Neural network modeling of bismuth-doped fiber amplifier

IF 1.9 4区 物理与天体物理 Q3 OPTICS Journal of the European Optical Society-Rapid Publications Pub Date : 2022-12-06 DOI:10.1051/jeos/2022016
A. Donodin, E. Manuylovich, V. Dvoyrin, Francesco Da Ros, A. Carena, D. Zibar, W. Forysiak, S. Turitsyn, Ann Margareth Rosa Brusin, Uiara Celine de Moura
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引用次数: 1

Abstract

Bismuth-doped fiber amplifiers offer an attractive solution for meeting continuously growing enormous demand on the bandwidth of modern communication systems. However, practical deployment of such amplifiers require massive development and optimization efforts with the numerical modeling being the core design tool. The numerical optimization of bismuth-doped fiber amplifiers is challenging due to a large number of unknown parameters in the conventional rate equations models. We propose here a new approach to develop a bismuth-doped fiber amplifier model based on a neural network purely trained with experimental data sets in E- and S-bands. This method allows a robust prediction of the amplifier operation that incorporates variations of fiber properties due to manufacturing process and any fluctuations of the amplifier characteristics. Using the proposed approach the spectral dependencies of gain and noise figure for given bi-directional pump currents and input signal powers have been obtained. The low mean (less than 0.19 dB) and standard deviation (less than 0.09 dB) of the maximum error are achieved for gain and noise figure predictions in the 1410-1490 nm spectral band.
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掺铋光纤放大器的神经网络建模
掺铋光纤放大器为满足现代通信系统对带宽不断增长的巨大需求提供了一种有吸引力的解决方案。然而,这种放大器的实际部署需要大量的开发和优化工作,而数值建模是核心设计工具。由于传统速率方程模型中存在大量未知参数,掺铋光纤放大器的数值优化具有挑战性。我们在这里提出了一种新的方法来开发基于纯用E波段和S波段的实验数据集训练的神经网络的掺铋光纤放大器模型。该方法允许对放大器操作进行稳健的预测,其中包括由于制造过程和放大器特性的任何波动而引起的光纤特性的变化。使用所提出的方法,获得了给定双向泵浦电流和输入信号功率的增益和噪声系数的频谱相关性。对于1410-1490nm谱带中的增益和噪声系数预测,实现了最大误差的低平均值(小于0.19dB)和标准偏差(小于0.09dB)。
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来源期刊
CiteScore
2.40
自引率
0.00%
发文量
12
审稿时长
5 weeks
期刊介绍: Rapid progress in optics and photonics has broadened its application enormously into many branches, including information and communication technology, security, sensing, bio- and medical sciences, healthcare and chemistry. Recent achievements in other sciences have allowed continual discovery of new natural mysteries and formulation of challenging goals for optics that require further development of modern concepts and running fundamental research. The Journal of the European Optical Society – Rapid Publications (JEOS:RP) aims to tackle all of the aforementioned points in the form of prompt, scientific, high-quality communications that report on the latest findings. It presents emerging technologies and outlining strategic goals in optics and photonics. The journal covers both fundamental and applied topics, including but not limited to: Classical and quantum optics Light/matter interaction Optical communication Micro- and nanooptics Nonlinear optical phenomena Optical materials Optical metrology Optical spectroscopy Colour research Nano and metamaterials Modern photonics technology Optical engineering, design and instrumentation Optical applications in bio-physics and medicine Interdisciplinary fields using photonics, such as in energy, climate change and cultural heritage The journal aims to provide readers with recent and important achievements in optics/photonics and, as its name suggests, it strives for the shortest possible publication time.
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