Statistical physics approaches for network-on-chip traffic characterization

International Conference on Hardware/Software Codesign and System Synthesis Pub Date : 2009-10-11 DOI:10.1145/1629435.1629498

P. Bogdan, R. Marculescu

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引用次数: 62

Abstract

In order to face the growing complexity of embedded applications, we aim to build highly efficient Network-on-Chip (NoC) architectures which can connect in a scalable manner various computational modules of the platform. For such networked platforms, it is increasingly important to accurately model the traffic characteristics as this is intimately related to our ability to determine the optimal buffer size at various routers in the network and thus provide analytical metrics for various power-performance trade-offs. In this paper, we show that the main limitations of queueing theory and Markov chain approaches to solving the buffer sizing problem can be overcome by adopting a statistical physics approach to probability density characterization which incorporates the power law distribution, correlations, and scaling properties exhibited within an NoC architecture due to various network transactions. As experimental results show, this new approach represents a breakthrough in accurate traffic modeling under non-equilibrium conditions. As such, our results can be directly used to solve the buffer sizing problem for multiprocessor systems where communication happens via the NoC approach.

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片上网络流量表征的统计物理方法

为了应对日益复杂的嵌入式应用，我们的目标是构建高效的片上网络(NoC)架构，该架构可以以可扩展的方式连接平台的各种计算模块。对于这样的网络平台，准确地建模流量特征变得越来越重要，因为这与我们确定网络中各种路由器的最佳缓冲区大小的能力密切相关，从而为各种功率性能权衡提供分析指标。在本文中，我们展示了排队理论和马尔可夫链方法解决缓冲区大小问题的主要局限性，可以通过采用统计物理方法进行概率密度表征来克服，该方法结合了幂律分布、相关性和在NoC架构中由于各种网络事务而表现出的缩放特性。实验结果表明，该方法在非平衡条件下的精确交通建模方面取得了突破。因此，我们的结果可以直接用于解决通过NoC方法进行通信的多处理器系统的缓冲区大小问题。

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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International Conference on Hardware/Software Codesign and System Synthesis

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