Quasi-physical phase compensation in digital holographic microscopy

Qu, Weijuan; Choo, Chee Oi; Singh, Vijay Raj; Yu, Yingjie; Asundi, Anand

doi:10.1364/josaa.26.002005

Cited by 69 publications

(27 citation statements)

References 15 publications

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“…The corresponding threedimensional (3D) profile is shown by converting the phase to the physical height of the lens [the refractive index of lens material (fused silica) is 1.46]. For comparison, the same sample was also measured using a digital holographic microscopy (DHM) system (laser wavelength 650 nm, magnification 43x), described in detail in [37]. Figure 4(g) shows the digital hologram captured and the high-frequency carrier fringes due to the off-axis geometry are clearly visible in the enlarged area.…”

Section: Characterization Of Microlens Array Using Ofsmentioning

confidence: 99%

High-speed transport-of-intensity phase microscopy with an electrically tunable lens

Zuo¹,

Chen²,

Qu³

et al. 2013

Opt. Express

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192

136

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We present a high-speed transport-of-intensity equation (TIE) quantitative phase microscopy technique, named TL-TIE, by combining an electrically tunable lens with a conventional transmission microscope. This permits the specimen at different focus position to be imaged in rapid succession, with constant magnification and no physically moving parts. The simplified image stack collection significantly reduces the acquisition time, allows for the diffraction-limited through-focus intensity stack collection at 15 frames per second, making dynamic TIE phase imaging possible. The technique is demonstrated by profiling of microlens array using optimal frequency selection scheme, and time-lapse imaging of live breast cancer cells by inversion the defocused phase optical transfer function to correct the phase blurring in traditional TIE. Experimental results illustrate its outstanding capability of the technique for quantitative phase imaging, through a simple, non-interferometric, high-speed, high-resolution, and unwrapping-free approach with prosperous applications in micro-optics, life sciences and bio-photonics.

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Section: Characterization Of Microlens Array Using Ofsmentioning

confidence: 99%

High-speed transport-of-intensity phase microscopy with an electrically tunable lens

Zuo¹,

Chen²,

Qu³

et al. 2013

Opt. Express

Self Cite

192

136

View full text Add to dashboard Cite

show abstract

“…1(b), we assume that the reference wave is generated by a point source located at x r ; y r ; z r , and the object wave is also generated by a point source located at x o ; y o ; z o , where z r is the distance between the point source of the reference wave and hologram plane; similarly, z o is the distance between the point source of the object wave and hologram plane. Thus, the reference wave Rx H ; y H and object wave Ox H ; y H in the hologram plane can be, respectively, expressed as follows [20]:…”

Section: A Phase Errors Mathematical Modelmentioning

confidence: 99%

“…(4)] by the frequency filtering method for numerical reconstruction. Throughout this paper, the reconstructed holographic image ψ I can be calculated from ψ F H by the angular spectrum method [20] as in Eq. (5)…”

Section: A Phase Errors Mathematical Modelmentioning

confidence: 99%

Further investigation on the phase stitching and system errors in digital holography

Wen

Cheng

et al. 2015

Appl. Opt.

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In this work, an improved phase stitching algorithm is proposed in digital holography (DH) based on a deduced phase errors model and a global optimization algorithm. In addition, to correct the relative rotation error between the coordinate systems of a CCD and xy-motion stages, we presented a simple and reliable image-based correction method. The experimental results obtained from our proposed method are compared with those calculated from the existing phase stitching method to verify the performance of the presented method. It is shown that our new proposed methods are robust and valid for measurement of a large microstructure element. As far as we know, the improved phase stitching algorithm and image-base correction method have not been discussed in DH, as we presented in this paper.

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“…Aberration compensation usually relies on the optimization of a quality criterium (usually the Strehl ratio combined to an aberration model [23], or the maximization of the specular component in Fourier space [24]), or a reference hologram allowing for the measurement of any departure from a perfect reference wave (i.e., plane or spherical). This reference hologram is obtained by double exposition [25], or by selecting a profile (for example, a line profile) in a flat area of the sample [26].…”

Section: A Automatic Aberration Compensationmentioning

confidence: 99%

Tomographic diffractive microscopy and multiview profilometry with flexible aberration correction

et al. 2014

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We have developed a tomographic diffractive microscope in reflection, which permits observation of sample surfaces with an improved lateral resolution, compared to a conventional holographic microscope. From the same set of data, high-precision measurements can be performed on the shape of the reflective surface by reconstructing the phase of the diffracted field. Doing so allows for several advantages compared to classical holographic interferometric measurements: improvement in lateral resolution, easier phase unwrapping, reduction of the coherent noise, combined with the high-longitudinal precision provided by interferometric phase measurements. We demonstrate these capabilities by imaging various test samples.

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Quasi-physical phase compensation in digital holographic microscopy

Cited by 69 publications

References 15 publications

High-speed transport-of-intensity phase microscopy with an electrically tunable lens

High-speed transport-of-intensity phase microscopy with an electrically tunable lens

Further investigation on the phase stitching and system errors in digital holography

Tomographic diffractive microscopy and multiview profilometry with flexible aberration correction

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