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引用次数: 14
摘要
作为快速衰落的global - synchronous模型的替代品,我们为soc定义了一种灵活的设计风格,称为GRLS,用于global - ratiochronous, local - synchronous,它不依赖于全局同步,而是基于使用来自同一源的合理相关时钟频率。本文利用理性相关系统的特殊周期特性,基于在接收端使用两个时钟边采样数据的思想,构建了一种延迟不敏感、最大吞吐量、低开销的通信方法。本文正式证明了该方法的有效性及其对抖动、失调和时钟漂移等非理想情况的抵抗能力,并给出了包括开销在内的90 nm技术的实验结果。尽管允许更大的灵活性,但我们的方法的开销与最先进的中同步通信技术相当。我们还展示了迄今为止针对合理相关时钟频率提出的所有其他方法在性能、复杂性和开销方面的改进。
A flexible communication scheme for rationally-related clock frequencies
As a replacement for the fast-fading Globally-Synchronous model, we have defined a flexible design style for SoCs, called GRLS, for Globally-Ratiochronous, Locally-Synchronous, which does not rely on global synchronization and is based on using rationally-related clock frequencies derived from the same source. In this paper, using the special periodical properties of rationally-related systems, we build a latency-insensitive, maximal-throughput, low-overhead communication method, based on the idea of using both clock edges to sample data at the Receiver. The validity of the method and its resistance to non-idealities such as jitter, misalignments and clock drifts are formally proven while experimental results including overhead are presented for 90 nm technology. Despite allowing much greater flexibility, the overhead of our method is comparable to that of state-of-the-art mesochronous communication techniques. We also show performances, complexity and overhead improvements over all other approaches that have so far been proposed for rationally-related clock frequencies.
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