IEEE VIS 2024 Content: Localized Evaluation for Constructing Discrete Vector Fields

Localized Evaluation for Constructing Discrete Vector Fields

Tanner Finken - University of Arizona, Tucson, United States

Julien Tierny - Sorbonne Université, Paris, France

Joshua A Levine - University of Arizona, Tucson, United States

Room: Bayshore VI

2024-10-18T12:42:00ZGMT-0600Change your timezone on the schedule page
2024-10-18T12:42:00Z
Exemplar figure, described by caption below
We extract and simplify a vector field of ocean currents using our technique. The input mesh has over 48 million simplices, and the original flow results in over 65000 critical points. We simplify to approximately 2000 critical points using a discrete representation of the field. Computing the original field for a domain this big takes only 4 minutes and computing complete simplification takes approximately 10 minutes.
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Keywords

Flow visualization, discrete Morse theory, topological data analysis

Abstract

Topological abstractions offer a method to summarize the behavior of vector fields, but computing them robustly can be challenging due to numerical precision issues. One alternative is to represent the vector field using a discrete approach, which constructs a collection of pairs of simplices in the input mesh that satisfies criteria introduced by Forman’s discrete Morse theory. While numerous approaches exist to compute pairs in the restricted case of the gradient of a scalar field, state-of-the-art algorithms for the general case of vector fields require expensive optimization procedures. This paper introduces a fast, novel approach for pairing simplices of two-dimensional, triangulated vector fields that do not vary in time. The key insight of our approach is that we can employ a local evaluation, inspired by the approach used to construct a discrete gradient field, where every simplex in a mesh is considered by no more than one of its vertices. Specifically, we observe that for any edge in the input mesh, we can uniquely assign an outward direction of flow. We can further expand this consistent notion of outward flow at each vertex, which corresponds to the concept of a downhill flow in the case of scalar fields. Working with outward flow enables a linear-time algorithm that processes the (outward) neighborhoods of each vertex one-by-one, similar to the approach used for scalar fields. We couple our approach to constructing discrete vector fields with a method to extract, simplify, and visualize topological features. Empirical results on analytic and simulation data demonstrate drastic improvements in running time, produce features similar to the current state-of-the-art, and show the application of simplification to large, complex flows