基于卷积神经网络改进宽带发射烟灰热测量

A. Rodríguez, J. Portilla, J. J. Cruz, F. Escudero, R. Demarco, A. Fuentes, G. Carvajal
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引用次数: 2

摘要

宽带发射(BEMI)高温法是一种低成本的技术,用于间接表征实验室火焰中的烟灰温度场,使用RGB相机捕获图像。然而,通过经典的反卷积技术从彩色图像中获取温度需要解决不适定逆问题,产生的结果对信号噪声和正则化参数的选择高度敏感。本文提出利用卷积神经网络(cnn)提高典型轴对称层流火焰图像估计二维烟灰温度场的精度。利用火焰温度场的物理模拟图像数据集及其在相机平面上相应的卷积投影,我们训练CNN来学习参考温度与测量信号之间的关系。在模拟和实验图像上的实验表明,训练后的CNN在从噪声图像中检索温度时优于经典的反演方法,特别是在火焰中心等感兴趣的区域。对噪声的弹性使cnn对使用不同质量的设备实施低成本的煤烟热测量技术具有吸引力。
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Improving Broadband Emission-Based Soot Pyrometry Using Convolutional Neural Networks
Broadband Emission (BEMI) pyrometry is a low-cost technique for indirect characterization of soot temperature fields in laboratory flames using images captured with an RGB camera. However, retrieving temperature from color images through classical deconvolution techniques requires solving ill-posed inverse problems, producing results that are highly sensitive to signal noise and the choice of regularization parameters. This paper proposes using Convolutional Neural Networks (CNNs) to improve the accuracy of estimated 2D soot temperature fields from images of canonical axisymmetric laminar flames. Using a dataset of physically-grounded simulated images of temperature fields in the flame and their corresponding convoluted projections in the camera plane, we trained a CNN to learn the relationship between the reference temperature and the measured signals. Experiments over simulated and experimental images show that the trained CNN outperforms classical inversion methods when retrieving temperature from noisy images, especially in areas of interest such as the center of the flame. Resilience to noise makes CNNs attractive for implementing low-cost techniques for soot pyrometry using equipment of different quality.
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