1. The Access Grid at Vislab Chris Willing chris@vislab.usyd.edu.au Vislab University of Sydney, Australia.

2. Today Background Differences to “traditional” vc Vislab Implementation – ATP Vislab Implementation – Physics Virtual Venues Differences to ANL implementation Future Work

3. Background VISLAB – visualisation, high perf. Computing Labs at Physics, ATP Bernard Pailthorpe at SDSC in 2000 –High resolution displays –AG node Start April 2001 for SCGlobal, November 2001

4. Hyogo Prefecture (Japan) Police Command Center - reference site Tiled rear projection array of 6 Model 200 ILA Projectors

5. SmartSpaces, Stanford Courtesy of Pat Hanrahan, CS - Stanford

6. PowerWall, Princeton Courtesy of Kai Li, CS - Princeton 8x commodity projectors

7. High Density Tiled Display, SDSC 3x3 array with common light source http://vis.sdsc.edu/research/tileddisplay.html

8. (Background) VISLAB – visualisation, high perf. Computing Labs at Physics, ATP Bernard Pailthorpe at SDSC in 2000 –High resolution displays –AG node Start April 2001 for SCGlobal, November 2001

9. Display, VisLab 2001 3x1 array, 3840x1024 pixels, single light source

10. Application in archaeology: Angkor

11. (Today) Background Differences to “traditional” vc Vislab Implementation – ATP Vislab Implementation – Physics Virtual Venues Differences to ANL implementation Future Work

12. Differences – 1. traditional Each node sends image stream(s) to MCU which decides what is output to each node TV style

13. Differences – 2. access grid Each node sends image streams to a multicast group address Each node sees all other sources

14. but if “Each node sees all other sources” then screen overload e.g. 10 other sites, each with 3 cameras => 30 video streams

15. Normal screen First Access Grid session at USyd on 29 Aug, 2001

16. Widescreen 5120x1024 Normal screen 1280x1024

17. Summary of Differences limited vs. rich user experience complex (studio) vs. simple (pc) proprietary vs. open expensive vs. cheap but richness requires pixels

18. Technology diversion 1 Unicast 3 streams to 7 sites = 21 video streams

19. Efficient but who pays? Multicast 3 streams to 7 sites = 3 streams (mostly)

20. Today Background Differences to “traditional” vc Vislab Implementation – ATP Vislab Implementation – Physics Virtual Venues Differences to ANL implementation Future Work

21. Vislab Implementation (ATP) display video audio Gentner cameras mics PA projectors (monitor)

22. Access Grid Sydney Preparing for SC-Global: test “cruises” + A/G-Sydney

23. ATP display Mon. display network Projected display 3840x1024

24. ATP video capture video network table screen mon. camera projectors

25. ATP audio capture Gentner Rx audio network 1x Radio mic 2x PZM mon. PA

26. Gentner – echo control Site ASite B echo delay due to - distance - application buffering

27. Vislab Implementation (Physics) Mon. network Projected display 2560x1024 2x cameras Polycom Soundstation 1x video

28. Virtual Venues ANL runs Virtual Venues Server APAG server at http://venues.ap-accessgrid.orghttp://venues.ap-accessgrid.org Virtual rooms characterised by facilities –Video multicast group address –Audio multicast group address –MUD location (back channel link for participants)

29. Linux only –stability –sync with vvd (not CORBA event handler) –potential for compute clustering (openMosix) Graphics cards (nVidia Quadro4) –use “well known” visualisation apps e.g. performer, openInventor, openDX –potential for video clustering (chromium) Differences to ANL

30. Video clustered AG display video audio Gentner cameras 1 mics PA 2 3 monitorprojectors

31. Performer with AG

32. High Resolution with AG

33. Future Video clustering, stereo viewing Shared event stream Higher resolution (PAL, HDTV) –H263, hardware MJPEG External machine capture Coexistence with H323 (via VRVS)

34. Links http://www.vislab.usyd.edu.au/research/accessgrid/ http://www.vislab.usyd.edu.au/research/display/ http://www.accessgrid.org http://www.scglobal.org http://vis.sdsc.edu/research/tileddisplay.html