A Parameter Refinement Method for Ptychography Based on Deep Learning Concepts

Guzzi, Francesco; Kourousias, George; Gianoncelli, Alessandra; Billè, Fulvio; Carrato, Sergio

doi:10.3390/condmat6040036

Cited by 12 publications

(19 citation statements)

References 63 publications

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“…Recently, the rPIE algorithm ( Maiden, Johnson & Li, 2017 ) has been proposed and studied: while being reasonably simple, it provides a fast convergence to a good object estimate ( Maiden, Johnson & Li, 2017 ). Compared to ePIE, we noticed that the rPIE algorithm, at least in our implementation, also provides a large computational FOV, which is comparable to the one seen in more advanced, but also computational eager, optimisation algorithms ( Guizar-Sicairos & Fienup, 2008 ; Thibault & Guizar-Sicairos, 2012 ; Guzzi et al, 2021b ). Indeed, these latter methods are used to refine a previous reconstruction, as they are more prone to stagnation ( Thibault & Guizar-Sicairos, 2012 ).…”

Section: Introductionmentioning

confidence: 70%

“…A correction method must then be introduced a posteriori , increasing the reconstruction time. In Guizar-Sicairos & Fienup (2008) ; Guzzi et al (2021b) positions are corrected through an optimisation method, within the gradient-based reconstruction; in Mandula et al (2016) , instead, the authors propose to use a gradient-less method based on Powell (1964) to guide the position refinement procedure. In this work, we consider a fast and reliable way to correct translations.…”

Section: Methodsmentioning

confidence: 99%

“…Writing such programs is typically done by an expert software engineer, and this step may discourage the prototyping or the study of new methods. Ptychography algorithms are complex not only in their implementation, but also per se : simple computational systems suffers from setup inconsistencies, which usually takes the form of bad parameter modelling of positions ( Zhang et al, 2013 ), distances ( Guzzi et al, 2021b ), illumination conditions ( Thibault & Menzel, 2013 ), just to enumerate a few. Such problems produce very noticeable artefacts.…”

Section: Introductionmentioning

confidence: 99%

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A modular software framework for the design and implementation of ptychography algorithms

Guzzi

Kourousias

Billè

et al. 2022

PeerJ Computer Science

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Computational methods are driving high impact microscopy techniques such as ptychography. However, the design and implementation of new algorithms is often a laborious process, as many parts of the code are written in close-to-the-hardware programming constructs to speed up the reconstruction. In this article, we present SciComPty, a new ptychography software framework aiming at simulating ptychography datasets and testing state-of-the-art and new reconstruction algorithms. Despite its simplicity, the software leverages GPU accelerated processing through the PyTorch CUDA interface. This is essential for designing new methods that can readily be employed. As an example, we present an improved position refinement method based on Adam and a new version of the rPIE algorithm, adapted for partial coherence setups. Results are shown on both synthetic and real datasets. The software is released as open-source.

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Section: Introductionmentioning

confidence: 70%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A modular software framework for the design and implementation of ptychography algorithms

Guzzi

Kourousias

Billè

et al. 2022

PeerJ Computer Science

Self Cite

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“…Following our framework, it is possible to rapidly prototype state-of-the-art solutions for computational microscopy methods. Possible examples are: a compressive sensing reconstruction algorithm for sparse datasets, a single image super-resolution algorithm for recovering missing information from a low-resolution image, a 2D/3D tomography reconstruction algorithm that can deal with the missing wedge problem, sparse acquisition and axial misalignment, and a ptychography algorithm, which can retrieve many geometry parameters [ 13 ]. Even if the aforementioned solutions are purely “conventional”, the use of such an AI component as AD blurs out the distinction between classical and AI methods [ 12 , 14 , 15 ].…”

Section: Introductionmentioning

confidence: 99%

Automatic Differentiation for Inverse Problems in X-ray Imaging and Microscopy

Guzzi

Gianoncelli

Billè

et al. 2023

Life

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Computational techniques allow breaking the limits of traditional imaging methods, such as time restrictions, resolution, and optics flaws. While simple computational methods can be enough for highly controlled microscope setups or just for previews, an increased level of complexity is instead required for advanced setups, acquisition modalities or where uncertainty is high; the need for complex computational methods clashes with rapid design and execution. In all these cases, Automatic Differentiation, one of the subtopics of Artificial Intelligence, may offer a functional solution, but only if a GPU implementation is available. In this paper, we show how a framework built to solve just one optimisation problem can be employed for many different X-ray imaging inverse problems.

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“…Its effectiveness is shown also for ptychographic inverse problem in [33]. In addition, supervised approaches such as the deep generative priors (DGPs) have also been applied for reducing imaging artifacts associated with undersampling [34], [35], as well as to overcome issues related to partialcoherence of the source [36]. Successful reconstructions using generative networks are demonstrated in [37] for Fourier ptychography and [38] for x-ray ptychography.…”

Section: Introductionmentioning

confidence: 99%

Compressive Ptychography using Deep Image and Generative Priors

Barutcu¹,

Gürsoy²,

Katsaggelos³

2022

Preprint

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Ptychography is a well-established coherent diffraction imaging technique that enables non-invasive imaging of samples at a nanometer scale. It has been extensively used in various areas such as the defense industry or materials science. One major limitation of ptychography is the long data acquisition time due to mechanical scanning of the sample; therefore, approaches to reduce the scan points are highly desired. However, reconstructions with less number of scan points lead to imaging artifacts and significant distortions, hindering a quantitative evaluation of the results. To address this bottleneck, we propose a generative model combining deep image priors with deep generative priors. The self-training approach optimizes the deep generative neural network to create a solution for a given dataset. We complement our approach with a prior acquired from a previously trained discriminator network to avoid a possible divergence from the desired output caused by the noise in the measurements. We also suggest using the total variation as a complementary before combat artifacts due to measurement noise. We analyze our approach with numerical experiments through different probe overlap percentages and varying noise levels. We also demonstrate improved reconstruction accuracy compared to the state-of-the-art method and discuss the advantages and disadvantages of our approach.

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A Parameter Refinement Method for Ptychography Based on Deep Learning Concepts

Cited by 12 publications

References 63 publications

A modular software framework for the design and implementation of ptychography algorithms

A modular software framework for the design and implementation of ptychography algorithms

Automatic Differentiation for Inverse Problems in X-ray Imaging and Microscopy

Compressive Ptychography using Deep Image and Generative Priors

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