Architectural mechanisms to support three-dimensional lattice gas simulations

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Architectural mechanisms to support three-dimensional lattice gas simulations

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ACM Symposium on Parallel Algorithms and Architectures archive
Proceedings of the third annual ACM symposium on Parallel algorithms and architectures table of contents

Hilton Head, South Carolina, United States

Pages: 115 - 122

Year of Publication: 1991

ISBN:0-89791-438-4

Authors

Fung F. Lee	Computer Systems Laboratory, Stanford University, CA
Michael J. Flynn	Computer Systems Laboratory, Stanford University, CA

Sponsors

SIGACT: ACM Special Interest Group on Algorithms and Computation Theory
SIGARCH: ACM Special Interest Group on Computer Architecture

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 2, Downloads (12 Months): 12, Citation Count: 0

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REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	Andre Clouqueur and Dominique d'Humi~res. R.A.P., A Family of Cellular Automaton Machines for Fluid Dynamics. Helvetica Physica Acla, 62:525-541, 1989.
	2	Dominique d'Humi~res and Pierre Lallemand. Numerical Simulations of Hydrodynamics with Lattice Gas Automata in Two Dimensions. Complex Systems, 1(4):599-632, August 1987.
	3	K. Diemer, K. Hunt, S. Chen, T. Shimomura, and G.Doolen. Density and velocity dependence of reynolds numbers for several lattice gas models. Latlice Gas Methods for Partial Differential Equations, pages 137-177, 1990.
	4	Gray D. Doolen, editor. Lattice Gas Methods for Partial Differential Equations, volume IV of Santa Fe Instilute Studies in the Sciences of Complexity. Addison-Wesley, 1990.
	5	Uriel Frisch, Dominique d'Humi~res, Brosl Hasslacher, Pierre Lallemand, Yves Pomeau, and Jean-Pierre Rivet. Lattice Gas Hydrodynamics in Two and Three Dimensions. Complex Systems, 1(4):649-707, 1987.
	6	Michel H~non. Isometric Collision Rules for the Four-Dimensional FCHC Lattice Gas. Complex Systems, 1(3):475-494, June 1987.
	7	Steven Kugelmass, Architectures for two-dimensional lattice computations with linear speedup, Princeton University, Princeton, NJ, 1988
	8	Fung F. Lee , Michael J. Flynn , Martin Morf, A VLSI architecture for the FCHC isometric lattice gas model, Stanford University, Stanford, CA, 1990
	9	Fung F. Lee, Michael j. Flynn, and Martin Morf. Design of Compact High Performance Processing Elements for the FCHC Lattice Gas Models. Proceedings of the Fifth SIAM Conference on Parallel Processing for Scientific Computing, March 1991.
	10	Norman Margolus and Tommaso Toffoli. Cellular Automata Machines. Lattice Gas Methods for Partial Differential Equations, pages 219-249, 1990.
	11	Jean-Pierre Rivet, Michel tI@non, Uriel Frisch, and Dominique d'Humi~res. Simulating Fully Three-Dimensional External Flow by Lattice Gas Methods. Proceedings of the Workshop on Discrete Kinetic Theory, Lattice Gas Dynamics and Foundalions of Hydrodynamics, pages 276-285, September 1988.
	12	Tommaso Toffoli , Norman Margolus, Cellular automata machines: a new environment for modeling, MIT Press, Cambridge, MA, 1987