Hologram classification of occluded and deformable objects with speckle noise contamination by deep learning

H. H. S. Lam; P. W. M. Tsang; T.-C. Poon

doi:10.1364/JOSAA.444648

Journal of the Optical Society of America A
Vol. 39,
Issue 3,
pp. 411-417
(2022)
•https://doi.org/10.1364/JOSAA.444648

Hologram classification of occluded and deformable objects with speckle noise contamination by deep learning

H. H. S. Lam, P. W. M. Tsang, and T.-C. Poon

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H. H. S. Lam, P. W. M. Tsang, and T.-C. Poon, "Hologram classification of occluded and deformable objects with speckle noise contamination by deep learning," J. Opt. Soc. Am. A 39, 411-417 (2022)

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Abstract

Advancements in optical, computing, and electronic technologies have enabled holograms of physical three-dimensional (3D) objects to be captured. The hologram can be displayed with a spatial light modulator to reconstruct a visible image. Although holography is an ideal solution for recording 3D images, a hologram comprises high-frequency fringe patterns that are almost impossible to recognize with traditional computer vision methods. Recently, it has been shown that holograms can be classified with deep learning based on convolution neural networks. However, the method can only achieve a high success classification rate if the image represented in the hologram is without speckle noise and occlusion. Minor occlusion of the image generally leads to a substantial drop in the success rate. This paper proposes a method known as ensemble deep-learning invariant occluded hologram classification to overcome this problem. The proposed new method attains over 95% accuracy in the classification of holograms of partially occluded handwritten numbers contaminated with speckle noise. To achieve the performance, a new augmentation scheme and a new enhanced ensemble structure are necessary. The new augmentation process includes occluded objects and simulates the worst-case scenario of speckle noise.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Section	Number of Convolution Filters	Kernel Size of Filters	Stride Size of Filters	Pooling Size	Dropout Ratio
1	6	$3 \times 3$	$1 \times 1$	$2 \times 2$	0.15
2	12	$3 \times 3$	$2 \times 2$	$2 \times 2$	0.25
3	NA	NA	NA	NA	0.25

Variation	Range	Step Size
Scaling	[0.8,1.2]	0.1
Rotation	$\pm 30^{\circ}$	1 deg
Translation	$\pm 3$ pixels	1 pixel
Depth	$0.016 m \pm 0.0016 m$	0.0001

Wavelength of Light $λ$	540 nm
Pixel size $δ$	6.4 µm
Size of hologram	64 rows and 64 columns
Depth $z$	Longitudinal displacement of the corresponding image

Success Rate (%)	Success Rate of EDL-IHC	Success Rate of EDL-IOHC	Difference in Success Rates between EDL-IHC and EDL-IOHC
Test set	69.12%	95.80%	−26.68%
Full set (both out-of-training and in-training sets)	73.90%	98.11%	−24.21%

	EDL-IHC the Decision by “Maximum Or”	EDL-IOHC the Decision by “Concatenate Unit”
Neural network model’s memory usage size (32 bits floating point)	16,614	16,810
Time taken for training (seconds)	62.54 s	35.38 s
Time taken for prediction (seconds)	0.78 s	0.49 s

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Journal of the Optical Society of America A