When Convolutional Neural Networks Meet Laser-Induced Breakdown Spectroscopy: End-to-End Quantitative Analysis Modeling of ChemCam Spectral Data for Major Elements Based on Ensemble Convolutional Neural Networks

Remote. Sens. Pub Date : 2023-07-06 DOI:10.3390/rs15133422
Yan Yu, Meibao Yao
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Abstract

Modeling the quantitative relationship between target components and measured spectral information is an essential part of laser-induced breakdown spectroscopy (LIBS) analysis. However, many traditional multivariate analysis algorithms must reduce the spectral dimension or extract the characteristic spectral lines in advance, which may result in information loss and reduced accuracy. Indeed, improving the precision and interpretability of LIBS quantitative analysis is a critical challenge in Mars exploration. To solve this problem, this paper proposes an end-to-end lightweight quantitative modeling framework based on ensemble convolutional neural networks (ECNNs). This method eliminates the need for dimensionality reduction of the raw spectrum along with other pre-processing operations. We used the ChemCam calibration dataset as an example to verify the effectiveness of the proposed approach. Compared with partial least squares regression (a linear method) and extreme learning machine (a nonlinear method), our proposed method resulted in a lower root-mean-square error for major element prediction (54% and 73% lower, respectively) and was more stable. We also delved into the internal learning mechanism of the deep CNN model to understand how it hierarchically extracts spectral information features. The experimental results demonstrate that the easy-to-use ECNN-based regression model achieves excellent prediction performance while maintaining interpretability.
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当卷积神经网络满足激光诱导击穿光谱:基于集成卷积神经网络的ChemCam主要元素光谱数据的端到端定量分析建模
建立目标组分与被测光谱信息之间的定量关系是激光诱导击穿光谱(LIBS)分析的重要组成部分。然而,许多传统的多变量分析算法必须降低光谱维数或提前提取特征光谱线,这可能导致信息丢失,降低精度。事实上,提高LIBS定量分析的精度和可解释性是火星探测的关键挑战。为了解决这一问题,本文提出了一种基于集成卷积神经网络(ecnn)的端到端轻量级定量建模框架。该方法消除了对原始光谱进行降维和其他预处理操作的需要。以ChemCam标定数据集为例,验证了该方法的有效性。与偏最小二乘回归(一种线性方法)和极限学习机(一种非线性方法)相比,我们提出的方法对主要元素预测的均方根误差更低(分别降低54%和73%),并且更稳定。我们还深入研究了深度CNN模型的内部学习机制,以了解它是如何分层提取光谱信息特征的。实验结果表明,基于ecnn的简单易用的回归模型在保持可解释性的同时取得了良好的预测性能。
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