Aberration compensation of holographic particle images using digital holographic microscopy
Characterisation of small and large-scale vortices in turbulent flows demands a system with high spatial resolution. The measurement of high spatial resolution, three-dimensional vector displacements in fluid mechanics using holography, is usually hampered by aberration. Aberration poses some prob...
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my.unimas.ir.177692017-09-25T04:10:29Z http://ir.unimas.my/id/eprint/17769/ Aberration compensation of holographic particle images using digital holographic microscopy Tamrin, K. F. Rahmatullah, B. Samuri, S. M. TJ Mechanical engineering and machinery Characterisation of small and large-scale vortices in turbulent flows demands a system with high spatial resolution. The measurement of high spatial resolution, three-dimensional vector displacements in fluid mechanics using holography, is usually hampered by aberration. Aberration poses some problems in particle image identification due to low fidelity of real image reconstruction. Phase mismatch between the recording and the reconstruction waves was identified as the main source of aberration in this study. This paper demonstrates how aberration compensation can be achieved by cross-correlating the complex amplitude of an aberrated reconstructed object with the phase conjugate of a known reference object in the plane of the hologram (frequency space). Results favourably show significant increase in Strehl ratio and suppression of background noise that are more pronounced for particle images of 10 and 5 microns. It is clear from the work conducted that wavefront aberration measurement and compensation of holographic microscopic objects are now possible with the use of a variant digital holographic microscope Taylor & Francis Ltd 2015 E-Article PeerReviewed text en http://ir.unimas.my/id/eprint/17769/1/Aberration%20compensation%20of%20holographic%20particle%20%28abstract%29.pdf Tamrin, K. F. and Rahmatullah, B. and Samuri, S. M. (2015) Aberration compensation of holographic particle images using digital holographic microscopy. Journal of Modern Optics. ISSN 0950-0340 https://www.researchgate.net/publication/273338756 doi : 10.1080/09500340.2014.1003257 |
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TJ Mechanical engineering and machinery Tamrin, K. F. Rahmatullah, B. Samuri, S. M. Aberration compensation of holographic particle images using digital holographic microscopy |
description |
Characterisation of small and large-scale vortices in turbulent flows demands a system with high spatial resolution. The
measurement of high spatial resolution, three-dimensional vector displacements in fluid mechanics using holography, is
usually hampered by aberration. Aberration poses some problems in particle image identification due to low fidelity of
real image reconstruction. Phase mismatch between the recording and the reconstruction waves was identified as the
main source of aberration in this study. This paper demonstrates how aberration compensation can be achieved by
cross-correlating the complex amplitude of an aberrated reconstructed object with the phase conjugate of a known
reference object in the plane of the hologram (frequency space). Results favourably show significant increase in Strehl
ratio and suppression of background noise that are more pronounced for particle images of 10 and 5 microns. It is clear
from the work conducted that wavefront aberration measurement and compensation of holographic microscopic objects
are now possible with the use of a variant digital holographic microscope |
format |
E-Article |
author |
Tamrin, K. F. Rahmatullah, B. Samuri, S. M. |
author_facet |
Tamrin, K. F. Rahmatullah, B. Samuri, S. M. |
author_sort |
Tamrin, K. F. |
title |
Aberration compensation of holographic particle images using digital holographic microscopy |
title_short |
Aberration compensation of holographic particle images using digital holographic microscopy |
title_full |
Aberration compensation of holographic particle images using digital holographic microscopy |
title_fullStr |
Aberration compensation of holographic particle images using digital holographic microscopy |
title_full_unstemmed |
Aberration compensation of holographic particle images using digital holographic microscopy |
title_sort |
aberration compensation of holographic particle images using digital holographic microscopy |
publisher |
Taylor & Francis Ltd |
publishDate |
2015 |
url |
http://ir.unimas.my/id/eprint/17769/1/Aberration%20compensation%20of%20holographic%20particle%20%28abstract%29.pdf http://ir.unimas.my/id/eprint/17769/ https://www.researchgate.net/publication/273338756 |
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