Multilevel Robustness for 2D Vector Field Feature Tracking, Selection and Comparison

Author:

Yan Lin1,Ullrich Paul Aaron2,Van Roekel Luke P.3,Wang Bei4,Guo Hanqi5

Affiliation:

1. Environmental Science & Mathematics and Computer Science Argonne National Laboratory Lemont USA

2. Department of Land, Air and Water Resources University of California Davis USA

3. The Fluid Dynamics and Solid Mechanics, Los Alamos USA

4. School of Computing, Scientific Computing and Imaging (SCI) Institute University of Utah Salt Lake City USA

5. Department of Computer Science and Engineering The Ohio State University Columbus USA

Abstract

AbstractCritical point tracking is a core topic in scientific visualization for understanding the dynamic behaviour of time‐varying vector field data. The topological notion of robustness has been introduced recently to quantify the structural stability of critical points, that is, the robustness of a critical point is the minimum amount of perturbation to the vector field necessary to cancel it. A theoretical basis has been established previously that relates critical point tracking with the notion of robustness, in particular, critical points could be tracked based on their closeness in stability, measured by robustness, instead of just distance proximity within the domain. However, in practice, the computation of classic robustness may produce artifacts when a critical point is close to the boundary of the domain; thus, we do not have a complete picture of the vector field behaviour within its local neighbourhood. To alleviate these issues, we introduce a multilevel robustness framework for the study of 2D time‐varying vector fields. We compute the robustness of critical points across varying neighbourhoods to capture the multiscale nature of the data and to mitigate the boundary effect suffered by the classic robustness computation. We demonstrate via experiments that such a new notion of robustness can be combined seamlessly with existing feature tracking algorithms to improve the visual interpretability of vector fields in terms of feature tracking, selection and comparison for large‐scale scientific simulations. We observe, for the first time, that the minimum multilevel robustness is highly correlated with physical quantities used by domain scientists in studying a real‐world tropical cyclone dataset. Such an observation helps to increase the physical interpretability of robustness.

Funder

U.S. Department of Energy

National Science Foundation

Publisher

Wiley

Subject

Computer Graphics and Computer-Aided Design

Cited by 1 articles. 订阅此论文施引文献 订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献

1. TROPHY: A Topologically Robust Physics-Informed Tracking Framework for Tropical Cyclones;IEEE Transactions on Visualization and Computer Graphics;2023

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