Boosting Techniques for Physics-Based Vortex Detection

Boosting Techniques for Physics-Based Vortex Detection

Robust automated vortex detection algorithms are needed to facilitate the exploration of large‐scale turbulent fluid flow simulations. Unfortunately, robust non‐local vortex detection algorithms are computationally intractable for large data sets and local algorithms, while computationally tractable...

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Bibliographic Details
Published in:Computer graphics forum Vol. 33; no. 1; pp. 282 - 293
Main Authors: Zhang, L., Deng, Q., Machiraju, R., Rangarajan, A., Thompson, D., Walters, D. K., Shen, H.-W.
Format: Journal Article
Language:English
Published: Oxford Blackwell Publishing Ltd 01-02-2014
Subjects:
Algorithms
flow visualization
I.2.6 [Artificial intelligence]: LearningParameter learning
I.4.6 [Artificial intelligence]: Segmentation-Edge and feature detection
Machine learning
methods and applications
scientific visualization
visualization
Vortices
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Summary:Robust automated vortex detection algorithms are needed to facilitate the exploration of large‐scale turbulent fluid flow simulations. Unfortunately, robust non‐local vortex detection algorithms are computationally intractable for large data sets and local algorithms, while computationally tractable, lack robustness. We argue that the deficiencies inherent to the local definitions occur because of two fundamental issues: the lack of a rigorous definition of a vortex and the fact that a vortex is an intrinsically non‐local phenomenon. As a first step towards addressing this problem, we demonstrate the use of machine learning techniques to enhance the robustness of local vortex detection algorithms. We motivate the presence of an expert‐in‐the‐loop using empirical results based on machine learning techniques. We employ adaptive boosting to combine a suite of widely used, local vortex detection algorithms, which we term weak classifiers, into a robust compound classifier. Fundamentally, the training phase of the algorithm, in which an expert manually labels small, spatially contiguous regions of the data, incorporates non‐local information into the resulting compound classifier. We demonstrate the efficacy of our approach by applying the compound classifier to two data sets obtained from computational fluid dynamical simulations. Our results demonstrate that the compound classifier has a reduced misclassification rate relative to the component classifiers. Robust automated vortex detection algorithms are needed to facilitate the exploration of large‐scale turbulent fluid flow simulations. Unfortunately, robust non‐local vortex detection algorithms are computationally intractable for large data sets and local algorithms, while computationally tractable, lack robustness. We argue that the deficiencies inherent to the local definitions occur because of two fundamental issues: the lack of a rigorous definition of a vortex and the fact that a vortex is an intrinsically non‐local phenomenon. As a first step towards addressing this problem, we demonstrate the use of machine learning techniques to enhance the robustness of local vortex detection algorithms.
Bibliography:National Science Foundation - No. IIS-1065107
istex:5F24AEED8691F6F1F861B842738486396D5306B4
ark:/67375/WNG-SM7172MD-W
ArticleID:CGF12275
ISSN:0167-7055
1467-8659
DOI:10.1111/cgf.12275