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University of Illinois at Chicago Electronic Visualization Laboratory (EVL) SuperDuperNetworking Transforming Supercomputing …from the point of view of.

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Presentation on theme: "University of Illinois at Chicago Electronic Visualization Laboratory (EVL) SuperDuperNetworking Transforming Supercomputing …from the point of view of."— Presentation transcript:

1 University of Illinois at Chicago Electronic Visualization Laboratory (EVL) SuperDuperNetworking Transforming Supercomputing …from the point of view of Large Scale Visualization and Collaborative Work Jason Leigh spiff@evl.uic.edu

2 University of Illinois at Chicago Electronic Visualization Laboratory (EVL) A Typical Data Correlation and Visualization Pipeline Data Source  Correlate/Filter  Render  Display Data Source  Render  Display Data Source  Render + Display Data Source  Correlate  Render + Display Data Source + Correlate  Render + Display Data Source + Correlate  Render  Display Things to notice: -Pipelines are static for long periods of time- NOT like web surfing- so…. -Routing is not crucial. -Program code is tiny compared to volume of data processed. Caching won’t help much- so…. -Need to stream lots of data through fast concurrent pipelines! -Need pipelines to be optimized from end to end.

3 University of Illinois at Chicago Electronic Visualization Laboratory (EVL) Experiment to Use Inexpensive Photonic Switches as an alternative to traditional million $ routers to provide application-controlled deterministic network paths/pipelines. Long haul link The cross connections are application- programmable. Calient / Glimmerglass at StarLight & EVL Protocol & data rate independent

4 University of Illinois at Chicago Electronic Visualization Laboratory (EVL) In Collaborative Work, Data or Visualization needs to be Distributed to Collaborating Sites Data Source  Correlate  Render  Display Data Source  Render + Display Data Source  Render  Display Data Source  Correlate  Render + Display Data Source + Correlate  Render + Display Data Source + Correlate  Render  Display

5 University of Illinois at Chicago Electronic Visualization Laboratory (EVL) Photonic Multicast Service Glimmerglass Reflexion Photonic Multicast-capable Switch

6 University of Illinois at Chicago Electronic Visualization Laboratory (EVL) Photonically Multicasting a Visualization Challenges: Need to augment traditional Routing and Wavelength Assignment algorithms to consider photonic multicast constraints. Need extreme speed reliable multicast protocol

7 University of Illinois at Chicago Electronic Visualization Laboratory (EVL) 1 st Step: Realize Local Area Photonic Multicasting (Visit Booth R2935 to learn how this is done on the OptIPuter)

8 University of Illinois at Chicago Electronic Visualization Laboratory (EVL) Quiz: Guess the Mystery Computer with the enormous bandwidth but tiny caches… Memory 32MB VU0 300MhZ MIPS 3 IPU DMA VU1 SIF 128bit bus Graphics Synthesizer 4MB GIF 16K cache FPU 2.4GB/s from main memory to graphics (Today’s AGP8X is at 2.1GB/s) 48GB/s! (Today’s Quadro FX3000 only has 27GB/s) Vector processors with several parallel pipelines Tiny caches For distributed, collaborative large scale data visualization, we need a version of this that extends to wide area environments.

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