基于阵列光学的快速多维度成像制导光学系统设计

史浩东; 卢琦; 赵义武; 王稼禹; 赵晓; 李英超; 付强

doi:10.37188/CO.2023-0206

基于阵列光学的快速多维度成像制导光学系统设计

doi: 10.37188/CO.2023-0206

史浩东^1,,
卢琦^{1, 2, ,},
赵义武¹,
王稼禹^{1, 2},
赵晓³,
李英超¹,
付强¹

1.
长春理工大学吉林省空间光电技术重点实验室, 吉林长春 130022
2.
长春理工大学光电工程学院, 吉林长春 130022
3.
东北工业集团有限公司, 吉林长春 130103

基金项目: 吉林省教育厅科学技术研究项目（No. JJKH20230813KJ）

详细信息

作者简介:
史浩东（1989—），男，吉林长春人，博士，副研究员，博士生导师，主要从事先进光学系统设计及多维度探测方面的研究。E-mail：shihaodong08@163.com

卢　琦（1999—），男，广西桂林人，硕士研究生，2021年于长春理工大学获得学士学位，主要从事光学系统设计及探测制导方面的研究。E-mail：luqi9942@163.com

中图分类号: O435.1;O435.2;O436.3
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出版历程
- 网络出版日期: 2024-04-30

Design of a fast multidimensional imaging guidance optical system based on array optics

SHI Hao-dong^1
,,
LU Qi^{1, 2
, ,},
ZHAO Yi-wu¹,
WANG Jia-yu^{1, 2},
ZHAO Xiao³,
LI Ying-chao¹,
FU Qiang¹

1.
Jilin Provincial Key Laboratory of Space Optoelectronics Technology, Changchun University of Science and Technology, Changchun 130022, Jilin, China
2.
School of Opto-Electronic Engineering, Changchun University of Science and Technology, Changchun 130022, Jilin, China
3.
Northeast Industries Group Co., Ltd. Changchun 130103, Jilin, China

Funds: Supported by

More Information

Corresponding author: luqi9942@163.com

摘要

摘要:
针对传统偏振光谱成像方法难以适用于弹载平台的瓶颈，提出基于阵列光学的快速多维度成像制导光学方案；构建了通道分辨率与望远放大倍率的关联模型，实现了微透镜阵列、光谱滤光阵列和微纳偏振阵列探测器参数的精准匹配和高效利用；基于常规导引头和工业偏振探测器，设计了包含球形整流罩的多维度成像制导光学系统；系统采用4×4光场分割布局，在可见光波段内形成16个光谱通道，光谱分辨率16 nm，实现单光路、单探测器条件下0°、45°、90°、135°等四个偏振方向的偏振光谱图像数据立方体同时高效获取；系统整体焦距150 mm，筒长145 mm。仿真结果表明，系统16个通道下全视场调制传递函数在奈奎斯特频率处均接近衍射极限，成像质量良好，满足弹载目标多维度探测与识别需求。
- 成像系统 /
- 微透镜阵列 /
- 偏振光谱成像 /
- 孔径分割
Abstract:
To address the bottleneck that makes the conventional polarization spectral imaging method difficult to apply to the ballistic platform, a fast multi-dimensional imaging guidance optical scheme based on array optics is proposed. The correlation model between channel resolution and telescopic magnification is constructed. The precise matching and efficient utilization of the parameters of the microlens array, spectral filter array, and micro-nano-polarization array detector are realized. Based on the conventional guidance head and commercial polarization detector, a multi-dimensional imaging guidance optical system including spherical is designed. The system adopts a 4×4 optical field segmentation layout, forming 16 spectral channels through the visible light band with a spectral resolution of 16 nm. A polarization spectral data cube in four polarization directions, such as 0°, 45°, 90°, and 135° is acquired efficiently under the conditions of a single optical path and a single detector. The system has an effective focal length of 150 mm and a structure length of 145 mm. Simulation results show that the full-field modulation transfer function of the system is close to the diffraction limit at the Nyquist frequency for 16 channels. The imaging quality meets the requirements of bullet-loaded target multi-dimensional detection and identification.
- subpixel imaging system /
- microlens array /
- polarization spectrum imaging /
- division of aperture

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图 1 系统组成示意图

Figure 1. System composition diagram

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图 2 光学系统符号示意图

Figure 2. Symbolic diagram of the optical system

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图 3 不同空间分辨率下微透镜阵列子单元通光孔径与望远单元放大倍率关系曲线

Figure 3. The relationship between the aperture of the sub-unit of the microlens array and the telescope unit magnification at different spatial resolutions

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图 4 光谱滤光阵列透过率曲线

Figure 4. Schematic diagram of spectral filter array channel

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图 5 探测器区域划分示意图

Figure 5. Schematic diagram of detector area division

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图 6 微透镜阵列像方远心光路原理图

Figure 6. Schematic diagram of microlens array image square telecentric optical circuit

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图 7 光学系统设计结果三维图

Figure 7. Three-dimensional diagram of optical system design results

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图 8 光学系统16个光谱通道的MTF

Figure 8. MTF of 16 spectral channels of the optical system

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图 9 光学系统16个光谱通道归一化视场下的畸变图

Figure 9. Distortion map of 16 spectral channels in the normalized field of view of the optical system

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图 10 光学系统16个光谱通道能量集中度曲线

Figure 10. The energy concentration curve of 16 spectral channels of the optical system

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表 1 光学系统技术指标

Table 1. Technical index of the optical system

参数	数值
有效焦距/mm	150
入瞳孔径/mm	17.25
空间分辨率/m	0.25@10 km
视场/mrad	5.34×5.34
工作波长/nm	450-706
光谱分辨率/nm	16
探测器靶面	4096×3000
像元尺寸/μm	3.45

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表 2 光学系统公差设置

Table 2. Optical system tolerance settings

分析对象	公差类型	数值
望远单元		主镜	次镜
	X、Y方向偏心/mm	±0.08	±0.08
	Z方向厚度/mm	±0.025	±0.025
	X、Y方向倾斜/(°)	±0.1	±0.1
	二次曲率系数	±0.001	±0.001
	曲率半径/mm	±0.001	±0.001
微透镜阵列	位置精度偏心/mm	±0.005
	厚度/mm	±0.025
	单元透镜倾斜/(′)	±0.3
	不规则度	±0.2
	曲率半径/mm	±0.01
光谱滤光阵列	位置精度偏心/mm	±0.005
	光谱通道倾斜/(′)	±0.3
	不规则度	±0.2
	厚度/mm	±0.01
常规透镜	折射率	±0.0008
	光圈数	±2
	厚度/mm	±0.025
	不规则度	±0.25
	阿贝数/%	0.08
	元件倾斜/(′)	±0.8
	表面倾斜/(′)	±0.8
	元件偏心/mm	±0.008
	表面偏心/mm	±0.008

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表 3 蒙特卡罗公差分析结果

Table 3. Monte Carlo tolerance analysis results

通道	RMS光斑半径/μm	通道	RMS光斑半径/μm
通道	90%	通道	90%
通道1	5.936	通道9	4.737
通道2	4.927	通道10	2.899
通道3	4.786	通道11	2.994
通道4	5.723	通道12	4.938
通道5	4.880	通道13	5.885
通道6	3.087	通道 14	5.047
通道7	3.007	通道15	5.296
通道8	4.895	通道16	5.821

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