A High Speed Reconfigurable Gate Array for Gigahertz Applications
Authors: 
Jong-Ru Guo, Chao You, Michael Chu, Okan Erdogan, Russell P. Kraft, John F. McDonaldAuthors Info & Claims
Pages 124 - 129
Abstract
This paper describes the implementation of the next generation of a scalable SiGe FPGA in the latest IBM 8HP SiGe process (fT = 210GHz) that serves as an interleaving and de-interleaving block in a high speed reconfigurable data acquisition system. In this paper, different generations of SiGe configurable blocks (Basic Cells) are presented and measured. The latest generation has a 94% reduction in power consumption (from 71mW to 4.2mW) and an 83% reduction of the propagation delay (from 238ps to 42ps) compared to the first generation design. To demonstrate the SiGe FPGAýs capabilities of handling GHz signals, the SiGe FPGAs are configured as a multiplexer (MUX), de-multiplexer (DEMUX) and pseudo-SERDES. For the IBM 8HP process, the MUX, DEMUX andpseudo-SERDES can achieve a transmission rate of 28Gbps. For the previous IBM 7HP case, the 4:1 multiplexer runs at a transmission rate of 8Gbps. With these design results, the SiGe FPGA is able to process GHz signals such as S and K microwave bands.
References
[1]
J. F. McDonald and Bryan S. Goda, et al "Reconfigurable FPGA's in the 1-20GHz Bandwidth with HBT BiCMOS", Proceedings of the first NASA/ DoD Workshop on Evolvable Hardware, pp. 188-192.
[2]
B. S. Goda, J. F. McDonald, et al "SiGe HBT BiCMOS FPGA for fast reconfigurable systems", IEE Proc. On Computer and digital Techniques Vol. 147, No. 3, May 2000, pp. 189-194.
[3]
J.-R. Guo, C. You et al, "A Scalable 2V, 20GHz FPGA using SiGe HBT BiCMOS Technology", International Symposium on Field-Programmable Gate Arrays, 2003, pp. 145-153.
[4]
Jong-Ru Guo, et al, "A 10GHz 4:1 MUX and 1:4 DEMUX implemented by a Gigahertz SiGe FPGA for fast ADC". Elsevier, Integration, the VLSI Journal of, Vol. 38, No. 3, March 2005, pp. 525-540.
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R. Singh, David L. Harame and Modest M. Oprysko, "Silicon Germanium, Technology, Modeling, and Design", IEEE PRESS, Wiley-Interscience, 2004, pp. 4-6.
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Ken Martin, "Digital integrated circuit design", Oxford University Press Inc, pp. 334-350.
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S. Singh, J. Rose., P. Chow. and D. Lewis. "The effect of Logic Block Architecture on FPGA Performance", IEEE Journal of Solid State Circuits, Vol. 27, No. 3, March 1992, pp. 281-287.
[8]
Xilinx XC6200 FPGA data sheet.
[9]
J.-R. Guo, et al, "A 10GHz 4:1 MUX and 1:4 DEMUX implemented by a Gigahertz SiGe FPGA" GLSVLSI 2004, pp. 40-44.
[10]
T. W. Krawczyk, P. F. Curran, M. W. Ernest, et al, "SiGe HBT serial transmitter architecture for high speed variable bit rate intercomputer networking", IEE Proc.-Circuits Devices System. Vol. 151, No. 4, August 2004, pp. 315-321.
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- A High Speed Reconfigurable Gate Array for Gigahertz Applications
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Published In
May 2005
301 pages
ISBN:076952365X
Publisher
IEEE Computer Society
United States
Publication History
Published: 11 May 2005
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