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六边形环带排布的共光路复眼光学系统设计

范晨,刘钧,高明,吕宏

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范晨, 刘钧, 高明, 吕宏. 六边形环带排布的共光路复眼光学系统设计[J]. , 2023, 16(1): 158-173. doi: 10.37188/CO.2022-0116
引用本文: 范晨, 刘钧, 高明, 吕宏. 六边形环带排布的共光路复眼光学系统设计[J]. , 2023, 16(1): 158-173.doi:10.37188/CO.2022-0116
FAN Chen, LIU Jun, GAO Ming, LV Hong. Design of compound eye optical system with hexagonal band arrangement and common optical path[J]. Chinese Optics, 2023, 16(1): 158-173. doi: 10.37188/CO.2022-0116
Citation: FAN Chen, LIU Jun, GAO Ming, LV Hong. Design of compound eye optical system with hexagonal band arrangement and common optical path[J].Chinese Optics, 2023, 16(1): 158-173.doi:10.37188/CO.2022-0116

六边形环带排布的共光路复眼光学系统设计

doi:10.37188/CO.2022-0116
基金项目:陕西省自然科学基础研究计划项目(No. 2019JM-470); 陕西省教育厅科研计划项目(No. 18JS048)
详细信息
    作者简介:

    范 晨(1996—),男,陕西西安人,硕士研究生,2020年于西安工业大学光电工程学院获得学士学位,主要研究方向为光学系统设计理论与应用。E-mail:272497924@qq.com

    刘 钧(1964—),女,辽宁葫芦岛人,教授,硕士研究生导师,2005年于南京理工大学获得硕士学位。研究方向包括:光学设计,光电仪器设计,光电检测技术等。E-mail:junliu1990@163.com

    高 明(1964—),男,吉林长春人,教授,博士研究生导师,院长。现任中国兵工学会光电子技术专业委员会委员、中国光学学会会员、国家科学技术奖评审专家,2010年于西安电子科技大学获得博士学位。研究技术领域包括:光电测试与光学仪器、光学设计、精密仪器及机械, 大气传输理论及技术,光电对抗技术等。E-mail:minggao1964@163.com

    吕 宏(1975—),男,山西省河津人,副教授,硕士研究生导师,2012年于西安理工大学获得博士学位。研究方向包括: 大气传输特性、光场调控以及测控技术等。E-mail:lvhong@xatu.edu.cn

  • 中图分类号:O439

Design of compound eye optical system with hexagonal band arrangement and common optical path

Funds:Supported by Natural Science Basic Research Plan Project of Shaanxi Province (No. 2019JM-470); Scientific Research Plan Project of Shaanxi Provincial Education Department (No. 18JS048)
More Information
    Corresponding author:junliu1990@163.com
  • 摘要:

    为解决仿生复眼系统目前普遍存在的空间利用率较低、子眼孔径较小问题,本文提出一种六边形环带排布的大孔径复眼系统设计方法,通过引入填充因子理论,以传统曲面圆周式排布为对照组,论证了六边形环带排布模型可有效提高大孔径复眼系统的空间利用率。针对单波段复眼系统获取目标信息量有限的问题,设计采用红外双波段共光路的成像结构形式,辅以红外双色探测器接收,增强了复眼系统获取目标信息的多维度能力,同时建立了六边形环带排布方式的子孔径定位数学模型。仿生复眼系统共由91个子孔径组成,子孔径入瞳为16 mm,焦距为48 mm,视场角为9°,子孔径合成总视场为96°×85°,中继转像系统焦距为6.14 mm,子眼系统和中继转像系统在−40 °C~+60 °C温度变化范围内无热差影响,探测器冷反射效应可忽略。对复眼系统进行组合,仿真结果表明:各个光学子通道均方根(RMS)半径均小于艾里斑,光学畸变值均小于0.1%,边缘子通道红外中波/长波波段调制传递函数(MTF)在17 lp/mm处均达到0.5以上。该系统结构紧凑、探测能力强,可用于复杂环境中多目标的探测与识别。

  • 图 1六边形环带排布模型图

    Figure 1.Hexagonal band arrangement model diagram

    图 2主阵列子孔径投影示意图

    Figure 2.Schematic diagram of main array direction sub aperture projection

    图 3两种排布模型子孔径投影对比图

    Figure 3.Sub aperture projection contrast of two arrangement models

    图 4某主阵列子孔径排布剖面图

    Figure 4.A sub aperture layout section view of a main array

    图 5复眼 $ OXYZ $ 坐标系模型图

    Figure 5.Compound eye coordinate system model diagram

    图 6子孔径平面角示意图

    Figure 6.Schematic diagram of sub aperture plane angle

    图 7子孔径光路结构示意图

    Figure 7.Schematic diagram of sub aperture optical path structure

    图 8子孔径系统光学传递函数曲线图

    Figure 8.MTF of sub aperture system

    图 9子孔径系统的RMS波前视场图

    Figure 9.RMS wavefront view of a sub aperture system

    图 10主阵列平面方向排布子孔径二维模型图

    Figure 10.2D model diagram of sub-apertures arranged in the plane direction of the main array

    图 114层子孔径阵列三维模型图

    Figure 11.3D model of 4-layer sub-aperture array

    图 12中继转像系统光路图

    Figure 12.Relay system optical path diagram

    图 13中继转像系统光学传递函数曲线图

    Figure 13.MTF of relay system

    图 14中继转像系统的RMS波前视场图

    Figure 14.RMS wavefront view of a relay system

    图 15子孔径系统不同波段高低温下的MTF曲线

    Figure 15.MTF of sub aperture system at different bands at high and low temperatures

