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    Journals >Acta Optica Sinica >Volume 43 >Issue 19 >Page 1905002 > Article
    • Acta Optica Sinica
    • Vol. 43, Issue 19, 1905002 (2023)
    Two-Dimensional Dispersion System Based on Planar Optical Waveguides
    Shengping Jia, Shun Lu, and Zhongwei Tan*
    Author Affiliations
  • Key Laboratory of All Optical Network and Advanced Telecommunication Network, Ministry of Education, Institute of Lightwave Technology, School of Electronic and Information Engineering, Beijing Jiaotong University, Beijing 100044, China
    • show less
    DOI: 10.3788/AOS230588 Cite this Article Set citation alerts
    Shengping Jia, Shun Lu, Zhongwei Tan. Two-Dimensional Dispersion System Based on Planar Optical Waveguides[J]. Acta Optica Sinica, 2023, 43(19): 1905002 Copy Citation Text show less
    Structure of proposed system
    Fig. 1. Structure of proposed system
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    Principle of operation of diffraction waveguides
    Fig. 2. Principle of operation of diffraction waveguides
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    Position of output light with different wavelengths at coupled-out volume grating
    Fig. 3. Position of output light with different wavelengths at coupled-out volume grating
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    Grating design principle. (a) Coupled-in volume grating structure; (b) coupled-out volume grating structure
    Fig. 4. Grating design principle. (a) Coupled-in volume grating structure; (b) coupled-out volume grating structure
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    Distribution of the spectra on the detector from different light sources. (a) Continuous light source; (b) discrete light source
    Fig. 5. Distribution of the spectra on the detector from different light sources. (a) Continuous light source; (b) discrete light source
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    Diffraction efficiency of composite grating
    Fig. 6. Diffraction efficiency of composite grating
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    Relationship between FSR and h
    Fig. 7. Relationship between FSR and h
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    Simulate structure of proposed system
    Fig. 8. Simulate structure of proposed system
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    Simulation results of discrete wavelength points in each band to be measured. (a) Blue band,h=0.5 mm; (b) blue band, h=1 mm; (c) blue band, h=3 mm; (d) green band, h=0.5 mm; (e) green band, h=1 mm; (f) green band, h=3 mm; (g) red band, h=0.5 mm; (h) red band, h=1 mm; (i) red band, h=3 mm
    Fig. 9. Simulation results of discrete wavelength points in each band to be measured. (a) Blue band,h=0.5 mm; (b) blue band, h=1 mm; (c) blue band, h=3 mm; (d) green band, h=0.5 mm; (e) green band, h=1 mm; (f) green band, h=3 mm; (g) red band, h=0.5 mm; (h) red band, h=1 mm; (i) red band, h=3 mm
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    Simulation results of discrete wavelength points in a wide band range. (a) h=0.5 mm, L2=8 mm; (b) h=0.5 mm, L2=16 mm; (c) h=0.5 mm, L2=25 mm; (d) h=1 mm, L2=8 mm; (e) h=1 mm, L2=16 mm; (f) h=1 mm, L2=25 mm; (g) h=3 mm, L2=8 mm; (h) h=3 mm, L2=16 mm; (i) h=3 mm, L2=25 mm
    Fig. 10. Simulation results of discrete wavelength points in a wide band range. (a) h=0.5 mm, L2=8 mm; (b) h=0.5 mm, L2=16 mm; (c) h=0.5 mm, L2=25 mm; (d) h=1 mm, L2=8 mm; (e) h=1 mm, L2=16 mm; (f) h=1 mm, L2=25 mm; (g) h=3 mm, L2=8 mm; (h) h=3 mm, L2=16 mm; (i) h=3 mm, L2=25 mm
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    ItemDescription
    Source400-500 nm,500-560 nm,620-780 nm,and visible band,random polarization
    Wave guideH-K9,l1=1 mm;l12=14 mm;l2=8,16,25 mm;h=0.5,1,3 mm
    Volume gratingCoupled-in grating:n=1.54;R:(0°,λR),S:(54°,λR
    Coupled-out grating:n=1.54;R:(54°,λR),S:(0°,λR),λR is the central wavelength of each band
    Orthogonal gratingno=1.54;same as the coupled-in grating;rotate the diffraction direction by 90°
    Column lensfx=0 mm, fy=10 mm
    CCD resolution600 pixel×600 pixel
    Table 1. Parameters in the simulated structure
    L2 /mmWavelength range /μm
    h=0.5 mmh=1 mmh=3 mm
    80.45-0.6763400.45-0.6745300.45-0.656100
    160.45-0.6766040.45-0.6755990.45-0.664900
    250.45-0.6767380.45-0.6761270.45-0.669730
    Table 2. Wavelength range for each parameter
    Abstract
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    References (17)
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    Shengping Jia, Shun Lu, Zhongwei Tan. Two-Dimensional Dispersion System Based on Planar Optical Waveguides[J]. Acta Optica Sinica, 2023, 43(19): 1905002
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