Automatic Particle Trajectory Classification in Plasma Simulations

Automatic Particle Trajectory Classification in Plasma Simulations

Numerical simulations of plasma flows are crucial for advancing our understanding of microscopic processes that drive the global plasma dynamics in fusion devices, space, and astrophysical systems. Identifying and classifying particle trajectories allows us to determine specific on-going acceleratio...

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Bibliographic Details
Published in:2020 IEEE/ACM Workshop on Machine Learning in High Performance Computing Environments (MLHPC) and Workshop on Artificial Intelligence and Machine Learning for Scientific Applications (AI4S) pp. 64 - 71
Main Authors: Markidis, Stefano, Peng, Ivy, Podobas, Artur, Jongsuebchoke, Itthinat, Bengtsson, Gabriel, Herman, Pawel
Format: Conference Proceeding
Language:English
Published: IEEE 01-11-2020
Subjects:
Clustering
Conferences
Fast Fourier Transform
K-means
Machine learning
Magnetic reconnection
Numerical simulation
Particle Trajectory Classification
Particle-in-Cell Simulations
Plasma simulation
Principal Component Analysis
Space exploration
Trajectory
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Summary:Numerical simulations of plasma flows are crucial for advancing our understanding of microscopic processes that drive the global plasma dynamics in fusion devices, space, and astrophysical systems. Identifying and classifying particle trajectories allows us to determine specific on-going acceleration mechanisms, shedding light on essential plasma processes.Our overall goal is to provide a general workflow for exploring particle trajectory space and automatically classifying particle trajectories from plasma simulations in an unsupervised manner. We combine pre-processing techniques, such as Fast Fourier Transform (FFT), with Machine Learning methods, such as Principal Component Analysis (PCA), k-means clustering algorithms, and silhouette analysis. We demonstrate our workflow by classifying electron trajectories during magnetic reconnection problem. Our method successfully recovers existing results from previous literature without a priori knowledge of the underlying system.Our workflow can be applied to analyzing particle trajectories in different phenomena, from magnetic reconnection, shocks to magnetospheric flows. The workflow has no dependence on any physics model and can identify particle trajectories and acceleration mechanisms that were not detected before.
DOI:10.1109/MLHPCAI4S51975.2020.00014