On-chip high performance signaling using passive compensation

2008 IEEE International Conference on Computer Design Pub Date : 2008-10-01 DOI:10.1109/ICCD.2008.4751859

Yulei Zhang, Ling Zhang, A. Tsuchiya, M. Hashimoto, Chung-Kuan Cheng

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引用次数: 3

Abstract

To address the performance limitation brought by the scaling issues of on-chip global wires, a new configuration for global wiring using on-chip lossy transmission lines(T-lines) is proposed and optimized in this paper. Firstly, we use passive compensation and repeated transceivers composed by sense amplifier and inverter chain to compensate the distortion and attenuation of on-chip T-lines. Secondly, an optimization flow for designing this scheme based on eye-diagram prediction and sequential quadratic programming (SQP) is proposed. This flow is employed to study the latency, power dissipation and throughput performance of the new global wiring scheme as the technology scales from 90nm to 22nm. Compared with conventional repeater insertion methods, our experimental results demonstrate that, at 22nm technology node, this new scheme reduces the normalized delay by 85.1%, the normalized energy consumption by 98.8%. Furthermore, all the performance metrics are scalable as the technology advances, which makes this new signaling scheme a potential candidate to break the “interconnect wall” of digital system performance.

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采用无源补偿的片上高性能信号

为了解决片上全局布线的缩放问题带来的性能限制，本文提出了一种使用片上损耗传输线(t线)的全局布线新配置，并对其进行了优化。首先，我们采用由感测放大器和逆变链组成的无源补偿和重复收发器来补偿片上t线的失真和衰减。其次，提出了基于眼图预测和序列二次规划(SQP)的方案优化设计流程;该流程用于研究新全局布线方案在技术从90nm扩展到22nm时的延迟、功耗和吞吐量性能。实验结果表明，与传统的中继器插入方法相比，在22nm技术节点上，新方案将归一化延迟降低85.1%，归一化能耗降低98.8%。此外，随着技术的进步，所有的性能指标都是可扩展的，这使得这种新的信令方案成为打破数字系统性能“互连墙”的潜在候选者。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2008 IEEE International Conference on Computer Design

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