenka S A, Chrisp M P. Airborne visible/infrared imaging spectrometer (AVIRIS) Spectrometer Design And Performance[C]// Proc. of SPIE, 1987, 834: 32-43.

[3] 薛永祺. 机载扫描成像系统的技术发展 [J].红外与毫米波学报, 1992, 11(3): 169-170.

[4] 邵晖, 王建宇, 薛永祺. 推帚式超光谱成像仪(PHI)关键技术[J].遥感学报, 1998, 11(3): 181-188.

[5] Andreas Mueller, Andrea Hausold. HySens-DAIS/ROSIS Imaging Spectrometers at DLR[C]//Proc. of SPIE, 2002, 4545: 225-235.

[6] Mark Folkman, Jay Peariman. Hyperion hyperspectral imager design, development, characterization, and calibration[C]//Proc. of SPIE, 2001, 4151: 120-129.

[7] Curtiss O Davis, Donald Horan. On-Orbit Calibration of the Naval EarthMap Observer (NEMO) Coastal Ocean Imaging Spectrometer (COIS)[C]//Proc. of SPIE, 2000, 4132: 250-259.

[8] Murchie S L. Compact reconnaissance imaging spectrometer for mars (CRISM) on mars reconnaissance orbiter (MRO)[C]//Proc. of SPIE, 2004, 5660: 66-77.

[9] Green R O. The moon mineralogy mapper: characteristics and early laboratory calibration results[C]//38th Lunar and Planetary Science Conference, 2007: 2354.

[10] 李欢, 周峰. 成像光谱仪宽视场离轴三反望远系统的光学设计 [J].航天返回与遥感, 2012, 33(2): 28-33.

[11] 薛庆生. 星载高分辨力、大视场高光谱成像仪光学设计[J].光电工程, 2011, 38(5): 16-29.

[12] Aikio M. Hyperspectral prism grating prism imaging spectrograph[D]. Finland: VTT Electronics, 2001.

[13] 袁立银. 短波红外棱镜 -光栅-棱镜成像光谱仪光学系统设计 [J].光子学报, 2011, 40(6): 89-96.

姚波, 袁立银, 亓洪兴, 舒嵘. 双通道成像光谱仪共用离轴三反射光学系统的设计[J]. 红外技术, 2013, 35(7): 419. YAO Bo, YUAN Li-yin, QI Hong-xing, SHU Rong. Optical Design of a Dual-channel Imaging Spectrometer Sharing the Off-axis TMA System[J]. Infrared Technology, 2013, 35(7): 419.

双通道成像光谱仪共用离轴三反射光学系统的设计

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