On-chip Parallel Photonic Reservoir Computing using Multiple Delay Lines

2020 IEEE 32nd International Symposium on Computer Architecture and High Performance Computing (SBAC-PAD) Pub Date : 2020-09-01 DOI:10.1109/SBAC-PAD49847.2020.00015

S. Hasnain, R. Mahapatra

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引用次数: 2

Abstract

Silicon-Photonics architectures have enabled high speed hardware implementations of Reservoir Computing (RC). With a delayed feedback reservoir (DFR) model, only one non-linear node can be used to perform RC. However, the delay is often provided by using off-chip fiber optics which is not only space inconvenient but it also becomes architectural bottleneck and hinders to scalability. In this paper, we propose a completely on-chip photonic RC architecture for high performance computing, employing multiple electronically tunable delay lines and micro-ring resonator (MRR) switch for multi-tasking. Proposed architecture provides 84% less error compared to the state-of-the-art standalone architecture in [8] for executing NARMA task. For multi-tasking, the proposed architecture shows 80% better performance than [8]. The architecture outperforms all other proposed architectures as well. The on-chip area and power overhead of proposed architecture due to delay lines and MRR switch are 0.0184mm^2 and 26mW respectively.

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基于多延迟线的片上并行光子库计算

硅光子学架构使水库计算(RC)的高速硬件实现成为可能。对于延迟反馈水库(DFR)模型，只有一个非线性节点可以进行RC。然而，通常使用片外光纤提供延迟，不仅空间不便，而且成为架构瓶颈，阻碍了可扩展性。在本文中，我们提出了一个完整的片上光子RC架构，用于高性能计算，采用多条电子可调谐延迟线和微环谐振器(MRR)开关进行多任务处理。与[8]中最先进的独立体系结构相比，所提出的体系结构在执行NARMA任务时提供的错误减少了84%。对于多任务处理，该架构的性能比[8]提高了80%。该体系结构也优于所有其他提出的体系结构。由于延迟线和MRR开关造成的片上面积和功耗开销分别为0.0184mm^2和26mW。

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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来源期刊

2020 IEEE 32nd International Symposium on Computer Architecture and High Performance Computing (SBAC-PAD)

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