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制冷型红外成像系统内部杂散辐射测量方法

常松涛 孙志远 张尧禹 朱玮

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制冷型红外成像系统内部杂散辐射测量方法

常松涛, 孙志远, 张尧禹, 朱玮

Internal stray radiation measurement for cooled infrared imaging systems

Chang Song-Tao, Sun Zhi-Yuan, Zhang Yao-Yu, Zhu Wei
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  • 杂散辐射是红外光学系统设计和检测过程中涉及的一项重要指标.为了定量测量红外成像系统内部杂散辐射, 提出一种基于辐射定标的测量方法, 并通过理论推导和实验验证以说明该方法的合理性.首先, 建立了不带光学系统的辐射定标模型, 即探测器直接接收定标源辐射能, 获得探测器内部因素对系统输出的影响; 然后将其与带有光学系统的定标结果进行比较, 得到由光学系统自身辐射对系统输出的影响, 进而计算红外成像系统内部杂散辐射; 最后通过实验证明了本文理论的正确性.该方法操作简单, 对实验条件要求低, 并可以精确地测量红外成像系统内部杂散辐射.可用于指导红外系统设计中的杂散辐射抑制, 验证系统杂散辐射分析结果是否准确以及检测系统杂散辐射指标是否合格.
    Stray radiation is an important indicator for the infrared optical systems involved in the process of designing and testing. In order to measure the internal stray radiation in infrared imaging systems, a method based on radiometric calibration is proposed, and its rationality is verified by theoretical analysis and experiments. Firstly, the model of radiometric calibration without lens, in other words the detector for absorbing the radiation flux directly from the calibration reference source, is developed to show the influence of internal factors of the detector on the system output. Then it is compared with the results of calibration of the infrared system with a lens to obtain the system output results from the optical system, namely the internal stray radiation caused by the optical system. Finally, experiments are performed to prove the correctness of the theories proposed in this paper. The proposed method has some advantages, such as simple operation, low demand for the experimental conditions, and the capability of measuring the internal stray radiation accurately. It can be used to guide the stray radiation suppression in the process of infrared system designing, to verify the stray radiation analysis results, and to test whether the stray radiation level meets the practical requirements.
    • 基金项目: 国家高技术研究发展计划(863计划)(批准号: 2012AA121502)资助的课题.
    • Funds: Project supported by the National High Technology Research and Development Program of China (Grant No. 2012AA121502).
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    Hunt G H, Shelton G B 1977 SPIE. 107 146

    [2]

    Pravdivtsev A V, Akram M N 2013 Infrared Physics & Technology 60 306

    [3]

    Liu Y, An X Q, Wang Q 2013 Applied Optics 52 4

    [4]

    Xia X L, Shuai Y, Tan H P 2005 Journal of Quantitative Spectroscopy & Radiative Transfer 101

    [5]

    Peng Z Y, Wang X J, Lu J 2013 Acta Phys. Sin. 62 230702 (in Chinese) [彭志勇, 王向军, 卢进 2013 物理学报 62 230702]

    [6]

    Li Y, Liu J F 2013 Acta Opt. Sin. 33 0928002 (in Chinese) [李岩, 刘剑峰 2013 光学学报 33 0928002]

    [7]

    Howard J W, Abel I R 1982 Applied Optics 21 3393

    [8]

    Akram M N 2010 Applied Optics 49 964

    [9]

    Akram M N 2010 Applied Optics 49 1185

    [10]

    Liu Y, An X Q 2012 Acta Optia Sinica 32 0222007 (in Chinese) [刘洋, 安晓强 2012 光学学报 32 0222007]

    [11]

    Fest E C 2013 Stray Light Analysis and Control (SPIE)

    [12]

    Breault R P 1977 SPIE. 107 1

    [13]

    Liepmann T W 2009 SPIE. 7439 743913

    [14]

    Frank Grochocki, John Fleming 2010 SPIE 7794 77940W-1

    [15]

    Birkl R, Lange G, Manhart S, Maurer R 1988 SPIE 967 78

    [16]

    Birkl R, Lange G, Boeswetter C, Lamb G M 1994 SPIE 2260 128

    [17]

    Lightsey P A, Wei Z Y 2012 SPIE 8442 84423B-1

    [18]

    Fan M, Chen L F, Li S S, Tao J H, Su L, Zou M M 2014 Chin. Phys. B 23 104203

    [19]

    Siegel R, Howell J R 1972 Thermal Radiation Heat Transfer (Academic)

    [20]

    Wolfe W L 1998 Introduction to Radiometry (SPIE)

    [21]

    Palmer J M, Grant B G 2010 The Art of Radiometry (SPIE)

  • [1]

    Hunt G H, Shelton G B 1977 SPIE. 107 146

    [2]

    Pravdivtsev A V, Akram M N 2013 Infrared Physics & Technology 60 306

    [3]

    Liu Y, An X Q, Wang Q 2013 Applied Optics 52 4

    [4]

    Xia X L, Shuai Y, Tan H P 2005 Journal of Quantitative Spectroscopy & Radiative Transfer 101

    [5]

    Peng Z Y, Wang X J, Lu J 2013 Acta Phys. Sin. 62 230702 (in Chinese) [彭志勇, 王向军, 卢进 2013 物理学报 62 230702]

    [6]

    Li Y, Liu J F 2013 Acta Opt. Sin. 33 0928002 (in Chinese) [李岩, 刘剑峰 2013 光学学报 33 0928002]

    [7]

    Howard J W, Abel I R 1982 Applied Optics 21 3393

    [8]

    Akram M N 2010 Applied Optics 49 964

    [9]

    Akram M N 2010 Applied Optics 49 1185

    [10]

    Liu Y, An X Q 2012 Acta Optia Sinica 32 0222007 (in Chinese) [刘洋, 安晓强 2012 光学学报 32 0222007]

    [11]

    Fest E C 2013 Stray Light Analysis and Control (SPIE)

    [12]

    Breault R P 1977 SPIE. 107 1

    [13]

    Liepmann T W 2009 SPIE. 7439 743913

    [14]

    Frank Grochocki, John Fleming 2010 SPIE 7794 77940W-1

    [15]

    Birkl R, Lange G, Manhart S, Maurer R 1988 SPIE 967 78

    [16]

    Birkl R, Lange G, Boeswetter C, Lamb G M 1994 SPIE 2260 128

    [17]

    Lightsey P A, Wei Z Y 2012 SPIE 8442 84423B-1

    [18]

    Fan M, Chen L F, Li S S, Tao J H, Su L, Zou M M 2014 Chin. Phys. B 23 104203

    [19]

    Siegel R, Howell J R 1972 Thermal Radiation Heat Transfer (Academic)

    [20]

    Wolfe W L 1998 Introduction to Radiometry (SPIE)

    [21]

    Palmer J M, Grant B G 2010 The Art of Radiometry (SPIE)

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出版历程
  • 收稿日期:  2014-08-12
  • 修回日期:  2014-10-09
  • 刊出日期:  2015-03-05

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