双层谐波双波长红外光学系统的热化光学设计

International Conference on Photonics and Optical Engineering and the Annual West China Photonics Conference Pub Date : 2019-01-24 DOI:10.1117/12.2521909

Fuzeng Kang, Yangyu Fan, Guoyun Lv, Yongsheng Gao, Hao Wang, Yichao Li

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引用次数: 0

摘要

本文建立了双层谐波衍射元件衍射效率随环境温度变化的数学模型，并对其影响进行了分析。对双层HDE结构进行了研究，并根据双层HDE衍射效率方程对其进行了优化。通过选择合适的设计波长，系统在工作波长和工作温度下的平均衍射效率达到99%，显著提高了图像对比度和图像质量。基于双波长320x240元件冷式热红外焦平面阵列探测器，设计了一套双波长红外光学系统。通过引入双层hde和非球面，很好地校正了系统的色差和离轴像差，简化了系统结构。该系统工作在3.7~4.8μm和7.7~9.5μm波段，F数为2，由8个元件组成，具有100%的冷屏蔽效率。图像质量评价结果表明，双波长红外光学系统在-40°~ +60°的温度范围内具有良好的成像性能。

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Athermalization optical design of dual-wavelength infrared optical system with double-layer harmonic elements

A mathematical model of the diffraction efficiency change with the ambient temperature for the double-layer harmonic diffractive elements (HDE) is presented, and its effects are analyzed in this paper. The double-layer HDE structure is investigated and the optimization procedure is based on the equation of diffraction efficiency of the double-layer HDEs. By selecting appropriate design wavelength, the average diffraction efficiency of the system is reaching 99% in working wavelength and working temperature, which improves the image contrast and the image quality significantly. A set of dual-wavelength infrared optical system is designed based on dual-wavelength 320x240 element cooled thermal IR focal plane arrays detector. By introducing double-layer HDEs and aspheric surfaces, the chromatic aberration and the off-axis aberration are well corrected and the system structure is simplified. The system working in the wave band of 3.7~4.8μm and 7.7~9.5μm and with the F number of 2 is consisted of 8 elements and has 100% cold shield efficiency. The image quality evaluating results show that the performance of the dual-wavelength infrared optical system is very well in temperature from -40C° to +60C°.

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International Conference on Photonics and Optical Engineering and the Annual West China Photonics Conference

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