准直系统热光学效应对静态傅里叶变换红外光谱仪光谱复原的影响研究

陈成; 梁静秋; 梁中翥; 吕金光; 秦余欣; 田超; 王维彪

doi:10.7498/aps.64.130703

摘要

在以多级微反射镜为核心器件的静态傅里叶变换红外光谱仪中, 由于准直系统距离红外光源较近, 光源的热辐射会导致其局部温度升高, 从而引起材料折射率发生改变, 使得由准直系统出射的光束存在一定的发散角, 进而影响光谱仪系统复原光谱所能达到的分辨率水平. 本文研究了光谱仪系统正常工作状态下准直系统各区域的温度分布情况, 由此计算出了相应的离焦量. 通过计算准直光束发散角在光程差采样区域内的分布, 分析了由此引入的附加光程差对光谱复原的影响. 通过计算光谱结构误差随准直系统温度的变化, 得到了准直系统温度控制的合理范围. 最后, 对基于SiC光源的光谱仪进行了实验, 结果显示制冷光源复原光谱的光谱结构误差与非制冷光源的光谱结构误差相比有明显改善. 因此, 降低光源温度对减小准直系统热光学效应的影响是非常有效的. 本文的研究结果将为解决同类问题提供参考.

关键词:

Abstract

In a stepped-mirror-based static Fourier transform infrared spectrometer, the collimation lens is located adjacent to the light source and the thermal radiation would lead to the partial temperature increase, and the refractive index of the infrared material unavoidably changes. Then the light beam passing through the collimation lens will induce a divergence angle, directly affecting the resolution of the recovered spectrum. Meanwhile, the angular divergence results in a displacement in the interference signal, making increasing difficulties in the interferogram processing and the spectrum recovery. In this paper, the distribution of temperature in different areas of the collimation lens is studied under the working condition, and the defocusing value of the collimation lens is 0.153 mm that is caused by the refractive index gradient of the infrared material along with the temperature. In addition, the divergence angle induced by defocusing is calculated, its distribution being nonuniform but symmetrical within the sample area. Moreover, the divergence angle brings about additional optical path difference, its effect on the recovered spectrum is analyzed. Compared with the ideal recovered spectrum, much noise emerges and the peak value is reduced in the real recovered spectrum. The spectrum-construction error of the real recovered spectrum is 18.72%, indicating that the recovered spectrum is seriously distorted, and the resolution at the center wavelength in the ideal recovered spectrum and the real spectrum are 4.71 cm-1 and 5.57 cm-1, respectively. This indicates that the spectrum resolving power is weakened. Furthermore, the reasonable temperature range is obtained by analyzing the curve of spectrum-construction error versus temperature of the collimation lens. When a spectrum-construction error of less than 5% is demanded, the temperature difference between the front len of collimation and the ambient must be less than 8 ℃. Finally, experiments are performed using a SiC rod as the light source, and interferograms are made by four steps including dark current electric noise elimination, spatial gain correction, image signal averaging, and spectrum recovery. Results show that the spectrum-construction errors (SCE) from the cold light source and non-cold light source are 8.48% and 21.51%, respectively. Although they are all larger than the theoretical value, the SCE of cold light source decreases by 13.03% compared to cooling-free light source. Hence, it is necessary to reduced the thermal radiation influence on collimation lens from the light source. This result is helpful in solving the analogous problems.

Keywords:

作者及机构信息

1.
中国科学院长春光学精密机械与物理研究所, 应用光学国家重点实验室, 长春 130033;

2.
中国科学院大学, 北京 100049

基金项目: 国家自然科学基金(批准号:61027010,60977062,61376122)、吉林省科技发展计划(批准号:201205025,20130206010GX,20150204072GX)和长春市科技计划(批准号:2011131,2013261)资助的课题.

Authors and contacts

1.
State Key Laboratory of Applied Optics, Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Science, Changchun 130033, China;

2.
University of Chinese Academy of Science, Beijing 100049, China

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 61027010, 60977062, 61376122), the Jilin Province Science and Technology Development Plan, China (Grant Nos. 201205025, 20130206010GX, 20150204072GX), and the Changchun Science Development Plan, China (Grant Nos. 2011131, 2013261).

参考文献

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施引文献

[1]	Dong Q L, Liu Y Q, Teng H, Li Y J, Zhang J 2014 Chin. Phys. B 23 065206
[2]	Giuseppe C, Alexander K, Scott D, Alexander G, Pavel S, Sergey B, Vladimir Y, Stefano C, Christophe P 2014 Light: Science & Applications 3 e203
[3]	Sin J, Lee W H, Popa D, Stephanou H E 2006 Proc. SPIE 6109 610904
[4]	Wallrabe U, Solf C, Mohr J, Korvink J G 2005 Sens. ctu. A 123-124 459
[5]	Kong Y M, Liang J Q, Wang B, Liang Z Z, Xu D W, Zhang J 2009 Spectrosc. Spec. Anal. 4 29 (in Chinese) [孔延梅, 梁静秋, 王波, 梁中翥, 徐大伟, 张军 2009 光谱学与光谱分析 4 29]
[6]	Brachet F, Hébert P J, Cansot E, Buil C, Lacan A, Roucayrol L, Courau E, Bernard F, Casteras C, Loesel J, Pierangelo C 2008 Proc. SPIE 7100 710019
[7]	Lacan A, Bréon F M, Rosak A, Brachet F, Roucayrol L, Etcheto P, Casteras C, Salan Y 2010 Opt. Express 8 18
[8]	Ivanov E V 2000 J . Opt A. Pure Appl. Opt. 6 2
[9]	L J G, Liang J Q, Liang Z Z 2012 Acta phys. sin. 61 140702 (in Chinese) [吕金光, 梁静秋, 梁中翥 2012 61 140702]
[10]	Feng C, Wang B, Liang Z Z, Liang J Q 2011 J. Opt. Soc. Am. B. 1 28
[11]	Zhang Y M 2011 Applied Optics (Vol. 3) (Beijing: Publishing House of Electronics Industry) p561 (in Chinese) [张以谟 2011 应用光学 (北京:电子工业出版社) 第 561 页]
[12]	Saptari V 2003 Fouri-Transfrom Spectroscopy Instrumentation Engineering Washington, SPIE PRESS, 2003 p29
[13]	Zhang C M, Ren W Y, Mu T K 2010 Chin. Phys. B 19 024202
[14]	Kuo C W, Lin C L, Han C Y 2010 Appl. Opt. 19 49
[15]	Yang H S, Kihm H, Moon I K, Jung G J, Choi S C, Lee K J, Hwang H Y, Kim S W, Lee Y W 2011 Appl. Opt. 33 50
[16]	Wang X X, Jiao M Y 2009 J. Appl. Opt. 1 30 (in Chinese) [王学新, 焦明印 2009 应用光学 1 30]
[17]	L J G, Liang J Q, Liang Z Z 2012 Acta phys. sin. 61 070704 (in Chinese) [吕金光, 梁静秋, 梁中翥 2012 61 070704]
[18]	Zhang C M, Huang W J, Zhao B C 2010 Acta Phys. Sin. 59 5479 (in Chinese) [张淳民, 黄伟建, 赵葆常 2010 59 5479]
[19]	Feng C, Liang J Q, Liang Z Z 2011 Appl. Opt. 34 50

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