A compiled accelerator for biological cell signaling simulations

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A compiled accelerator for biological cell signaling simulations

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International Symposium on Field Programmable Gate Arrays archive
Proceedings of the 2004 ACM/SIGDA 12th international symposium on Field programmable gate arrays table of contents

Monterey, California, USA

SESSION: Applications II table of contents

Pages: 233 - 241

Year of Publication: 2004

ISBN:1-58113-829-6

Authors

John F. Keane	University of Washington, Seattle, WA
Christopher Bradley	University of Washington, Seattle, WA
Carl Ebeling	University of Washington, Seattle, WA

Sponsors

SIGDA: ACM Special Interest Group on Design Automation
ACM: Association for Computing Machinery

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 2, Downloads (12 Months): 29, Citation Count: 9

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ABSTRACT

The simulation of large systems of biochemical reactions is a key part of research into molecular signaling and information processing in biological cells. However, it can be impractical because many relevant reactions are modeled as stochastic, discrete event processes, and the complexity of the computing task scales with the number of discrete events in a simulation. Traditionally, such simulations are computed on general purpose CPUs, and sometimes in networks of such processors. We show that an alternative algorithm to the conventional approaches based on the Gillespie algorithm reveals a fine-grained parallel structure that is amenable to realization in FPGA hardware. A method is shown for compiling biochemical reaction systems into corresponding Verilog descriptions of simulators that employ this alternative algorithm. We describe a preliminary implementation of such a compiled accelerator that demonstrates the performance of this approach, achieving an initial performance that is 20 times faster than a competing general purpose CPU.

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.

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	Zhi Guo , Betul Buyukkurt , Walid Najjar , Kees Vissers, Optimized Generation of Data-Path from C Codes for FPGAs, Proceedings of the conference on Design, Automation and Test in Europe, p.112-117, March 07-11, 2005
	Roman Lysecky, Scalability and parallel execution of warp processing: dynamic hardware/software partitioning, International Journal of Parallel Programming, v.36 n.5, p.478-492, October 2008
	Roman Lysecky, Low-power warp processor for power efficient high-performance embedded systems, Proceedings of the conference on Design, automation and test in Europe, April 16-20, 2007, Nice, France
	Lance Saldanha , Roman Lysecky, Hardware/software partitioning of floating point software applications to fixed-pointed coprocessor circuits, Proceedings of the 6th IEEE/ACM/IFIP international conference on Hardware/Software codesign and system synthesis, October 19-24, 2008, Atlanta, GA, USA
	Yoshiki Yamaguchi , Tsutomu Maruyama , Ryuzo Azuma , Moritoshi Yasunaga , Akihiko Konagaya, Mesoscopic-level Simulation of Dynamics and Interactions of Biological Molecules Using Monte Carlo Simulation, Journal of VLSI Signal Processing Systems, v.48 n.3, p.287-299, September 2007
	Ajay Nair , Roman Lysecky, Non-intrusive dynamic application profiler for detailed loop execution characterization, Proceedings of the 2008 international conference on Compilers, architectures and synthesis for embedded systems, October 19-24, 2008, Atlanta, GA, USA
	Zhi Guo , Walid Najjar , Betul Buyukkurt, Efficient hardware code generation for FPGAs, ACM Transactions on Architecture and Code Optimization (TACO), v.5 n.1, p.1-26, May 2008
	Roman Lysecky , Greg Stitt , Frank Vahid, Warp Processors, ACM Transactions on Design Automation of Electronic Systems (TODAES), v.11 n.3, p.659-681, July 2006