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Pegase data set visualized by clipped 3D--LIC
source: Interactive Exploration of Volume Line Integral Convolution Based on 3D--Texture Mapping
contact: Peter Hastreiter |
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Cavity flow field visualized by clipped 3D-LIC.
source: Interactive Exploration of Volume Line Integral Convolution Based on 3D--Texture Mapping
contact: Peter Hastreiter |
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Vector plot and 3D-LIC within the aorta.
source: Interactive Exploration of Volume Line Integral Convolution Based on 3D--Texture Mapping
contact: Peter Hastreiter |
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Visualization of 3D-LIC with different transfer functions.
source: Interactive Exploration of Volume Line Integral Convolution Based on 3D--Texture Mapping
contact: Peter Hastreiter |
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Visualization of 3D-LIC combined with an arrow plot.
source: Interactive Exploration of Volume Line Integral Convolution Based on 3D--Texture Mapping
contact: Peter Hastreiter |
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Color table animation of 3D-LIC.
source: Interactive Exploration of Volume Line Integral Convolution Based on 3D--Texture Mapping
contact: Peter Hastreiter |
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Interactive exploration of 3D-LIC.
source: Interactive Exploration of Volume Line Integral Convolution Based on 3D--Texture Mapping
contact: Peter Hastreiter |
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Animation of 3D-LIC of a flow simulation.
source: Interactive Exploration of Volume Line Integral Convolution Based on 3D--Texture Mapping
contact: Peter Hastreiter |
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Interactive visualization of 3D--LIC of a flow simulation.
source: Interactive Exploration of Volume Line Integral Convolution Based on 3D--Texture Mapping
contact: Peter Hastreiter |
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Example of an IRIS Explorer map for sparse grid particle tracing.
source: Scientific Visualization on Sparse Grids
contact: Christian Teitzel |
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Streak tetrahedra in an analytically given flow on a curvilinear sparse grid of level 5.
source: Scientific Visualization on Sparse Grids
contact: Christian Teitzel |
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Streak lines in a vortex flow; yellow lines display the flow on a full grid, blue, green, and red lines on a curvilinear sparse grid of level 2, 3, and 4 respectively. It can be seen that the traces computed on the full grid and the sparse grid of level 4 are almost identical.
source: Scientific Visualization on Sparse Grids
contact: Christian Teitzel |
 |
Streak lines in a vortex flow; yellow lines display the flow on a full grid, blue, green, and red lines on a curvilinear sparse grid of level 2, 3, and 4 respectively.
source: Scientific Visualization on Sparse Grids
contact: Christian Teitzel |
 |
Streak balls in the blunt fin data set; the red balls are computed on a curvilinear sparse grid of level 4, the yellow ones on a grid of level 3, and the green ones on a grid of level 2.
source: Scientific Visualization on Sparse Grids
contact: Christian Teitzel |
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Colored streak balls and tetrahedra in a vortex flow given on a sparse grid.
source: Particle Tracing on Sparse Grids
contact: Christian Teitzel |
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Streak bands in a vortex flow; ribbons containing blue edges display the flow on a full grid of level 7, bands with green edges the flow on a sparse grid of level 1.
source: Particle Tracing on Sparse Grids
contact: Christian Teitzel |
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Streak bands in a vortex flow; ribbons containing blue edges display the flow on a full grid of level 7, bands with green edges the flow on a sparse grid of level 3.
source: Particle Tracing on Sparse Grids
contact: Christian Teitzel |
 |
Streak tubes in a cavity flow; the red tubes are computed on a full grid of level 7, the other tubes are created on sparse grids of level 7 (yellow), 5 (blue), and 3 (green).
source: Particle Tracing on Sparse Grids
contact: Christian Teitzel |
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Flow in a floating-zone furnace for crystal growing. On the left hand side the stream bands are computed by the linear implicit Euler scheme and on the right hand
side the classical Runge-Kutta method of order four is used.
source: Efficient and Reliable Integration Methods for Particle Tracing in Unsteady Flows on Discrete Meshes
contact: Christian Teitzel |
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Particle tracing in a cross cylinder flow by means of stream tetrahedra. In the background you can see a green iso-surface of the pressure.
source: Flow Visualization for Multiblock Multigrid Simulations
contact: Christian Teitzel |
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Slice through the gas generator of a car air bag. The velocity field of the unsteady gas flow is visualized during the initial ignition of the air bag. At the bottom you
can see the box with the blasting composition, then a channel to reduce the temperature of the gas and on the top a small part of the actual air bag. This data set
consists of thirteen blocks. The pressure is colour coded.
source: Line Integral Convolution on Triangulated Surfaces
contact: Christian Teitzel |
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Slice through the gas generator of a car air bag. The velocity field of the unsteady gas flow is visualized by LIC during the initial ignition of the air bag. At the bottom you
can see the box with the blasting composition, then a channel to reduce the temperature of the gas and on the top a small part of the actual air bag. This data set consists of thirteen blocks.
source: Line Integral Convolution on Triangulated Surfaces
contact: Christian Teitzel |
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Flow in a sewage purification plant visualized by LIC. The multi-block data arises out of measurement.
source: Line Integral Convolution on Triangulated Surfaces
contact: Christian Teitzel |
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Flow in a sewage purification plant visualized by LIC. The multi-block data arises out of measurement.
source: Line Integral Convolution on Triangulated Surfaces
contact: Christian Teitzel |
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Stream lines of the velocity field in a Czochralski furnace for crystal growing visualized by means of line integral convolution.
source: Line Integral Convolution on Triangulated Surfaces
contact: Christian Teitzel |
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Vector field on a sphere visualized by means of line integral convolution.
source: Line Integral Convolution on Triangulated Surfaces
contact: Christian Teitzel |