Cores of Swirling Particle Motion in Unsteady Flows

In nature and in flow experiments particles form patterns of swirling motion in certain locations. Existing approaches identify these structures by considering the behavior of stream lines. However, in unsteady flows particle motion is described by path lines which generally gives different swirling patterns than stream lines. We introduce a novel mathematical characterization of swirling motion cores in unsteady flows by generalizing the approach of Sujudi/Haimes to path lines. The cores of swirling particle motion are lines sweeping over time, i.e., surfaces in the space-time domain. They occur at locations where three derived 4D vectors become coplanar. To extract them, we show how to re-formulate the problem using the parallel vectors operator. We apply our method to a number of unsteady flow fields.

[1]  Hans-Christian Hege,et al.  Vortex and Strain Skeletons in Eulerian and Lagrangian Frames , 2007, IEEE Transactions on Visualization and Computer Graphics.

[2]  Ronald Peikert,et al.  A higher-order method for finding vortex core lines , 1998, Proceedings Visualization '98 (Cat. No.98CB36276).

[3]  Lambertus Hesselink,et al.  Representation and display of vector field topology in fluid flow data sets , 1989, Computer.

[4]  David C. Banks,et al.  A Predictor-Corrector Technique for Visualizing Unsteady Flow , 1995, IEEE Trans. Vis. Comput. Graph..

[5]  B. R. Noack,et al.  On the transition of the cylinder wake , 1995 .

[6]  Jinhee Jeong,et al.  On the identification of a vortex , 1995, Journal of Fluid Mechanics.

[7]  Hans-Christian Hege,et al.  amira: A Highly Interactive System for Visual Data Analysis , 2005, The Visualization Handbook.

[8]  Hans-Christian Hege,et al.  Eurographics -ieee Vgtc Symposium on Visualization (2005) Galilean Invariant Extraction and Iconic Representation of Vortex Core Lines , 2022 .

[9]  J. Hunt Vorticity and vortex dynamics in complex turbulent flows , 1987 .

[10]  Ronald Peikert,et al.  Vortex Tracking in Scale-Space , 2002, VisSym.

[11]  Hans-Peter Seidel,et al.  Feature Flow Fields , 2003, VisSym.

[12]  Hans Hagen,et al.  Topology tracking for the visualization of time-dependent two-dimensional flows , 2002, Comput. Graph..

[13]  Hans-Peter Seidel,et al.  Topological methods for 2D time-dependent vector fields based on stream lines and path lines , 2005, IEEE Transactions on Visualization and Computer Graphics.

[14]  Ronald Peikert,et al.  The "Parallel Vectors" operator-a vector field visualization primitive , 1999, Proceedings Visualization '99 (Cat. No.99CB37067).

[15]  G. Haller An objective definition of a vortex , 2004, Journal of Fluid Mechanics.

[16]  Robert S. Laramee,et al.  Feature Extraction and Visualisation of Flow Fields , 2002, Eurographics.

[17]  D. Sujudi,et al.  Identification of Swirling Flow in 3-D Vector Fields , 1995 .

[18]  J. Debonis,et al.  Low Dimensional Modeling of Flow for Closed-Loop Flow Control , 2003 .

[19]  Hans-Peter Seidel,et al.  Extraction of parallel vector surfaces in 3D time-dependent fields and application to vortex core line tracking , 2005, VIS 05. IEEE Visualization, 2005..

[20]  Hans-Peter Seidel,et al.  Feature Flow Fields in Out-of-Core Settings , 2007, Topology-based Methods in Visualization.