Over Two Decades of Integration‐Based, Geometric Flow Visualization

McLoughlin, Tony; Laramee, Robert S.; Peikert, Ronald; Post, Frits H.; Chen, Min

doi:10.1111/j.1467-8659.2010.01650.x

Cited by 259 publications

(162 citation statements)

References 89 publications

(167 reference statements)

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“…In fact this application framework was involved in the development of a novel streak surface algorithm [McLoughlin, Laramee & Zhang (2010)]. A thorough review of geometric techniques is beyond the scope of this paper and we refer the interested reader to a survey on the topic by McLoughlin et al [McLoughlin, Laramee, Peikert, Post & Chen (2010)]. …”

Section: Geometric Flow Visualization Techniquesmentioning

confidence: 99%

Design and Implementation of Interactive Flow Visualization Techniques

McLoughlin¹,

Laramee²

2012

Computer Graphics

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Section: Geometric Flow Visualization Techniquesmentioning

confidence: 99%

Design and Implementation of Interactive Flow Visualization Techniques

McLoughlin¹,

Laramee²

2012

Computer Graphics

Self Cite

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“…Flow visualization methods visualize the results of flow simulation by drawing arrows or streamlines [Turk and Banks 1996], texture-based methods by applying flow patterns to random texutures [Cabral and Leedom 1993;Laramee et al 2004], geometric methods by extracting geometric objects such as streamlines or stream surfaces [McLouglin et al 2010], and feature-based methods by visualizing physically meaningful parts such as vortices [Post et al 2003]. These techniques rely on offline simulation results and can provide accurate visual effects.…”

Section: Related Workmentioning

confidence: 99%

Sketch-based Dynamic Illustration of Fluid Systems

Zhu¹,

Iwata

Haraguchi

et al. 2011

Proceedings of the 2011 SIGGRAPH Asia Conference

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This paper presents a lightweight sketching system that enables interactive illustration of complex fluid systems. Users can sketch on a 2.5-dimensional (2.5D) canvas to design the shapes and connections of a fluid circuit. These input sketches are automatically analyzed and abstracted into a hydraulic graph, and a new hybrid fluid model is used in the background to enhance the illustrations. The system provides rich simple operations for users to edit the fluid system incrementally, and the new internal flow patterns can be simulated in real time. Our system is used to illustrate various fluid systems in medicine, biology, and engineering. We asked professional medical doctors to try our system and obtained positive feedback from them.

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“…A key issue that affects the quality of streamlines representation is the seeding strategy and streamlines placement [11] because straightforward solutions would easily lead to clutter. Verma et al [20] presented a seed placement strategy to capture flow patterns around the critical points and to provide sufficient coverage in noncritical regions.…”

Section: Related Workmentioning

confidence: 99%

A sketch-based interface for classifying and visualizing vector fields

Wei

Wang

et al. 2010

2010 IEEE Pacific Visualization Symposium (PacificVis)

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In flow visualization, field lines are often used to convey both global and local structure and movement of the flow. One challenge is to find and classify the representative field lines. Most existing solutions follow an automatic approach that generates field lines characterizing the flow and arranges these lines into a single picture. In our work, we advocate a user-centric approach to exploring 3D vector fields. Our method allows the user to sketch 2D curves for pattern matching in 2D and field lines clustering in 3D. Specifically, a 3D field line whose view-dependent 2D projection is most similar to the user drawing will be identified and utilized to extract all similar 3D field lines. Furthermore, we employ an automatic clustering method to generate field-line templates for the user to locate subfields of interest. This semi-automatic process leverages the user's knowledge about the flow field through intuitive user interaction, resulting in a promising alternative to existing flow visualization solutions. With our sketch-based interface, the user can effectively dissect the flow field and make more structured visualization for analysis or presentation.

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Over Two Decades of Integration‐Based, Geometric Flow Visualization

Cited by 259 publications

References 89 publications

Design and Implementation of Interactive Flow Visualization Techniques

Design and Implementation of Interactive Flow Visualization Techniques

Sketch-based Dynamic Illustration of Fluid Systems

A sketch-based interface for classifying and visualizing vector fields

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