Issue 17, 2024

Application of S-transform-based nonlinear processing for accurate LIBS quantitative analysis of iron ore slurry

Abstract

Real-time Fe content monitoring in iron ore slurry is crucial for evaluating concentrate quality and enhancing mineral processing efficiency. Laser-induced breakdown spectroscopy (LIBS) is a promising technique for the online monitoring of elemental content at industrial sites. However, LIBS measurements are hampered by the matrix effect and the self-absorption effect, limiting the precision of linear analytical processes. To overcome this, we propose to introduce a nonlinear processing unit based on the S-transform to incorporate nonlinearity into the data analysis process. This approach integrates a feature selection unit based on the spectral distance variable selection method (SDVS), a nonlinear processing unit based on the S-transform (ST), and a partial least squares regression model (PLS). To demonstrate the improvement in accuracy achieved through nonlinear processing, a comparative analysis involving five models, Raw-PLS, SDVS-PLS, ST-PLS, SDVS-ANN, and SDVS-ST-PLS, is conducted. The results reveal a significant improvement in the performance of the SDVS-ST-PLS model, effectively facilitating the successful application of the LIBSlurry analyzer to the mineral flotation process.

Graphical abstract: Application of S-transform-based nonlinear processing for accurate LIBS quantitative analysis of iron ore slurry

Article information

Article type
Paper
Submitted
30 Apr 2024
Accepted
04 Jul 2024
First published
05 Jul 2024

Analyst, 2024,149, 4407-4417

Application of S-transform-based nonlinear processing for accurate LIBS quantitative analysis of iron ore slurry

T. Chen, L. Sun, H. Yu, L. Qi, P. Zhang and H. Dong, Analyst, 2024, 149, 4407 DOI: 10.1039/D4AN00631C

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