Abstract
Computer vision and machine learning tools offer an exciting new way for automatically analyzing and categorizing information from complex computer simulations. Here we design an ensemble machine learning framework that can independently and robustly categorize and dissect simulation data output contents of turbulent flow patterns into distinct structure catalogs. The segmentation is performed using an unsupervised clustering algorithm, which segments physical structures by grouping together similar pixels in simulation images. The accuracy and robustness of the resulting segment region boundaries are enhanced by combining information from multiple simultaneously-evaluated clustering operations. The stacking of object segmentation evaluations is performed using image mask combination operations. This statistically-combined ensemble (SCE) of different cluster masks allows us to construct cluster reliability metrics for each pixel and for the associated segments without any prior user input. By comparing the similarity of different cluster occurrences in the ensemble, we can also assess the optimal number of clusters needed to describe the data. Furthermore, by relying on ensemble-averaged spatial segment region boundaries, the SCE method enables reconstruction of more accurate and robust region of interest (ROI) boundaries for the different image data clusters. We apply the SCE algorithm to 2-dimensional simulation data snapshots of magnetically-dominated fully-kinetic turbulent plasma flows where accurate ROI boundaries are needed for geometrical measurements of intermittent flow structures known as current sheets.
Highlights
Turbulent, seemingly chaotic flows, are known to create self-similar structures and flow patterns on multiple scales
We present a new ensemble unsupervised machine learning algorithm for image structure detection and automated segmentation that is tailored for structure detection from computer simulation outputs
We show that the resulting region of interest (ROI) of the objects from the combined ensemble algorithm are more interpretable and geometrically more stable against fluctuations
Summary
Seemingly chaotic flows, are known to create self-similar structures and flow patterns on multiple scales. Interesting are any discrete long-lived structures that appear close to the dissipation scales, originating from the intermittency of the turbulence. Analyzing the geometrical shapes and sizes of these structures can help us better quantify the role of intermittency in turbulent fluids and plasmas. Different statistical methods for automating the detection of such structures have been conceived but the algorithms are known to be computationally very demanding [e.g.2–4]. Machine learning methods and computer vision algorithms offer a new promising avenue for constructing such detection frameworks since they are fast to evaluate and highly optimized [e.g., 5–7]. We present a new ensemble unsupervised machine learning algorithm for image structure detection and automated segmentation that is tailored for structure detection from computer simulation outputs
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