红外与毫米波学报, 2019, 38 (1): 55, 网络出版: 2019-03-19  

大变倍比大相对孔径连续变焦红外光学系统研制

Realization of a continuous-zoom infrared optical system with high ratio and large relative aperture
于洋 1,2,*周潘伟 1,2潘兆鑫 1,2蹇毅 1,2
作者单位
1 中国科学院上海技术物理研究所, 上海 200083
2 中国科学院红外探测与成像技术重点实验室, 上海 200083
摘要
提出了一种新型连续变焦结构形式, 在现有经典四组元机械补偿变焦模型的基础上, 添加一个独立的变倍组, 利用二个变倍组级联的方式获得超大变倍比, 并推导了数学模型.在此基础上, 针对制冷型中波探测器, 研制了一套大变倍比大相对孔径连续变焦红外光学系统, 解决了大相对孔径红外变焦系统变倍比难以提高的问题.该光学系统工作波长3.7~4.8 μm, 冷光阑效率100%, 可实现从焦距6 mm至330 mm连续变焦, 在F数恒定为2的同时, 变倍比高达55倍.该系统仅包含八片镜片, 其中三片镜片独立运动实现变焦.设计结果显示, 该系统在6 mm至330 mm的焦距范围内, 变焦曲线平滑、像质良好.实验室测试和外场成像结果显示, 该系统在整个焦距范围内成像效果清晰, 达到设计要求, 验证了这种新型连续变焦数学模型的应用效果.
Abstract
A new continuous zoom structure was described, and a new independent zoom group was added on the classical four-group-mechanical-compensation. And larger zoom ratio was achieved by the way of two zoom groups cascading. This mathematical model was deduced. Then, according to the cooled mid-wave infrared detector, a continuous-zoom infrared optical system with large zoom ratio and large relative aperture was designed. And the problem that it’s hard for a zoom optical system to achieve both large zoom ratio and large relative aperture was solved. This optical system can zoom from 6 mm to 330 mm, which means it can reach 55x zoom ratio while the F number is 2 constantly. The working waveband was 3.7~4.8 μm, the cold shield efficiency was 100%.It contains only eight lenses, three of them move in order to change the focal length. The result shows that the zoom curves are quite smooth and the image quality is quite good in the whole zoom range. The laboratory test and the out-door imaging experiment shows that the image quality is quite good in the whole zoom range. It proves the application effect of this new kind of zoom model, and shows that the system reaches its design goal.

于洋, 周潘伟, 潘兆鑫, 蹇毅. 大变倍比大相对孔径连续变焦红外光学系统研制[J]. 红外与毫米波学报, 2019, 38(1): 55. YU Yang, ZHOU Pan-Wei, PAN Zhao-Xin, JIAN Yi. Realization of a continuous-zoom infrared optical system with high ratio and large relative aperture[J]. Journal of Infrared and Millimeter Waves, 2019, 38(1): 55.

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