A Hybrid Opto-Electrical Floating-point Multiplier

2022 IEEE 15th International Symposium on Embedded Multicore/Many-core Systems-on-Chip (MCSoC) Pub Date : 2022-12-01 DOI:10.1109/MCSoC57363.2022.00057

Takumi Inaba, Takatsugu Ono, Koji Inoue, Satoshi Kawakami

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Abstract

The performance improvement by CMOS circuit technology is reaching its limits. Many researchers have been studying computing technologies that use emerging devices to challenge such critical issues. Nanophotonic technology is a promising candidate due to its ultra-low latency, high bandwidth, and low power natures. The advanced research activity of nanophotonic computing is to design hardware accelerators for AI inference applications. However, few considerations about nanophotonic accelerators for AI training applications have been conducted. The main reason is that state-of-the-art nanophotonic AI accelerators involve integer operations, whereas floating-point (FP) sum-of-products dominate the training process. However, to the best of the authors' knowledge, there are no optical circuits that target floating-point arithmetic units. This study proposes a novel Opto-Electrical Floating-point Multiplier (OEFM) toward ultra-low-latency, a power-efficient nanophotonic accelerator for AI training applications. We design a microarchitecture of OEFM, including a novel optical integer multiplier and other electrical components. Based on our evaluation framework, we analyze the calculation accuracy of the proposed multiplier and OEFM. Experimental results show that OEFM achieves a 56 % reduction in latency and a 41 % reduction in energy consumption compared with a conventional electrical circuit.

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一种混合光电浮点乘法器

CMOS电路技术的性能提升已经达到极限。许多研究人员一直在研究使用新兴设备来挑战这些关键问题的计算技术。纳米光子技术由于其超低延迟、高带宽和低功耗的特性，是一个很有前途的候选技术。纳米光子计算的前沿研究活动是设计用于人工智能推理应用的硬件加速器。然而，纳米光子加速器在人工智能训练中的应用却很少。主要原因是最先进的纳米光子人工智能加速器涉及整数运算，而浮点(FP)乘积和在训练过程中占主导地位。然而，据作者所知，目前还没有针对浮点算术单位的光学电路。本研究提出了一种面向超低延迟的新型光电浮点乘法器(OEFM)，一种用于人工智能训练应用的节能纳米光子加速器。我们设计了一个OEFM的微架构，包括一个新型的光学整数乘法器和其他电子元件。基于我们的评估框架，我们分析了所提乘数和OEFM的计算精度。实验结果表明，与传统电路相比，OEFM的延迟降低了56%，能耗降低了41%。

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

2022 IEEE 15th International Symposium on Embedded Multicore/Many-core Systems-on-Chip (MCSoC)

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