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    Journals >Acta Photonica Sinica >Volume 49 >Issue 3 >Page 0322002 > Article
    • Acta Photonica Sinica
    • Vol. 49, Issue 3, 0322002 (2020)
    Design of Co-aperture Wide Spectrum Compound Eye Optical System
    Yang CHEN1, Ming GAO1,*, Xue-lei HU1, Xi-bin ZHANG2, and Yang JIAO3
    Author Affiliations
  • 1Institute of Optoelectronic Engineering, Xi'an Technological University, Xi'an 710021, China
  • 2Xi'an Institute of Optics and Precision Mechanics of CAS, Xi'an 710119, China
  • 3Northwest Institute of Mechanical & Electrical Engineering, Xianyang, Shaanxi 712099, China
    • show less
    DOI: 10.3788/gzxb20204903.0322002 Cite this Article
    Yang CHEN, Ming GAO, Xue-lei HU, Xi-bin ZHANG, Yang JIAO. Design of Co-aperture Wide Spectrum Compound Eye Optical System[J]. Acta Photonica Sinica, 2020, 49(3): 0322002 Copy Citation Text show less
    The difference in image plane position of the sub-eye optical system
    Fig. 1. The difference in image plane position of the sub-eye optical system
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    Matching the sub-eye and receiving optical system
    Fig. 2. Matching the sub-eye and receiving optical system
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    Sub-eye structure diagram
    Fig. 3. Sub-eye structure diagram
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    Sub-eye lens transfer function
    Fig. 4. Sub-eye lens transfer function
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    Sub-lens spot diagram
    Fig. 5. Sub-lens spot diagram
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    Receiving system structure
    Fig. 6. Receiving system structure
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    Receive system transfer function
    Fig. 7. Receive system transfer function
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    Receiving system spot diagram
    Fig. 8. Receiving system spot diagram
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    Compound eye system diagram
    Fig. 9. Compound eye system diagram
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    Visible light transfer function of the sub-eye lens
    Fig. 10. Visible light transfer function of the sub-eye lens
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    Long-wave infrared transfer function of the sub-eye lens
    Fig. 11. Long-wave infrared transfer function of the sub-eye lens
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    Visible light transfer function of receiver system
    Fig. 12. Visible light transfer function of receiver system
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    Infrared transfer function of the receiving system
    Fig. 13. Infrared transfer function of the receiving system
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    Diffraction surface turning simulation
    Fig. 14. Diffraction surface turning simulation
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    VisibleLWIR
    Wave0.38~0.76 μm8~12 μm
    Focal length5 mm
    F/#3
    Field of view10°
    Δl′/mm0
    Table 1. The parameters of the sub-eye lens
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    R/mmd/mmGnλ1nλ2ΔnlmΔl1
    2.3090.871BAF21.4741.4230.0512.838-0.345
    -3.5180.200
    -2.4350.600PBF21.7661.6680.102-2.1840.290
    3.7210.985
    3.2750.760CSBR1.6971.6640.0332.886-0.140
    -5.487
    Table 2. Sub-eye lens initial structure parameter
    View in the Article
    Surf: typeRadius/mmThickness/mmGlass
    Standard1.730.70BAF2
    Standard-11.490.20
    Standard-13.090.50PBF2
    Binary 215.280.10
    Standard1.240.60CSBR
    Standard0.802.9218
    Table 3. Dual-band sub-eye system parameters
    View in the Article
    Surf: typeSurfaceNorm radius2nd coefficient4th coefficient8th coefficient
    Binary 241-14.386 3-2.623 82.040 3
    Table 4. Diffractive surface coefficient of sub-eye
    View in the Article
    VisibleLWIR
    Wave0.38~0.76 μm8~12 μm
    Focal length4 mm
    Field of view80°
    F/#3
    Pixel1 024×768256×256
    Pixel size3.5 μm×3.5 μm25 μm×25 μm
    Table 5. Receiving system technical parameters
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    Surf:typeRadius/mmThickness/mmGlass
    Co-pathlensStandard26.405.00CAF2
    Standard6.885.00
    Standard-22.836.00ZNS_BROAD
    Standard-23.822.00
    Standard-22.964.50ZNS_BROAD
    Binary 2-41.183.90
    Infinity4.50ZNS_BROAD
    Infinity4.50
    Visible lensInfinity2.29
    Standard8.832.09BEO
    Standard-14.079.11
    LWIR lensInfinity2.00
    Binary 2-40.604.40GERMANIUM
    Standard50.899.24
    Table 6. Dual-band compound eye receiving system parameter
    View in the Article
    Surf: typeSurfaceNorm radius2nd coefficient4th coefficient8th coefficient
    Binary 26 92.5332.02-19.00-9.810.232.980.42
    Table 7. Diffractive surface coefficient of receive system
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    Yang CHEN, Ming GAO, Xue-lei HU, Xi-bin ZHANG, Yang JIAO. Design of Co-aperture Wide Spectrum Compound Eye Optical System[J]. Acta Photonica Sinica, 2020, 49(3): 0322002
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