-
The traditional window of high-speed aircraft is hemispherical, and the aberration produced by such a window is constant. However, the hemispherical window is difficult to meet the requirements of a high speed flight of aircraft. Aspheric windows are usually used to replace hemispherical windows to increase the aerodynamic performance. However, the aspheric window will introduce dynamic aberrations that fluctuate with the change of scanning field-of-view (FOV), which becomes the key issue of the development of optoelectronic imaging systems for high-speed aircraft. For the ellipsoidal window optical system with scanning FOV of ±60°, an aberration correction method in large FOV combined with the static correction and non-wavefront-sensor adaptive optical correction is studied. In the initial optical structure design, the types of system aberration are reduced and the fifth-order Zernike aberration is eliminated during initial aberration correction, thus, the number of the subsequent adaptive optimization control variables is reduced. According to the characteristics of the deformable mirror, the driving voltage of the driver is generally taken as a variable of the genetic algorithm. However, when the deformable mirror used has many units, too many variables will directly lead the optimization speed of the algorithm to greatly decrease. So, according to the aberration characteristics of the ellipsoidal optical window, using the conversion matrix between the Zernike polynomial coefficients and the voltages of the deformable mirror driver, the optimization variable is reduced from 140 driver voltages to 2−9 Zernike stripe polynomial coefficients in number. Finally, the genetic algorithm based on Zernike model is used to control the shape of the deformable mirror and correct the residual aberration. Taking 2−9 Zernike mode coefficients, 2−16 Zernike mode coefficients and 140 driver voltages as the variables of genetic algorithm respectively, the optimization generations of genetic algorithm under different variables are obtained. The simulation results show that the optimization speed of each typical scanning field of view is increased more than 95% by changing the variable from 140 driver voltages to 2−9 Zernike mode coefficients, and the imaging quality is close to the diffraction limit. This optimization method can not only correct the aberrations caused by the special-shaped optical window, but also compensate for the error caused by processing and aligning the optical system.
-
Keywords:
- aspheric window /
- Zernike polynomials /
- deformable mirror /
- genetic algorithm
[1] Zhang Y Q, Chang J, Dang F Y, Bai X D, Pan G Q 2020 Chin. Opt. Lett 18 072201
Google Scholar
[2] Knapp D 2002 Proc. SPIE 4832 394
Google Scholar
[3] 薛文慧, 王惠, 包春慧, 范志刚 2017 应用光学 38 1000
Google Scholar
Xue W H, Wang H, Bao C H, Fan Z G 2017 J. Appl. Opt. 38 1000
Google Scholar
[4] 史要涛, 翟金龙, 陈守谦, 范志刚 2016 航空兵器 1 51
Google Scholar
Shi Y T, Zhai J L, Chen S Q, Fan Z G 2016 Aero. Weap. 1 51
Google Scholar
[5] 张运强, 常军, 潘国庆 2019 应用光学 40 965
Google Scholar
Zhang Y Q, Chang J, Pan G Q 2019 J. Appl. Opt. 40 965
