Three-Dimensional Phase-Only Holographic Display Based on Deep Learning and Angular-Spectrum Layer-Oriented

Xiao Sun; Chao Han

doi:10.3788/LOP202259.0409001

Laser & Optoelectronics Progress, Volume. 59, Issue 4, 0409001(2022)

Three-Dimensional Phase-Only Holographic Display Based on Deep Learning and Angular-Spectrum Layer-Oriented

Xiao Sun and Chao Han^*

Key Laboratory of Advanced Perception and Intelligent Control of High-end Equipment, Ministry of Education, Anhui Polytechnic University, Wuhu , Anhui 241000, China

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Figures & Tables(11)

Fig. 1. Schematic diagram of improved algorithm

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Fig. 2. LeNet model structure

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Fig. 3. Contrast simulation of two-dimensional Lena image. (a) Original image; (b) hologram obtained of the proposed algorithm; (c) hologram obtained by the algorithm in Ref.[22]; (d) reconstructed image of the proposed algorithm; (e) reconstructed image using the algorithm in Ref.[22]

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Fig. 4. Small train model of modeling. (a) Depth map; (b) shading map

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Fig. 5. Output image. (a) Phase-only hologram of three-dimensional small train; (b) reconstruction image of three-dimensional small train image

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Fig. 6. Contrast simulation images. (a) Reconstructed image of proposed algorithm at $d_{1} = 210$ mm ; (b) reconstructed image at $d_{1} = 210$ mm using the algorithm in Ref.[22]; (c) reconstructed image of proposed algorithm at $d_{2} = 220$ mm; (d) reconstructed image at $d_{2} = 220$ mm using algorithm in Ref.[22]; (e) reconstructed image of proposed algorithm at $d_{3} = 230$ mm; (f) reconstructed image at $d_{3} = 230$ mm using the algorithm in Ref.[22]

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Fig. 7. Experimental light path diagram

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Fig. 8. Experiment reconstruction images. (a) Reconstructed image of the proposed algorithm at $d_{1} = 210$ mm; (b) reconstructed image at $d_{1} = 210$ mm using the algorithm inRef.[22]; (c) reconstructed image at $d_{1} = 210$ mm using the algorithm in Ref.[23]; (d) reconstructed image of the proposed algorithm at $d_{2} = 220$ mm; (e) reconstructed image at $d_{2} = 220$ mm using the algorithm in Ref.[22]; (f) reconstructed image at $d_{2} = 220$ mm using the algorithm in Ref.[23]; (g) reconstructed imageof the proposed algorithm at $d_{3} = 230$ mm; (h) reconstructed image at $d_{3} = 230$ mm using the algorithm in Ref.[22]; (i) reconstructed image at $d_{3} = 230$ mm using the algorithm in Ref.[23]

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Table 1. PSNR and SSIM of reconstructed image
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Table 1. PSNR and SSIM of reconstructed image
Parameter Fig. 3（d） Fig. 3（e）
$p_{P S N R}$ /dB 24.3100 15.5758
$s_{S S I M}$ 0.8032 0.5946

Table 2. SSIM of pure phase-only hologram
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Table 2. SSIM of pure phase-only hologram
Parameter Fig. 3（b） Fig. 3（c）
$s_{S S I M}$ 0.7825 0.4369

Table 3. Comparison of operation time of different size pictures
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Table 3. Comparison of operation time of different size pictures
Image size 512×512 1024×1024 2048×2048 4096×4096
Running time of algorithm in Ref. ［22］ /ms 3.4 7.9 19.3 45.9
Running time of improved algorithm /ms 4.1 8.9 20.2 49.4

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Xiao Sun, Chao Han. Three-Dimensional Phase-Only Holographic Display Based on Deep Learning and Angular-Spectrum Layer-Oriented[J]. Laser & Optoelectronics Progress, 2022, 59(4): 0409001

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