改进气体光谱合成数据训练的人工神经网络的性能——两种传感方法的研究

IF 0.8 4区 工程技术 Q4 INSTRUMENTS & INSTRUMENTATION Tm-Technisches Messen Pub Date : 2023-08-09 DOI:10.1515/teme-2023-0051
J. Goldschmidt, Elisabeth Moser, L. Nitzsche, Rudolf Bierl, J. Wöllenstein
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引用次数: 0

摘要

摘要将人工神经网络(ann)应用于定量红外气体光谱中,预测多组分吸收光谱上的浓度。人工神经网络的训练需要大量的标记训练数据,这些数据可能非常复杂且耗时。利用合成生成的光谱可以获得额外的数据,但代价是与测量数据的系统偏差。在这里,我们提出了两种方法,结合相对较小的测量数据集和合成生成的数据来训练人工神经网络。对于第一种方法,将合成的N2O和CO混合物的红外吸收光谱与中红外双梳状光谱仪测量的零气体光谱混合训练神经网络。这提高了网络预测的平均绝对误差(MAE),分别从0.46到0.01 ppmV和0.24到0.01 ppmV,分别用于零气体测量的N2O和CO浓度预测,这是以前在纯合成数据训练中观察到的。同时,在0 ~ 100 ppmV N2O和0 ~ 60 ppmV CO的混合气体中也获得了类似的光谱性能。对于第二种方法,在丙酮和乙醇混合物的合成红外光谱上预训练的人工神经网络在由中红外光声光谱仪拍摄的26个光谱组成的小数据集上重新训练。在这种情况下,与纯合成训练相比,乙醇和丙酮浓度预测的MAE分别提高了45% %和20% %。这表明利用合成生成的数据与少量测量数据相结合来训练人工神经网络的能力,以进一步改善用于气体传感的神经网络以及不同传感方法之间的可移植性。
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Improving the performance of artificial neural networks trained on synthetic data in gas spectroscopy – a study on two sensing approaches
Abstract Artificial neural networks (ANNs) are used in quantitative infrared gas spectroscopy to predict concentrations on multi-component absorption spectra. Training of ANNs requires vast amounts of labelled training data which may be elaborate and time consuming to obtain. Additional data can be gained by the utilization of synthetically generated spectra, but at the cost of systematic deviations to measured data. Here, we present two approaches to train ANNs with a combination of comparatively small, measured data sets and synthetically generated data. For the first approach a neural network is trained hybridly with synthetically generated infrared absorption spectra of mixtures of N2O and CO and measured zero-gas spectra, taken with a mid-infrared dual comb spectrometer. This improves the mean absolute error (MAE) of the network predictions from 0.46 to 0.01 ppmV and 0.24 to 0.01 ppmV for the concentration predictions of N2O and CO respectively for zero-gas measurements which was previously observed for training with purely synthetic data. At the same time a similar performance on spectra from gas mixtures of 0–100 ppmV N2O and 0 to 60 ppmV CO was achieved. For the second approach an ANN pre-trained on synthetic infrared spectra of mixtures of acetone and ethanol is retrained on a small dataset consisting of 26 spectra taken with a mid-infrared photoacoustic spectrometer. In this case the MAE for the concentration predictions of ethanol and acetone are improved by 45 % and 20 % in comparison to purely synthetic training. This shows the capability of using synthetically generated data to train ANNs in combination with small amounts of measured data to further improve neural networks for gas sensing and the transferability between different sensing approaches.
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来源期刊
Tm-Technisches Messen
Tm-Technisches Messen 工程技术-仪器仪表
CiteScore
1.70
自引率
20.00%
发文量
105
审稿时长
6-12 weeks
期刊介绍: The journal promotes dialogue between the developers of application-oriented sensors, measurement systems, and measurement methods and the manufacturers and measurement technologists who use them. Topics The manufacture and characteristics of new sensors for measurement technology in the industrial sector New measurement methods Hardware and software based processing and analysis of measurement signals to obtain measurement values The outcomes of employing new measurement systems and methods.
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