A novel fault-tolerant router architecture for network-on-chip reconfiguration

2015 28th IEEE International System-on-Chip Conference (SOCC) Pub Date : 2015-09-01 DOI:10.1109/SOCC.2015.7406966

P. Yan, Shixiong Jiang, R. Sridhar

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引用次数: 8

Abstract

In Network-on-Chip (NoC) architectures, a faulty router can isolate a functional processing element (PE) from other nodes, severely restricting the performance of the system. This paper presents a fault-tolerant router architecture that can avoid PE isolation even if the router fails. In this design, we connect the local port of the router with one of the other four ports through a fault tolerant control unit that works with the fault detection signal. If the router fails, the control unit will turn on and connect the PE with the neighboring router directly, thus protecting the system functioning. A revised XY-Routing algorithm is also presented to achieve the NoC reconfiguration when router fails. Theoretical analysis show that for a 10*10 mesh NoC, the reliability at year 10 is 20 times better than NoC implemented with traditional router. Also our design has greatly improved value for mean time to failure (MTTF). In video and DSP applications, simulation results show better power control with faulty PEs. The new architecture also has other advantages over annealing re-mapping algorithm. Our design has only 12% area overhead, which is significantly better than other approaches to deal with faults.

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一种基于片上网络重构的容错路由器结构

在片上网络(NoC)架构中，出现故障的路由器可能会将功能处理单元(PE)与其他节点隔离开来，从而严重限制系统的性能。本文提出了一种容错路由器结构，即使路由器发生故障也能避免PE隔离。在本设计中，我们通过容错控制单元将路由器的本地端口与其他四个端口中的一个连接起来，容错控制单元与故障检测信号一起工作。当路由器发生故障时，控制单元开启，PE直接与相邻路由器连接，保护系统正常运行。提出了一种改进的XY-Routing算法，实现了路由器故障时NoC的重新配置。理论分析表明，对于10*10 mesh NoC, 10年的可靠性是传统路由器NoC的20倍。此外，我们的设计大大提高了平均无故障时间(MTTF)的价值。在视频和DSP应用中，仿真结果表明故障pe具有较好的功率控制效果。与退火重映射算法相比，新架构还具有其他优点。我们的设计只有12%的面积开销，这明显优于其他处理故障的方法。

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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2015 28th IEEE International System-on-Chip Conference (SOCC)

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