    图 16中继转像系统不同波段高低温下的MTF曲线

    Figure 16.MTF of relay system at different bands at high and low temperatures

    图 17中继系统部分表面反射光线反向追迹图

    Figure 17.Reverse tracing diagram of reflected light on part surface of relay system

    图 18中继系统各光学表面NITD贡献值

    Figure 18.NITD contributions of optical surfaces of relay system

    图 19复眼光学系统主阵列方向成像光路图

    Figure 19.Imaging optical path diagram of the main array direction of the compound eye optical system

    图 20复眼光学系统整体成像光路图

    Figure 20.Overall imaging optical path diagram of compound eye optical system

    图 21中心成像子通道的MTF曲线和点列图

    Figure 21.MTF and spot diagram of central imaging sub channel

    图 22边缘成像子通道的MTF曲线和点列图

    Figure 22.MTF and spot diagram of margin imaging sub channel

    图 23复眼系统边缘子通道的场曲和畸变图

    Figure 23.Field curve and distortion plot of the margin sub channel of the compound eye system

    图 24复眼组合系统中心和边缘子通道RMS视场波前图

    Figure 24.RMS field of view wavefront diagram of center and edge sub-channels of compound eye combined system

    图 25复眼系统300组MC公差分析结果

    Figure 25.Results of 300 Monte Carlo tolerance analysis for compound eye system

    表 1相邻子孔径重叠角与子孔径视场角关系

    Table 1.Relationship between overlapping angle of adjacent sub aperture and FOV of sub aperture

    Angle relationship Conclusion
    β=0° The edge rays of adjacent sub-apertures are parallel, and there is a blind spot in the field of view at the object plane at finite distance
    0°<β<ω Adjacent sub-aperture edge rays intersect
    β=ω Sub-aperture edge rays are parallel to adjacent sub-aperture optical axes
    β>ω Alternate sub-aperture edge rays overlap far away, and the intermediate sub-aperture field of view is meaningless
    下载: 导出CSV

    表 2仿生复眼光学系统基本参数

    Table 2.Basic parameters of bionic compound eye optical system

    Type The parameter value
    Main array direction FOV 2θ/(°) 96
    sub-aperture FOV 2ω/(°) 9.0
    The angle between the optical axes of
    adjacent sub-apertures Δφ/(°)
    8.7
    Base radiusR/mm 111
    Number of sub-aperturesn 91
    Number of sub-aperture array layersS 6
    下载: 导出CSV

    表 3六边形环带复眼系统总体设计指标

    Table 3.Overall design index of compound eye system with hexagonal ring band

    Type The parameter value
    Detection distance/km 1
    Target size/m 2
    System diameter/mm <200
    Wavelength/μm MWIR: 3.7~4.8
    LWIR: 7.7~9.5
    下载: 导出CSV

    表 4红外双色探测器主要参数

    Table 4.Main parameters of infrared two-color detector

    Type The parameter value
    Resolution 320×256
    cell size/μm 30×30
    target size/mm 12.29
    下载: 导出CSV

    表 5子孔径光学系统设计参数

    Table 5.Sub-aperture optical system design parameters

    MWIR LWIR
    Wavelength/μm 3.7~4.8 7.7~9.5
    Focal length/mm 48 48
    F# 3 3
    Field of view/(°) 9 9
    下载: 导出CSV

    表 6中继转像系统光学设计参数

    Table 6.Optical system design parameters of relay system

    MWIR LWIR
    Wavelength/μm 3.7~4.8 7.7~9.5
    Focal length/mm 6 6
    Detector size/mm 12.29 12.29
    Field of view/(°) $ \geqslant $92 $ \geqslant $92
    下载: 导出CSV

    表 7子孔径系统不同波段温度下的焦距值

    Table 7.Focal length values of sub aperture systems at different band temperatures

    Temperature/°C MWIR/mm LWIR/mm
    −40 47.9395 48.0351
    +20 47.9392 48.0347
    +60 47.9391 48.0346
    下载: 导出CSV

    表 8中继转像系统不同波段温度下的焦距值

    Table 8.Focal length values of relay systems at different band temperatures

    Temperature/°C MWIR/mm LWIR/mm
    −40 6.1532 6.1422
    +20 6.1426 6.1320
    +60 6.1351 6.1252
    下载: 导出CSV

    表 9中继转像系统所有表面YNI和I/IBAR数值

    Table 9.YNI and I/IBAR values on all surfaces of relay system

    Surface YNI I/IBAR Surface YNI I/IBAR
    1 1.227 3.165 9 1.265 0.525
    2 1.425 0.810 10 1.389 0.527
    3 1.441 0.814 11 −1.174 3.822
    4 3.089 1.465 12 −0.973 16.673
    5 −2.574 4.499 13 −1.231 0.089
    6 −2.205 4.156 14 −0.166 0.243
    7 0.267 0.137 15 −0.360 1.058
    8 0.168 0.073 16 −0.282 0.414
    下载: 导出CSV

    表 10复眼系统公差分配表

    Table 10.Tolerance assignment table for compound eye system

    Parameters Specification
    Radius/fringes ±2
    Thickness/mm ±0.02
    SurfaceXYdecenter/mm ±0.01
    SurfaceXYtilt/(°) ±0.02
    ElementXYdecenter/mm ±0.01
    ElementXYtilt/(°) ±0.02
    Abbe number 0.5%
    Index 0.001
    Zernike irregularity/fringes 0.1
    下载: 导出CSV
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  • 收稿日期:2022-06-09
  • 修回日期:2022-06-27
  • 网络出版日期:2022-09-16

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