Google Scholar
[6] 张旺, 汪东生 2014 光学学报 34 61
Google Scholar
Zhang W, Wang D S 2014 Acta Opt. Sin. 34 61
Google Scholar
[7] 李衍璋, 黄长春, 张运强, 牛亚军, 宋大林, 常军 2017 红外与激光工程 46 11
Google Scholar
Li H Z, Huang C C, Zhang Y Q, Niu Y J, Song D L, Chang J 2017 Infraed Laser Eng. 46 11
Google Scholar
[8] 常军, 刘莉萍, 程德文, 赵楠 2009 红外与毫米波学报 28 204
Google Scholar
Chang J, Liu L P, Cheng D W, Zhao N 2009 J. Infrared Milli. Waves 28 204
Google Scholar
[9] 常军, 何伍斌, 冯树龙 2011 北京理工大学学报 31 333
Google Scholar
Chang J, He W B, Feng S L 2011 J. B. Inst. Techno. 31 333
Google Scholar
[10] Song D, Chang J 2013 Optik 124 2455
Google Scholar
[11] Morgan D, Cook L 1996 US Patent 6018424
[12] Chen C 1997 US Patent 6091548
[13] Yu J Q, Chen S Q, Dang F Y, Li X S, Shi X T, Ju L, Wang H, Xu X M, Fan Z G 2020 Opt. Commun. 463 125121
Google Scholar
[14] 王超, 张新, 王灵杰, 曲贺盟, 王超 2013 红外与毫米波学报 32 260
Google Scholar
Wang C, Zhang X, Wang L J, Qu H M, Wang C 2013 J. Infrared Milli. Waves 32 260
Google Scholar
[15] Dong B, Li Y, Han X L, Hu B 2016 Sensors 16 1414
Google Scholar
[16] 李东熙, 卢振武, 孙强, 刘华, 张云翠 2007 物理学报 56 5766
Google Scholar
Li D X, Lu Z W, Sun Q, Liu H, Zhang Y C 2007 Acta Phys. Sin. 56 5766
Google Scholar
[17] 孙金霞, 孙强, 李东熙, 卢振武 2007 物理学报 56 3900
Google Scholar
Sun J X, Sun Q, Li D X, Lu Z W 2007 Acta Phys. Sin. 56 3900
Google Scholar
[18] Crowther B, McKenney D, Mills J 1998 Proc. SPIE 3482 4861
Google Scholar
[19] 郭爱林, 朱海东, 杨泽平, 唐仕旺, 谢兴龙, 朱建强 2013 光学学报 33 11
Google Scholar
Guo A L, Zhu H D, Yang Z P, Tang S W, Xie X L, Zhu J Q 2013 Acta Opt. Sin. 33 11
Google Scholar
[20] 陆金桂, 李谦, 王浩, 曹一家 1997 遗传算法原理及其工程应用 (徐州: 中国矿业大学出版社) 第8页
Lu J G, Li Q, Wang H, Cao Y J 1997 Principle of Genetic Algorithm and its Engineering Application (Xuzhou: China University of Mining and Technology Press) p8 (in Chinese)
[21] 王超 2014博士学位论文 (北京: 中国科学院大学)
Wang C 2014 Ph. D. Dissertation (Beijing: University of Chinese Academy of Sciences) (in Chinese)
[22] 杨华峰 2008 博士学位论文 (长沙: 国防科学技术大学)
Yang H F 2008 Ph. D. Dissertation (Changsha: National University of Defense Technology) (in Chinese)
[23] 周仁忠, 阎吉祥, 赵达尊, 曹根瑞, 俞信 1996 自适应光学 (北京: 国防工业出版社) 第320页
Zhou R Z, Yan J X, Zhao D Z, Cao D Z, Yu R 1996 Adaptive Optics (Beijing: National Defense Industry Press) p320 (in Chinese)
[24] 周仁忠, 阎吉祥 1996 自适应光学理论 (北京: 北京理工大学出版社) 第371页
Zhou R Z, Yan J X 1996 Adaptive Optics Theory (Beijing: Beijing Institute of Technology Press) p371 (in Chinese)
-
图 1 椭球形窗口和观测系统的示意图
Figure 1. Schematic diagram of ellipsoid window and observation system.
图 2 Zernike系数随视场变化
Figure 2. Variation of Zernike coefficients with field of view.
图 3 椭球形窗口光学系统光路图
Figure 3. Optical path diagram of ellipsoid window optical system.
图 4 优化后Zernike系数随视场变化
Figure 4. Variation of Zernike coefficients with field of view after optimization.
图 5 变形镜驱动器排布
Figure 5. Actuator arrangement of deformable mirror.
图 6 遗传算法流程图
Figure 6. Flow chart of genetic algorithm.
图 7 不同变量下的优化代数
Figure 7. Optimization generations with different variables.
图 8 不同变焦位置的MTF图 (a) 0°; (b) 20°; (c) 40°; (d) 60°
Figure 8. MTF for different zoom positions: (a) 0°; (b) 20°; (c) 40°; (d) 60°.
