The Impact of Feature Representation on the Accuracy of Photonic Neural Networks

arXiv - CS - Emerging Technologies Pub Date : 2024-06-26 DOI:arxiv-2406.18757

Mauricio Gomes de Queiroz, Paul Jimenez, Raphael Cardoso, Mateus Vidaletti da Costa, Mohab Abdalla, Ian O'Connor, Alberto Bosio, Fabio Pavanello

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Abstract

Photonic Neural Networks (PNNs) are gaining significant interest in the research community due to their potential for high parallelization, low latency, and energy efficiency. PNNs compute using light, which leads to several differences in implementation when compared to electronics, such as the need to represent input features in the photonic domain before feeding them into the network. In this encoding process, it is common to combine multiple features into a single input to reduce the number of inputs and associated devices, leading to smaller and more energy-efficient PNNs. Although this alters the network's handling of input data, its impact on PNNs remains understudied. This paper addresses this open question, investigating the effect of commonly used encoding strategies that combine features on the performance and learning capabilities of PNNs. Here, using the concept of feature importance, we develop a mathematical framework for analyzing feature combination. Through this framework, we demonstrate that encoding multiple features together in a single input determines their relative importance, thus limiting the network's ability to learn from the data. Given some prior knowledge of the data, however, this can also be leveraged for higher accuracy. By selecting an optimal encoding method, we achieve up to a 12.3\% improvement in accuracy of PNNs trained on the Iris dataset compared to other encoding techniques, surpassing the performance of networks where features are not combined. These findings highlight the importance of carefully choosing the encoding to the accuracy and decision-making strategies of PNNs, particularly in size or power constrained applications.

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特征表示对光子神经网络准确性的影响

光子神经网络（Photonic Neural Networks，PNN）因其高并行性、低延迟和高能效的潜力而备受研究界关注。光子神经网络使用光进行计算，这导致其实现方式与电子技术相比存在诸多差异，例如在将输入特征输入网络之前，需要在光子域中对其进行表示。在这一编码过程中，通常将多个特征合并为一个输入，以减少输入和相关设备的数量，从而实现更小、更节能的 PNN。虽然这改变了网络对输入数据的处理，但其对 PNN 的影响仍未得到充分研究。本文针对这一开放性问题，研究了结合特征的常用编码策略对 PNN 性能和学习能力的影响。在此，我们使用 "特征重要性 "的概念，开发了一个分析特征组合的数学框架。通过这个框架，我们证明了在单个输入中将多个特征编码在一起决定了它们的相对重要性，从而限制了网络从数据中学习的能力。通过选择最佳编码方法，我们在虹膜数据集上训练的 PNN 的准确率与其他编码技术相比提高了 12.3%，超过了未进行特征组合的网络性能。这些发现凸显了谨慎选择编码对 PNN 的准确性和决策策略的重要性，尤其是在规模或功率受限的应用中。

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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arXiv - CS - Emerging Technologies

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