解决片上纳米光子网络中的系统级微调问题

2011 IEEE 17th International Symposium on High Performance Computer Architecture Pub Date : 2011-02-12 DOI:10.1109/HPCA.2011.5749722

C. Nitta, M. Farrens, V. Akella

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引用次数: 86

摘要

片上纳米光子互连的基本组成部分是微环谐振器[14]，这些谐振器会由于温度的变化而改变其谐振波长——这个问题可以通过一种叫做“微调”的技术来解决，这种技术包括通过加热和/或电流注入来纠正漂移。到目前为止，系统研究人员已经将修剪建模为每个环的固定成本。在这项工作中，我们表明，在系统层面上使用固定成本模型是不合适的-我们的模拟表明，加热成本与环的数量具有非线性关系，并且电流注入可能导致热失控。我们表明，为了使网络按预期工作，必须保持非常窄的温度控制窗口(TCW)。然而，通过利用同位环的群漂移特性，可以创建一个可以增加TCW的滑动窗口方案。我们还表明，部分非热环可以缓解但不能消除问题。

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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Addressing system-level trimming issues in on-chip nanophotonic networks

The basic building block of on-chip nanophotonic interconnects is the microring resonator [14], and these resonators change their resonant wavelengths due to variations in temperature — a problem that can be addressed using a technique called ”trimming”, which involves correcting the drift via heating and/or current injection. Thus far system researchers have modeled trimming as a per ring fixed cost. In this work we show that at the system level using a fixed cost model is inappropriate — our simulations demonstrate that the cost of heating has a non-linear relationship with the number of rings, and also that current injection can lead to thermal runaway. We show that a very narrow Temperature Control Window (TCW) must be maintained in order for the network to work as desired. However, by exploiting the group drift property of co-located rings, it is possible to create a sliding window scheme which can increase the TCW. We also show that partially athermal rings can alleviate but not eliminate the problem.

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2011 IEEE 17th International Symposium on High Performance Computer Architecture

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