Spatially-resolved Thermometry from Line-of-Sight Emission Spectroscopy via Machine Learning

TL;DR

This paper introduces a data-driven approach combining feature engineering and machine learning to achieve spatially resolved temperature measurements from line-of-sight emission spectroscopy data, overcoming traditional limitations.

Contribution

It demonstrates that feature engineering with classical machine learning outperforms CNNs in spatial thermometry, providing a practical method for nonuniform temperature field measurement.

Findings

Feature engineering improves temperature prediction accuracy.

Ensemble learning with light blender yields best performance.

Method effectively measures temperature distributions with unknown species concentration.

Abstract

A methodology is proposed, which addresses the caveat that line-of-sight emission spectroscopy presents in that it cannot provide spatially resolved temperature measurements in nonhomogeneous temperature fields. The aim of this research is to explore the use of data-driven models in measuring temperature distributions in a spatially resolved manner using emission spectroscopy data. Two categories of data-driven methods are analyzed: (i) Feature engineering and classical machine learning algorithms, and (ii) end-to-end convolutional neural networks (CNN). In total, combinations of fifteen feature groups and fifteen classical machine learning models, and eleven CNN models are considered and their performances explored. The results indicate that the combination of feature engineering and machine learning provides better performance than the direct use of CNN. Notably, feature engineering which is comprised of physics-guided transformation, signal representation-based feature extraction and Principal Component Analysis is found to be the most effective. Moreover, it is shown that when using the extracted features, the ensemble-based, light blender learning model offers the best performance with RMSE, RE, RRMSE and R values of 64.3, 0.017, 0.025 and 0.994, respectively. The proposed method, based on feature engineering and the light blender model, is capable of measuring nonuniform temperature distributions from low-resolution spectra, even when the species concentration distribution in the gas mixtures is unknown.