Variational Feature Extraction in Scientific Visualization

IF 7.8 1区 计算机科学 Q1 COMPUTER SCIENCE, SOFTWARE ENGINEERING ACM Transactions on Graphics Pub Date : 2024-07-19 DOI:10.1145/3658219
Nico Daßler, Tobias Günther
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Abstract

Across many scientific disciplines, the pursuit of even higher grid resolutions leads to a severe scalability problem in scientific computing. Feature extraction is a commonly chosen approach to reduce the amount of information from dense fields down to geometric primitives that further enable a quantitative analysis. Examples of common features are isolines, extremal lines, or vortex corelines. Due to the rising complexity of the observed phenomena, or in the event of discretization issues with the data, a straightforward application of textbook feature definitions is unfortunately insufficient. Thus, feature extraction from spatial data often requires substantial pre- or post-processing to either clean up the results or to include additional domain knowledge about the feature in question. Such a separate pre- or post-processing of features not only leads to suboptimal and incomparable solutions, it also results in many specialized feature extraction algorithms arising in the different application domains. In this paper, we establish a mathematical language that not only encompasses commonly used feature definitions, it also provides a set of regularizers that can be applied across the bounds of individual application domains. By using the language of variational calculus, we treat features as variational minimizers, which can be combined and regularized as needed. Our formulation not only encompasses existing feature definitions as special case, it also opens the path to novel feature definitions. This work lays the foundations for many new research directions regarding formal definitions, data representations, and numerical extraction algorithms.
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科学可视化中的变量特征提取
在许多科学学科中,对更高网格分辨率的追求导致了科学计算中严重的可扩展性问题。特征提取是一种常用的方法,可将密集场的信息量缩减为几何基元,从而进一步实现定量分析。常见特征的例子有孤立线、极值线或涡旋核心线。由于观测到的现象越来越复杂,或者在数据离散化的情况下,直接应用教科书上的特征定义是不够的。因此,从空间数据中提取特征往往需要大量的预处理或后处理,以清理结果或纳入有关特征的其他领域知识。这种单独的特征预处理或后处理不仅会导致次优和无法比较的解决方案,还会导致不同应用领域出现许多专门的特征提取算法。在本文中,我们建立了一种数学语言,它不仅包含了常用的特征定义,还提供了一组可应用于不同应用领域的正则。通过使用变分微积分语言,我们将特征视为变分最小值,可根据需要对其进行组合和正则化。我们的表述不仅将现有的特征定义作为特例,还为新颖的特征定义开辟了道路。这项工作为有关形式定义、数据表示和数值提取算法的许多新研究方向奠定了基础。
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来源期刊
ACM Transactions on Graphics
ACM Transactions on Graphics 工程技术-计算机:软件工程
CiteScore
14.30
自引率
25.80%
发文量
193
审稿时长
12 months
期刊介绍: ACM Transactions on Graphics (TOG) is a peer-reviewed scientific journal that aims to disseminate the latest findings of note in the field of computer graphics. It has been published since 1982 by the Association for Computing Machinery. Starting in 2003, all papers accepted for presentation at the annual SIGGRAPH conference are printed in a special summer issue of the journal.
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