-
[1] Zhang Y Q, Chang J, Dang F Y, Bai X D, Pan G Q 2020 Chin. Opt. Lett 18 072201
Google Scholar
[2] Knapp D 2002 Proc. SPIE 4832 394
Google Scholar
[3] 薛文慧, 王惠, 包春慧, 范志刚 2017 应用光学 38 1000
Google Scholar
Xue W H, Wang H, Bao C H, Fan Z G 2017 J. Appl. Opt. 38 1000
Google Scholar
[4] 史要涛, 翟金龙, 陈守谦, 范志刚 2016 航空兵器 1 51
Google Scholar
Shi Y T, Zhai J L, Chen S Q, Fan Z G 2016 Aero. Weap. 1 51
Google Scholar
[5] 张运强, 常军, 潘国庆 2019 应用光学 40 965
Google Scholar
Zhang Y Q, Chang J, Pan G Q 2019 J. Appl. Opt. 40 965
Google Scholar
[6] 张旺, 汪东生 2014 光学学报 34 61
Google Scholar
Zhang W, Wang D S 2014 Acta Opt. Sin. 34 61
Google Scholar
[7] 李衍璋, 黄长春, 张运强, 牛亚军, 宋大林, 常军 2017 红外与激光工程 46 11
Google Scholar
Li H Z, Huang C C, Zhang Y Q, Niu Y J, Song D L, Chang J 2017 Infraed Laser Eng. 46 11
Google Scholar
[8] 常军, 刘莉萍, 程德文, 赵楠 2009 红外与毫米波学报 28 204
Google Scholar
Chang J, Liu L P, Cheng D W, Zhao N 2009 J. Infrared Milli. Waves 28 204
Google Scholar
[9] 常军, 何伍斌, 冯树龙 2011 北京理工大学学报 31 333
Google Scholar
Chang J, He W B, Feng S L 2011 J. B. Inst. Techno. 31 333
Google Scholar
[10] Song D, Chang J 2013 Optik 124 2455
Google Scholar
[11] Morgan D, Cook L 1996 US Patent 6018424
[12] Chen C 1997 US Patent 6091548
[13] Yu J Q, Chen S Q, Dang F Y, Li X S, Shi X T, Ju L, Wang H, Xu X M, Fan Z G 2020 Opt. Commun. 463 125121
Google Scholar
[14] 王超, 张新, 王灵杰, 曲贺盟, 王超 2013 红外与毫米波学报 32 260
Google Scholar
Wang C, Zhang X, Wang L J, Qu H M, Wang C 2013 J. Infrared Milli. Waves 32 260
Google Scholar
[15] Dong B, Li Y, Han X L, Hu B 2016 Sensors 16 1414
Google Scholar
[16] 李东熙, 卢振武, 孙强, 刘华, 张云翠 2007 物理学报 56 5766
Google Scholar
Li D X, Lu Z W, Sun Q, Liu H, Zhang Y C 2007 Acta Phys. Sin. 56 5766
Google Scholar
[17] 孙金霞, 孙强, 李东熙, 卢振武 2007 物理学报 56 3900
Google Scholar
Sun J X, Sun Q, Li D X, Lu Z W 2007 Acta Phys. Sin. 56 3900
Google Scholar
[18] Crowther B, McKenney D, Mills J 1998 Proc. SPIE 3482 4861
Google Scholar
[19] 郭爱林, 朱海东, 杨泽平, 唐仕旺, 谢兴龙, 朱建强 2013 光学学报 33 11
Google Scholar
Guo A L, Zhu H D, Yang Z P, Tang S W, Xie X L, Zhu J Q 2013 Acta Opt. Sin. 33 11
Google Scholar
[20] 陆金桂, 李谦, 王浩, 曹一家 1997 遗传算法原理及其工程应用 (徐州: 中国矿业大学出版社) 第8页
Lu J G, Li Q, Wang H, Cao Y J 1997 Principle of Genetic Algorithm and its Engineering Application (Xuzhou: China University of Mining and Technology Press) p8 (in Chinese)
[21] 王超 2014博士学位论文 (北京: 中国科学院大学)
Wang C 2014 Ph. D. Dissertation (Beijing: University of Chinese Academy of Sciences) (in Chinese)
[22] 杨华峰 2008 博士学位论文 (长沙: 国防科学技术大学)
Yang H F 2008 Ph. D. Dissertation (Changsha: National University of Defense Technology) (in Chinese)
[23] 周仁忠, 阎吉祥, 赵达尊, 曹根瑞, 俞信 1996 自适应光学 (北京: 国防工业出版社) 第320页
Zhou R Z, Yan J X, Zhao D Z, Cao D Z, Yu R 1996 Adaptive Optics (Beijing: National Defense Industry Press) p320 (in Chinese)
[24] 周仁忠, 阎吉祥 1996 自适应光学理论 (北京: 北京理工大学出版社) 第371页
Zhou R Z, Yan J X 1996 Adaptive Optics Theory (Beijing: Beijing Institute of Technology Press) p371 (in Chinese)
DownLoad:
Catalog
Metrics
- Abstract views: 7918
- PDF Downloads: 110
- Cited By: 0
