Digital in-line holography for large-volume analysis of vertical motion of micro-scale marine plankton and other particles
Digital in-line holography for large-volume analysis of vertical motion of micro-scale marine plankton and other particles
Measuring the distribution, characteristics and dynamics of marine microscale plankton and other particulate matter is essential to understand the vertical flux of elements in the marine environment. Digital holographic microscopy is a powerful approach for measuring these and studying their 3-D trajectories in a relatively large observation volume. This article demonstrates a compact, in-line digital holographic microscope that allows large-volume and high-resolution recording of marine particles through combining a continuous wave laser and a short exposure CMOS camera with efficient global shutters. A resolution of better than 10 μm is demonstrated in air and the minimum distinguishable size of targets recorded in water is approximately 20 μm. The maximum volumetric throughput of the setup is 1904 mL/s. The microscope can take motion blur free holograms of particles moving at up to 490 mm/s in theory, and has been tested in the ∼200-mm/s flowing water. The orientation of the measured volume improves the ability of digital holography in profiling sinking rates and active vertical migration. The system was tested onboard a research vessel to record a range of live plankton and other particles. The motion of some samples, including the sinking motion and swimming motion, was analyzed using custom developed image processing software. The experimental results show that the combination of high resolution and a large volume over which motion of sparse-distribution particles can be tracked, can improve the ability to differentiate between different types of marine particle and identify behaviors of live plankton.
Digital in-line holographic microscopy, holo graphic image processing, large-volume recording, marine plank- ton and particle motion tracking, vertical profiling of particulates
1248-1260
Liu, Zonghua
76b789cb-cddf-49c2-89dd-ca8a56997486
Takahashi, Tomoko
937057f6-8e83-4a7f-b11f-b549c94afdf6
Lindsay, Dhugal
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Thevar, Thangavel
06bf7cc7-cf72-422e-a77b-9d1f55a2b3b1
Sangekar, Mehul
196e042f-c144-4310-aab1-1b8e963ac417
Watanabe, Hiromi Kayama
60f558d9-2bdf-4f8d-87b2-10792bba5d71
Burns, Nicholas
ec00597b-5a8b-4af1-8a42-252be6c61438
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
937057f6-8e83-4a7f-b11f-b549c94afdf6
Lindsay, Dhugal
95b74b27-090f-4b4c-9b2d-892dbc8e6f54
Thevar, Thangavel
06bf7cc7-cf72-422e-a77b-9d1f55a2b3b1
Sangekar, Mehul
196e042f-c144-4310-aab1-1b8e963ac417
Watanabe, Hiromi Kayama
60f558d9-2bdf-4f8d-87b2-10792bba5d71
Burns, Nicholas
ec00597b-5a8b-4af1-8a42-252be6c61438
Watson, John
5b87c996-09db-49f2-b114-404dcc418915
Thornton, Blair
8293beb5-c083-47e3-b5f0-d9c3cee14be9
Liu, Zonghua, Takahashi, Tomoko, Lindsay, Dhugal, Thevar, Thangavel, Sangekar, Mehul, Watanabe, Hiromi Kayama, Burns, Nicholas, Watson, John and Thornton, Blair
(2021)
Digital in-line holography for large-volume analysis of vertical motion of micro-scale marine plankton and other particles.
IEEE Journal of Oceanic Engineering, 46 (4), .
(doi:10.1109/JOE.2021.3066788).
Abstract
Measuring the distribution, characteristics and dynamics of marine microscale plankton and other particulate matter is essential to understand the vertical flux of elements in the marine environment. Digital holographic microscopy is a powerful approach for measuring these and studying their 3-D trajectories in a relatively large observation volume. This article demonstrates a compact, in-line digital holographic microscope that allows large-volume and high-resolution recording of marine particles through combining a continuous wave laser and a short exposure CMOS camera with efficient global shutters. A resolution of better than 10 μm is demonstrated in air and the minimum distinguishable size of targets recorded in water is approximately 20 μm. The maximum volumetric throughput of the setup is 1904 mL/s. The microscope can take motion blur free holograms of particles moving at up to 490 mm/s in theory, and has been tested in the ∼200-mm/s flowing water. The orientation of the measured volume improves the ability of digital holography in profiling sinking rates and active vertical migration. The system was tested onboard a research vessel to record a range of live plankton and other particles. The motion of some samples, including the sinking motion and swimming motion, was analyzed using custom developed image processing software. The experimental results show that the combination of high resolution and a large volume over which motion of sparse-distribution particles can be tracked, can improve the ability to differentiate between different types of marine particle and identify behaviors of live plankton.
Text
Liu_2021_JOE
- Accepted Manuscript
More information
Accepted/In Press date: 23 February 2021
e-pub ahead of print date: 22 June 2021
Published date: 1 October 2021
Additional Information:
Funding Information:
Thisworkwas supported by a joint U.K.-Japan research program (NERC-JST SICORP Marine Sensor Proof of Concept under Project Code NE/R01227X/1).
Keywords:
Digital in-line holographic microscopy, holo graphic image processing, large-volume recording, marine plank- ton and particle motion tracking, vertical profiling of particulates
Identifiers
Local EPrints ID: 484678
URI: http://eprints.soton.ac.uk/id/eprint/484678
ISSN: 0364-9059
PURE UUID: d13824d7-f5f2-4a6e-be63-3f8cc68ae1d7
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Date deposited: 20 Nov 2023 17:41
Last modified: 17 Mar 2024 12:44
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Contributors
Author:
Zonghua Liu
Author:
Tomoko Takahashi
Author:
Dhugal Lindsay
Author:
Thangavel Thevar
Author:
Mehul Sangekar
Author:
Hiromi Kayama Watanabe
Author:
Nicholas Burns
Author:
John Watson
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