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| Funder | Engineering and Physical Sciences Research Council |
|---|---|
| Recipient Organization | University of Bath |
| Country | United Kingdom |
| Start Date | Sep 30, 2024 |
| End Date | Mar 30, 2028 |
| Duration | 1,277 days |
| Number of Grantees | 2 |
| Roles | Student; Supervisor |
| Data Source | UKRI Gateway to Research |
| Grant ID | 2926418 |
Ptychography is a method of recovering the phase and amplitude of an image via an inverse Fourier transform problem. The method can be used to reconstruct images that are noisy and have low resolution. The ptychographical iterative engine (PIE) is a phase retrieval algorithm that can perform this method. There are several different
iterations of this algorithm such as parallel PIE (pPIE), extended PIE (ePIE), regularized PIE (rPIE) and momentumaccelerated PIE (mPIE). My aim is to develop, test and analyse algorithms for recovering full ptychography images from undersampled data, particularly in tomography, which consists of many similar images at slightly different
angles, and/or spectral ptychography at multiple beam energies. Initial objectives will be: - To study the error between fully sampled and undersampled images under random data collection. - Design a more efficient data collection pattern, especially for big data scenarios like spectral tomography. Other methods to look at are regularisation and relaxation techniques when applied to the optimisation problems
underlying ptychography and tomography. In particular, similar images in (spectral) tomography can be approximated by a low-rank matrix or tensor. In turn, the nonlinearity in the ptychography model can be lifted by considering a product of image with its copy. Time permitting, the project will consider uncertainty quantification (such as Bayesian
inference) if the noise in the image is large, for example, in the case of low photon counts. Ptychography is used in the reconstruction of images from x-ray spectrometers and images from electron microscopes. If under-sampling images has a comparable performance to an existing reconstruction algorithm,
reconstruction times might be quicker as fewer diffraction patterns will need to be recorded. This in turn will reduce the x-ray dosage required for the experiments. For synchrotron facilities that use this technique such as Diamond Light Source, UK, poss ible faster reconstruction times will mean less time running the experiment at the end of a
beamline so the cost will be cheaper. It will also mean that more experiments can be run since each individual experiment will take less time.
University of Bath
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