Chee Oi Choo scite author profile

Chee Oi Choo

5Publications

72Citation Statements Received

26Citation Statements Given

How they've been cited

215

How they cite others

Affiliations

Ngee Ann Polytechnic

Publications

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Quasi-physical phase compensation in digital holographic microscopy

Choo

Singh

et al. 2009

J. Opt. Soc. Am. A

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In digital holographic microscopy, if an optical setup is well aligned, the phase curvature introduced by the microscope objective (MO) together with the illuminating wave to the object wave is a spherical phase curvature. It can be physically compensated by introducing the same spherical phase curvature in the reference beam. Digital holographic microscopy setups based on the Michelson interferometric configuration with MO and an adjustable lens are presented, which can well perform the quasi-physical phase compensation during the hologram recording. In the reflection mode, the adjustable lens serves as both the condensing lens and the compensation lens. When the spatial frequency spectra of the hologram become a point spectrum, one can see that the phase curvature introduced by imaging is quasi-physically compensated. A simple plane numerical reference wavefront used for the reconstruction can give the correct quantitative phase map of the test object. A theoretical analysis and experimental demonstration are given. The simplicity of the presented setup makes it easy to align it well at lower cost.

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Digital holographic microscopy with physical phase compensation

Choo³

et al. 2009

Opt. Lett.

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An optical configuration for digital holographic microscopy is presented. Digital off-axis holograms are recorded by using a single-cube beam splitter in a nonconventional configuration so as to both split and combine a diverging spherical wavefront emerging from a microscope objective. When a plane numerical reference wavefront is used for the reconstruction of the recorded digital hologram, the phase curvature introduced by the microscope objective together with the illuminating wave to the object wave can be physically compensated.

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Transmission digital holographic microscopy based on a beam-splitter cube interferometer

Bhattacharya

Choo

et al. 2009

Appl. Opt.

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A new optical configuration for digital holographic microscopy is presented. Digital off-axis holograms are recorded by use of a single cube beam splitter in a nonconventional configuration to both split and combine a diverging spherical wavefront as it emerges from a single point source. Both the amplitude and the phase can then be reconstructed, yielding intensity and phase images with improved resolution. The novelty of the proposed configuration is its simplicity, minimal number of optical elements, insensitivity to vibration, and its inherent capability to compensate for the phase curvature that results from the illuminating wavefront in the case of microscopic samples.

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Microlens characterization by digital holographic microscopy with physical spherical phase compensation

Choo

et al. 2010

Appl. Opt.

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Microlenses have been characterized by a digital holographic microscopy system, which is immune to the inherent wavefront aberration. The digital holographic microscopy system takes advantage of fiber optics and uses the light emitted directly from a single-mode fiber as the recording reference wave. By using such a reference beam, which is quasi-identical to the object beam, the inherent wavefront aberration of the digital holographic microscope is removed. The alignment of the optical setup can be optimized with the help of numerical reconstruction software to give the system phase with the off-axis tilt removed. There is one, and only one, reference fiber point position to give a reference wavefront that is quasi-identical to the object wavefront where the system is free of wavefront aberration and directly gives the quantitative phase of the test object without the need for complicated numerical compensation.

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Physical spherical phase compensation in reflection digital holographic microscopy

Qu¹,

Choo²,

Rongwei³

et al. 2012

Optics and Lasers in Engineering

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Chee Oi Choo

Quasi-physical phase compensation in digital holographic microscopy

Digital holographic microscopy with physical phase compensation

Transmission digital holographic microscopy based on a beam-splitter cube interferometer

Microlens characterization by digital holographic microscopy with physical spherical phase compensation

Physical spherical phase compensation in reflection digital holographic microscopy

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