作为机器学习实现的光子延迟系统

J. Mach. Learn. Res. Pub Date : 2015-01-12 DOI:10.5555/2789272.2886817

Michiel Hermans, M. C. Soriano, J. Dambre, P. Bienstman, Ingo Fischer

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引用次数: 43

摘要

非线性光子延迟系统为机器学习模型提供了有趣的实现平台。它们可以非常快，提供高度的并行性，并且可能比数字处理器消耗更少的功率。到目前为止，它们已经成功地用于使用油藏计算范式进行信号处理。在本文中，我们证明了如果我们在系统的模型上使用随时间反向传播的梯度下降来优化这类系统的输入编码，则可以大大扩展它们的适用范围。我们进行了物理实验，证明了所获得的输入编码在现实中工作得很好，并且我们表明优化系统的性能明显优于普通的油藏计算方法。本文给出的结果表明，来自机器学习的常见梯度下降技术可能很好地适用于物理神经启发的模拟计算机。

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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Photonic delay systems as machine learning implementations

Nonlinear photonic delay systems present interesting implementation platforms for machine learning models. They can be extremely fast, offer great degrees of parallelism and potentially consume far less power than digital processors. So far they have been successfully employed for signal processing using the Reservoir Computing paradigm. In this paper we show that their range of applicability can be greatly extended if we use gradient descent with backpropagation through time on a model of the system to optimize the input encoding of such systems. We perform physical experiments that demonstrate that the obtained input encodings work well in reality, and we show that optimized systems perform significantly better than the common Reservoir Computing approach. The results presented here demonstrate that common gradient descent techniques from machine learning may well be applicable on physical neuro-inspired analog computers.

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J. Mach. Learn. Res.

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