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Electronic visualization laboratory, university of illinois at chicago Visualizing Very Large Scale Earthquake Simulations (SC 2003) K.L.Ma, UC-Davis.

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Presentation on theme: "Electronic visualization laboratory, university of illinois at chicago Visualizing Very Large Scale Earthquake Simulations (SC 2003) K.L.Ma, UC-Davis."— Presentation transcript:

1 electronic visualization laboratory, university of illinois at chicago Visualizing Very Large Scale Earthquake Simulations (SC 2003) K.L.Ma, UC-Davis

2 electronic visualization laboratory, university of illinois at chicago Summary A parallel rendering algorithm is presented to visualize a 3D seismic propagation (time varying data) of Northridge earthquake (highest resolution vol viz of an earthquake simulation to date) Issues dealt with: –Large data –Time varying data –Unstructured grid

3 electronic visualization laboratory, university of illinois at chicago Main strategies used Interleaving load distribution Overlapping communication and computation Avoiding per time step processing Buffering intermediate results to amortize communication overheads Compression A parallel cell projection algorithm is used which requires no connectivity between adjacent cells unlike ray tracing (for visualizing unstructured data)

4 electronic visualization laboratory, university of illinois at chicago Parallel Rendering An octree based representation of the volume is used at multiple resolutions The appropriate data resolution is used to match image resolution Projection data is scattered to the nodes to eliminate nodes that are not viewed The data block size is made coarse enough for faster traversal The loading of blocks from disk and rendering are overlapped.

5 electronic visualization laboratory, university of illinois at chicago Parallel Image Composition SLIC (Scheduled Linear Image Compositing) Pixels are classified as background (ignored), non- overlapping (sent directly to final processor) and 1, 2, 3 overlapping etc (figure 4) Compositing is scheduled according to overlap The overlapping calculation has to be redone when view point changes (scheduling for composition is also recalculated)

6 electronic visualization laboratory, university of illinois at chicago Results, References Test results should low compositing cost in most cases but after n=32, the parallel algorithm is inefficient due to load imbalance Papers to look at: –survey of visualization of time varying data –binary swap –communication costs of parallel volume rendering algorithms –SLIC

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