Unsupervised feature learning and clustering of particles imaged in raw holograms using an autoencoder
Unsupervised feature learning and clustering of particles imaged in raw holograms using an autoencoder
Digital holography is a useful tool to image microscopic particles. Reconstructed holograms give high-resolution shape information that can be used to identify the types of particles. However, the process of reconstructing holograms is computationally intensive and cannot easily keep up with the rate of data acquisition on low-power sensor platforms. In this work, we explore the possibility of performing object clustering on holograms that have not been reconstructed, i.e., images of raw interference patterns, using the latent representations of a deep-learning autoencoder and a self-organizing mapping network in a fully unsupervised manner. We demonstrate this concept on synthetically generated holograms of different shapes, where clustering of raw holograms achieves an accuracy of 94.4%. This is comparable to the 97.4% accuracy achieved using the reconstructed holograms of the same targets. Directly clustering raw holograms takes less than 0.1 s per image using a low-power CPU board. This represents a three-order of magnitude reduction in processing time compared to clustering of reconstructed holograms and makes it possible to interpret targets in real time on low-power sensor platforms. Experiments on real holograms demonstrate significant gains in clustering accuracy through the use of synthetic holograms to train models. Clustering accuracy increased from 47.1% when the models were trained only on the real raw holograms, to 64.1% when the models were entirely trained on the synthetic raw holograms, and further increased to 75.9% when models were trained on the both synthetic and real datasets using transfer learning. These results are broadly comparable to those achieved when reconstructed holograms are used, where the highest accuracy of 70% achieved when clustering raw holograms outperforms the highest accuracy achieved when clustering reconstructed holograms by a significant margin for our datasets.
1570-1580
Liu, Zonghua
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Takahashi, Tomoko
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Lindsay, Dhugal
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Sangekar, Mehul
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Burns, Nicholas
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Thevar, Thangavel
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Yamada, Takaki
81c66c35-0e2b-4342-80fa-cbee6ff9ce5f
Watson, John
5b87c996-09db-49f2-b114-404dcc418915
Thornton, Blair
8293beb5-c083-47e3-b5f0-d9c3cee14be9
1 October 2021
Liu, Zonghua
76b789cb-cddf-49c2-89dd-ca8a56997486
Takahashi, Tomoko
3f3f98c5-993c-4e11-b5ec-0fa4dbdbced9
Lindsay, Dhugal
95b74b27-090f-4b4c-9b2d-892dbc8e6f54
Sangekar, Mehul
196e042f-c144-4310-aab1-1b8e963ac417
Burns, Nicholas
ec00597b-5a8b-4af1-8a42-252be6c61438
Thevar, Thangavel
06bf7cc7-cf72-422e-a77b-9d1f55a2b3b1
Yamada, Takaki
81c66c35-0e2b-4342-80fa-cbee6ff9ce5f
Watson, John
5b87c996-09db-49f2-b114-404dcc418915
Thornton, Blair
8293beb5-c083-47e3-b5f0-d9c3cee14be9
Liu, Zonghua, Takahashi, Tomoko, Lindsay, Dhugal, Sangekar, Mehul, Burns, Nicholas, Thevar, Thangavel, Yamada, Takaki, Watson, John and Thornton, Blair
(2021)
Unsupervised feature learning and clustering of particles imaged in raw holograms using an autoencoder.
Journal of the Optical Society of America A: Optics and Image Science, and Vision, 38 (10), .
(doi:10.1364/JOSAA.424271).
Abstract
Digital holography is a useful tool to image microscopic particles. Reconstructed holograms give high-resolution shape information that can be used to identify the types of particles. However, the process of reconstructing holograms is computationally intensive and cannot easily keep up with the rate of data acquisition on low-power sensor platforms. In this work, we explore the possibility of performing object clustering on holograms that have not been reconstructed, i.e., images of raw interference patterns, using the latent representations of a deep-learning autoencoder and a self-organizing mapping network in a fully unsupervised manner. We demonstrate this concept on synthetically generated holograms of different shapes, where clustering of raw holograms achieves an accuracy of 94.4%. This is comparable to the 97.4% accuracy achieved using the reconstructed holograms of the same targets. Directly clustering raw holograms takes less than 0.1 s per image using a low-power CPU board. This represents a three-order of magnitude reduction in processing time compared to clustering of reconstructed holograms and makes it possible to interpret targets in real time on low-power sensor platforms. Experiments on real holograms demonstrate significant gains in clustering accuracy through the use of synthetic holograms to train models. Clustering accuracy increased from 47.1% when the models were trained only on the real raw holograms, to 64.1% when the models were entirely trained on the synthetic raw holograms, and further increased to 75.9% when models were trained on the both synthetic and real datasets using transfer learning. These results are broadly comparable to those achieved when reconstructed holograms are used, where the highest accuracy of 70% achieved when clustering raw holograms outperforms the highest accuracy achieved when clustering reconstructed holograms by a significant margin for our datasets.
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Published date: 1 October 2021
Additional Information:
Funding Information:
Natural Environment Research Council; Japan Science and Technology Agency (NE/R01227X/1).
Funding Information:
Acknowledgment. This work is funded by a joint UK-Japan research program (NERC-JST SICORP Marine Sensor Proof of Concept under project code NE/R01227X/1).
Publisher Copyright:
© 2021 Optica Publishing Group.
Identifiers
Local EPrints ID: 451739
URI: http://eprints.soton.ac.uk/id/eprint/451739
ISSN: 1084-7529
PURE UUID: 35453c75-ea72-4e8b-9c42-aceca669ed93
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Date deposited: 25 Oct 2021 16:30
Last modified: 17 Mar 2024 06:49
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Contributors
Author:
Zonghua Liu
Author:
Tomoko Takahashi
Author:
Dhugal Lindsay
Author:
Mehul Sangekar
Author:
Nicholas Burns
Author:
Thangavel Thevar
Author:
Takaki Yamada
Author:
John Watson
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