Improving functional density through run-time constant propagation

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Improving functional density through run-time constant propagation

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International Symposium on Field Programmable Gate Arrays archive
Proceedings of the 1997 ACM fifth international symposium on Field-programmable gate arrays table of contents

Monterey, California, United States

Pages 86-92

Year of Publication: 1997

ISBN:0-89791-801-0

Authors

Michael J. Wirthlin	Department of Electrical and Computer Engineering, Brigham Young University, Provo, UT
Brad L. Hutchings	Department of Electrical and Computer Engineering, Brigham Young University, Provo, UT

Sponsor

SIGDA: ACM Special Interest Group on Design Automation

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 1, Downloads (12 Months): 14, Citation Count: 9

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ABSTRACT

Circuit specialization techniques such as constant propagation are commonly used to reduce both the hardware resources and cycle time of digital circuits. When reconfigurable FPGAs are used, these advantages can be extended by dynamically specializing circuits using run-time reconfiguration (RTR). For systems exploiting constant propagation, hardware resources can be reduced by folding constants within the circuit and dynamically changing the constants using circuit reconfiguration. To measure the benefits of circuit specialization, a functional density metric is presented. This metric allows the analysis of both static and run-time reconfigured circuits by including the cost of circuit reconfiguration. This metric will be used to justify runtime constant propagation as well as analyze the effects of reconfiguration time on run-time reconfigured systems.

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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CITED BY 9

	Hea Joung Kim , William H. Mangione-Smith, Factoring large numbers with programmable hardware, Proceedings of the 2000 ACM/SIGDA eighth international symposium on Field programmable gate arrays, p.41-48, February 10-11, 2000, Monterey, California, United States
	Paul Graham , Brent Nelson, FPGA-based sonar processing, Proceedings of the 1998 ACM/SIGDA sixth international symposium on Field programmable gate arrays, p.201-208, February 22-25, 1998, Monterey, California, United States
	Kong Woei Susanto , Tom Melham, Formally Analyzed Dynamic Synthesis of Hardware, The Journal of Supercomputing, v.19 n.1, p.7-22, May 2001
	Alireza Shoa , Shahram Shirani, Run-time reconfigurable systems for digital signal processing applications: a survey, Journal of VLSI Signal Processing Systems, v.39 n.3, p.213-235, March 2005
	Katherine Compton , Scott Hauck, Reconfigurable computing: a survey of systems and software, ACM Computing Surveys (CSUR), v.34 n.2, p.171-210, June 2002
	Leandro Möller , Rafael Soares , Ewerson Carvalho , Ismael Grehs , Ney Calazans , Fernando Moraes, Infrastructure for dynamic reconfigurable systems: choices and trade-offs, Proceedings of the 19th annual symposium on Integrated circuits and systems design, August 28-September 01, 2006, Ouro Preto, MG, Brazil
	Krishna N. Vikram , Vinita Vasudevan, Mapping data-parallel tasks onto partially reconfigurable hybrid processor architectures, IEEE Transactions on Very Large Scale Integration (VLSI) Systems, v.14 n.9, p.1010-1023, September 2006
	Alireza Shoa , Shahram Shirani, Run-Time Reconfigurable Systems for Digital Signal Processing Applications: A Survey, Journal of VLSI Signal Processing Systems, v.39 n.3, p.213-235, March 2005
	N. Shirazi , D. Benyamin , W. Luk , P. Y. K. Cheung , S. Guo, Quantitative Analysis of FPGA-based Database Searching, Journal of VLSI Signal Processing Systems, v.28 n.1-2, p.85-96, May-June 2001