Golay3稀疏孔径成像系统共相误差研究 -

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Golay3稀疏孔径成像系统共相误差研究

doi:10.37188/CO.2022-0203

钱俊宏^{1, 2,},
张蓉竹^1,,

1.
四川大学电子信息学院, 四川成都 610065
2.
成都航空职业技术学院无人机产业学院, 四川成都 610065

基金项目:四川省重大科学仪器设备专项（No. 2019ZDZX0038）

详细信息

作者简介:
钱俊宏（1987—），男，四川广安人，博士，工程师，主要从事产品光机电一体化设计与研究。E-mail：475767903@qq.com
张蓉竹（1975—），女，四川成都人，博士，博士生导师，主要从事精密光学制造与检测研究。E-mail：zhang_rz@scu.edu.cn

中图分类号:O439;
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出版历程
- 收稿日期:2022-09-26
- 修回日期:2022-10-26
- 网络出版日期:2023-02-06

Cophasing error of the Golay3 sparse aperture imaging system

QIAN Jun-hong^{1, 2,},
ZHANG Rong-zhu^1,,

1.
College of Electronics and Information Engineering, Sichuan University, Chengdu 610065， China
2.
School of Unmanned Aerial Vehicles Industry, Chengdu Aeronautic Polytechnic, Chengdu 610065, China

Funds:Supported by Major Science and Technology Project in Sichuan Province (No. 2019ZDZX0038)

More Information

Corresponding author:zhang_rz@scu.edu.cn

摘要

摘要:
稀疏孔径成像系统在校正共相误差后可实现多个子孔径干涉成像，达到提高成像分辨率的目的。本文以Golay3稀疏孔径成像系统为研究对象，分析了子孔径间存在不同活塞误差和倾斜误差时，系统的MTF和面目标成像情况。研制了一套Golay3稀疏孔径成像系统，以USAF1951分辨率板为面目标进行了成像实验。通过调整光束折转调整模块中的平面反射镜位置，校正了子孔径的活塞误差和倾斜误差，实现了三孔径合成成像，并对理论分析结果进行了验证。实验结果表明：所研制系统的角分辨率为1.77 μrad，接近于等效单口径成像系统的理论极限分辨率1.18 μrad。所研制的Golay3稀疏孔径成像系统能有效校正共相误差，提高成像分辨率。
- 稀疏孔径成像/
- 共相误差/
- 分辨率板/
- 面目标成像/
- 角分辨率
Abstract:
Multiple sub-aperture interference imaging enables the images formed by the sparse aperture imaging system to have a higher resolution after the cophasing error is corrected. In this paper, the MTF and surface target imaging of the system are analyzed with a Golay3 sparse aperture imaging system as the research object when there are different piston and tilt errors among the sub-apertures. A Golay3 sparse aperture imaging system was developed to carry out an imaging experiment with the USAF1951 resolving power test target as the area target. Three-aperture synthetic imaging is achieved by adjusting the position of the plane mirror in the light beam deflection and the adjustment module to correct the piston and tilt errors of the sub-apertures. The results of a theoretical analysis are then verified. According to calculations, the developed system’s angular resolution of 1.38 μrad is close to the equivalent single-aperture imaging system’s theoretical resolution of 1.18 μrad. The developed Golay3 sparse aperture imaging system can correct the cophasing errors and improve the imaging resolution.
- sparse aperture imaging/
- cophasing error/
- resolution target/
- surface target imaging/
- angular resolution

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图 1Golay3阵列结构

Figure 1.Golay3 array structure

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图 2Golay3光学系统

Figure 2.Golay3 optical system

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图 3MTF随填充因子F变化曲线

Figure 3.MTF varies with the filling factorF

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图 4成像模拟对比结果

Figure 4.Imaging simulation comparison results

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图 5子孔径1共相误差

Figure 5.Cophasing error of sub-aperture 1

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图 6子孔径1存在不同活塞误差时三孔径系统的MTF

Figure 6.MTFs of Golay3 optical system when sub-aperture 1 has different piston errors

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图 7子孔径1存在不同倾斜误差时三孔径系统的MTF

Figure 7.MTFs of Golay3 optical system when sub-aperture 1 has different tilt errors

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图 8不同活塞误差下的模拟成像结果

Figure 8.Simulated imaging results under different piston errors

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图 9不同倾斜误差下的模拟成像结果

Figure 9.Simulated imaging results under different tilt errors

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图 10Tenengrad图像清晰度评价结果

Figure 10.Tenengrad image sharpness evaluation results

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图 11Golay3稀疏孔径成像系统

Figure 11.Golay3 sparse aperture imaging system

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图 12单孔径和三孔径成像系统MTF对比

Figure 12.Comparison of MTF of a single-aperture and three-apertures imaging system

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图 13光束折转调整结构

Figure 13.Beam steering and adjustment structure

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图 14FSM结构

Figure 14.FSM structure

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图 15点目标成像结果

Figure 15.Point source imaging

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图 16面目标输入图像

Figure 16.Input image of surface target

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图 17面目标成像实验结果

Figure 17.Results of the surface target image source experiment

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表 1所设计Golay3稀疏孔径成像系统设计参数

Table 1.Design specifications of the Golay3 sparse aperture imaging system

序号	参数	设计值
1	子孔径口径d	200 mm
2	等效口径D	570 mm
3	系统焦距f	6000 mm
4	全视场角h	0.2°
5	工作波段	0.48～0.65 μm

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表 2理论结果和实测结果对比

Table 2.Comparison of theoretical and measured results

参数名称	单孔径	三孔径	提高倍数
极限角分辨率	3.36 μrad	1.18 μrad	2.85
实测角分辨率	4.47 μrad	1.77 μrad	2.53

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