HEX: scaling honeycombs is easier than scaling clock trees

Proceedings of the twenty-fifth annual ACM symposium on Parallelism in algorithms and architectures Pub Date : 2013-07-23 DOI:10.1145/2486159.2486192

D. Dolev, Matthias Függer, C. Lenzen, Martin Perner, U. Schmid

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引用次数: 12

Abstract

We argue that grid structures are a very promising alternative to the standard approach for distributing a clock signal throughout VLSI circuits and other hardware devices. Traditionally, this is accomplished by a delay-balanced clock tree, which distributes the signal supplied by a single clock source via carefully engineered and buffered signal paths. Our approach, termed HEX, is based on a hexagonal grid with simple intermediate nodes, which both control the forwarding of clock ticks in the grid and supply them to nearby functional units. HEX is Byzantine fault-tolerant, in a way that scales with the grid size, self-stabilizing, and seamlessly integrates with multiple synchronized clock sources, as used in multi-synchronous Globally Synchronous Locally Asynchronous (GALS) architectures. Moreover, HEX guarantees a small clock skew between neighbors even for wire delays that are only moderately balanced. We provide both a theoretical analysis of the worst-case skew and simulation results that demonstrate very small typical skew in realistic runs.

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十六进制:缩放蜂窝比缩放时钟树更容易

我们认为网格结构是一种非常有前途的替代标准方法，用于在VLSI电路和其他硬件设备中分配时钟信号。传统上，这是由延迟平衡时钟树完成的，它通过精心设计和缓冲的信号路径分配单个时钟源提供的信号。我们的方法称为HEX，它基于具有简单中间节点的六边形网格，这些节点既控制网格中时钟节拍的转发，又将其提供给附近的功能单元。HEX是拜占庭式的容错性，在某种程度上可以随网格大小而扩展，自稳定，并与多个同步时钟源无缝集成，就像在多同步全局同步本地异步(GALS)架构中使用的那样。此外，HEX保证邻居之间的时钟偏差很小，即使电线延迟只是适度平衡。我们提供了最坏情况偏差的理论分析和仿真结果，证明了在实际运行中非常小的典型偏差。

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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Proceedings of the twenty-fifth annual ACM symposium on Parallelism in algorithms and architectures

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