Related papers: Harnessing Machine Learning for Single-Shot Measurement of Free Electron Laser Pulse Power

Harnessing Machine Learning for Single-Shot Measurement of Free Electron Laser Pulse Power

URL: http://arxiv.org/abs/2411.09468v2
Date: Fri, 15 Nov 2024 15:38:17 GMT
Title: Harnessing Machine Learning for Single-Shot Measurement of Free Electron Laser Pulse Power
Authors: Till Korten, Vladimir Rybnikov, Mathias Vogt, Juliane Roensch-Schulenburg, Peter Steinbach, Najmeh Mirian,
Abstract summary: We develop a machine learning model that predicts the temporal power profile of the electron bunch in the lasing-off regime. The model was statistically validated and showed superior predictions compared to the state-of-the-art batch calibrations.
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Abstract: Electron beam accelerators are essential in many scientific and technological fields. Their operation relies heavily on the stability and precision of the electron beam. Traditional diagnostic techniques encounter difficulties in addressing the complex and dynamic nature of electron beams. Particularly in the context of free-electron lasers (FELs), it is fundamentally impossible to measure the lasing-on and lasingoff electron power profiles for a single electron bunch. This is a crucial hurdle in the exact reconstruction of the photon pulse profile. To overcome this hurdle, we developed a machine learning model that predicts the temporal power profile of the electron bunch in the lasing-off regime using machine parameters that can be obtained when lasing is on. The model was statistically validated and showed superior predictions compared to the state-of-the-art batch calibrations. The work we present here is a critical element for a virtual pulse reconstruction diagnostic (VPRD) tool designed to reconstruct the power profile of individual photon pulses without requiring repeated measurements in the lasing-off regime. This promises to significantly enhance the diagnostic capabilities in FELs at large.

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