片上石墨烯互连的系统级性能优化和基准测试

2012 IEEE 21st Conference on Electrical Performance of Electronic Packaging and Systems Pub Date : 2012-10-01 DOI:10.1109/EPEPS.2012.6457837

C. Pan, A. Naeemi

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引用次数: 7

摘要

本文对石墨烯互连进行了分析，并与传统铜线进行了基准测试，表明了在短导线长度或由具有大输出电阻的器件驱动时使用石墨烯的优势。首次在单核和多核芯片上对石墨烯互连进行了系统级优化。研究发现，在相同的功率密度和芯片尺寸面积下，使用石墨烯作为短互连的优化多核处理器可以分别在吞吐量和每指令能量×执行时间方面提供高达25%和55%的改进。

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System-level performance optimization and benchmarking for on-chip graphene interconnects

In this paper, graphene interconnects are analyzed and benchmarked against conventional copper wires, indicating the advantage of using graphene at a short wire length or being driven by a device with a large output resistance. For the first time, a system-level optimization of graphene interconnects is performed for both single- and multi-core chips. It is found that under the same power density and die size area, an optimized multi-core processor using graphene as short interconnects can provide up to 25% and 55% improvements in throughput and energy × execution time per instruction, respectively.

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2012 IEEE 21st Conference on Electrical Performance of Electronic Packaging and Systems

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