Embedded pupil function recovery for Fourier ptychographic microscopy

Ou, Xiaoze; Zheng, Guoan; Yang, Changhuei

doi:10.1364/oe.22.004960

Cited by 349 publications

(275 citation statements)

References 24 publications

(42 reference statements)

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“…Our initial guess of the 2D transmittance function at the corresponding sample slice is then o Δz x; y ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi ffi I Δz x; y p . We then improve the estimate for the sample's intensity and phase at each slice, as well as an estimate of the pupil function aberrations [40,[44][45][46], by an iterative Fourier ptychography (c) Reconstructions using our multislice method are compared to light field refocusing and physically changing the microscope focus. Diffraction effects severely blur the light field results, whereas our multislice method is able to recover the full diffraction-limited resolution with improved image contrast, while also removing out-of-focus blur.…”

Section: B Multislice Forward Modelmentioning

confidence: 99%

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3D intensity and phase imaging from light field measurements in an LED array microscope

Tian¹,

Waller²

2015

Optica

396

289

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Section: B Multislice Forward Modelmentioning

confidence: 99%

“…Our system is built on a commercial microscope in which the illumination unit has been replaced by a programmable LED array. This simple, inexpensive hardware modification enables not only 4D light field capture [35,38], but also dark field [38,39], phase contrast [35,39], Fourier ptychography [23,24], and digital aberration removal [40].…”

Section: Introductionmentioning

confidence: 99%

3D intensity and phase imaging from light field measurements in an LED array microscope

Tian¹,

Waller²

2015

Optica

396

289

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“…Our on-going efforts include 1) incorporating the pupil function correction functionality into the reported scheme [1,18,21,33,43,63], and 2) implementing the aperture-scanning scheme in a transmission electron microscope (TEM). We note that, in most commercially available TEM platforms, aperture scanning is a routine functionality for darkfield imaging [64].…”

Section: Resultsmentioning

confidence: 99%

“…Another source may be incorrect modeling of the aperture shape (we use a circular pupil in our FP reconstruction, while it should be an irregular pentagon corresponding to the Nikon photographic lens iris diaphragm). To reconstruct an improved-quality FP image, we can simultaneously recover both the high-resolution image and the irregular pupil function's shape [43].…”

Section: Macroscopic Imaging Beyond the Diffraction Limit Via Camera-mentioning

confidence: 99%

Aperture-scanning Fourier ptychography for 3D refocusing and super-resolution macroscopic imaging

et al. 2014

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Abstract:We report an imaging scheme, termed aperture-scanning Fourier ptychography, for 3D refocusing and super-resolution macroscopic imaging. The reported scheme scans an aperture at the Fourier plane of an optical system and acquires the corresponding intensity images of the object. The acquired images are then synthesized in the frequency domain to recover a high-resolution complex sample wavefront; no phase information is needed in the recovery process. We demonstrate two applications of the reported scheme. In the first example, we use an aperture-scanning Fourier ptychography platform to recover the complex hologram of extended objects. The recovered hologram is then digitally propagated into different planes along the optical axis to examine the 3D structure of the object. We also demonstrate a reconstruction resolution better than the detector pixel limit (i.e., pixel super-resolution). In the second example, we develop a camera-scanning Fourier ptychography platform for super-resolution macroscopic imaging. By simply scanning the camera over different positions, we bypass the diffraction limit of the photographic lens and recover a super-resolution image of an object placed at the far field. This platform's maximum achievable resolution is ultimately determined by the camera's traveling range, not the aperture size of the lens. The FP scheme reported in this work may find applications in 3D object tracking, synthetic aperture imaging, remote sensing, and optical/electron/X-ray microscopy.

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“…We then constrain ψ After Fourier transforming ψ j into Ψ j , we are then ready to update our unaberrated sample spectrum estimate,Ŝ j . To remove the effects of aberrations, we adopt a strategy common to prior algorithms like ePIE [7] and EPRY [38] and effectively divide out the aberration function estimate A j from Ψ j :Ŝ…”

Section: Characterization and Removal Of Low-order Aberrationsmentioning

confidence: 99%

Overlapped Fourier coding for optical aberration removal

Horstmeyer¹,

Ou²,

Chung³

et al. 2014

Opt. Express

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We present an imaging procedure that simultaneously optimizes a camera's resolution and retrieves a sample's phase over a sequence of snapshots. The technique, termed overlapped Fourier coding (OFC), first digitally pans a small aperture across a camera's pupil plane with a spatial light modulator. At each aperture location, a unique image is acquired. The OFC algorithm then fuses these low-resolution images into a full-resolution estimate of the complex optical field incident upon the detector. Simultaneously, the algorithm utilizes redundancies within the acquired dataset to computationally estimate and remove unknown optical aberrations and system misalignments via simulated annealing. The result is an imaging system that can computationally overcome its optical imperfections to offer enhanced resolution, at the expense of taking multiple snapshots over time.

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Embedded pupil function recovery for Fourier ptychographic microscopy

Cited by 349 publications

References 24 publications

3D intensity and phase imaging from light field measurements in an LED array microscope

3D intensity and phase imaging from light field measurements in an LED array microscope

Aperture-scanning Fourier ptychography for 3D refocusing and super-resolution macroscopic imaging

Overlapped Fourier coding for optical aberration removal

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