2021
DOI: 10.1063/5.0054920
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Deep learning-based statistical noise reduction for multidimensional spectral data

Abstract: In spectroscopic experiments, data acquisition in multi-dimensional phase space may require long acquisition time, owing to the large phase space volume to be covered. In such a case, the limited time available for data acquisition can be a serious constraint for experiments in which multidimensional spectral data are acquired. Here, taking angle-resolved photoemission spectroscopy (ARPES) as an example, we demonstrate a denoising method that utilizes deep learning as an intelligent way to overcome the constra… Show more

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Cited by 32 publications
(41 citation statements)
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“…Small-angle neutron and X-ray scattering data [26] would be an obvious path to extend the training data. Spectroscopies [27,28] and microscopies [29,30] such as angle-resolved photoemission electron spectroscopy [31] and transmission electron microscopy [32,33] data could also help expanding the amount and variety of training data. Data from astronomy and medical scanners would be another way to train the networks on a wider spectrum of noise sources.…”
Section: Discussionmentioning
confidence: 99%
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“…Small-angle neutron and X-ray scattering data [26] would be an obvious path to extend the training data. Spectroscopies [27,28] and microscopies [29,30] such as angle-resolved photoemission electron spectroscopy [31] and transmission electron microscopy [32,33] data could also help expanding the amount and variety of training data. Data from astronomy and medical scanners would be another way to train the networks on a wider spectrum of noise sources.…”
Section: Discussionmentioning
confidence: 99%
“…Loss function: During each training epoch, the performance of the neural networks is determined by comparing the denoised output with the high-count frame. The used loss function L is given by a combination of mean absolute error (MAE) and multiscale structural similar-ity (MSSIM) [27,37] L = (1 − α)L MAE + αL MSSIM with α = 0.7 where the MAE between two images x and y is given by the sum over all pixels i MAE(x, y) =…”
Section: X-ray Diffractionmentioning
confidence: 99%
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“…Therefore, their use is limited to selected momentum locations determined heuristically from physical knowledge of the materials and the experimental settings. Image processing-based methods apply data transformations to improve the visibility of dispersive features [15][16][17][18]. They are more computationally efficient and can operate on entire datasets, yet offer only visual enhancement of the underlying band dispersion.…”
mentioning
confidence: 99%
“…For example, a deep layer of convolutional neural network (ConvNet) is trained to denoise ARPES data [28]. Afterwards, there are efforts to obtain how the bandstructure calculation based on the ARPES data [29,30], where reference [30] provides additional feature of obtaining the result even through a noisy data (simulated noise).…”
mentioning
confidence: 99%