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Coal Identification Based on Reflection Spectroscopy and Deep Learning: Paving the Way for Efficient Coal Combustion

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This study introduces a new deep learning method for rapid coal identification using reflection spectroscopy. The RS_PSOTELM model achieves 98.3% accuracy, enabling efficient coal sorting and processing.

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Area of Science:

  • Geoscience
  • Materials Science
  • Artificial Intelligence

Background:

  • Coal is a critical global energy source, requiring accurate identification for efficient utilization in mining, combustion, and pyrolysis.
  • Current coal identification methods may lack the speed and accuracy needed for dynamic industrial processes.
  • Optimizing coal energy conversion relies on precise classification based on its type and properties.

Purpose of the Study:

  • To develop a rapid and accurate coal identification approach using deep learning and reflection spectroscopy.
  • To create a novel model, RS_PSOTELM, integrating convolutional neural networks (CNN) and extreme learning machines (ELM) for spectral data analysis.
  • To enhance the model's performance through particle swarm optimization (PSO) for parameter tuning.

Main Methods:

  • Field collection and preprocessing of spectral data from diverse coal samples.
  • Development of the RS_PSOTELM model: CNN for feature extraction and ELM for classification.
  • Optimization of ELM parameters using particle swarm optimization (PSO) to improve identification accuracy.

Main Results:

  • The RS_PSOTELM model demonstrated a high accuracy of 98.3% in coal identification tasks.
  • The approach proved capable of quick and precise identification of different coal categories.
  • Successful extraction of effective spectral features and accurate classification were achieved.

Conclusions:

  • The proposed RS_PSOTELM method offers a low-cost, efficient, and reliable solution for coal identification.
  • This technique supports optimized coal utilization in mining, combustion, and pyrolysis stages.
  • The study paves the way for enhanced energy conversion efficiency through advanced coal classification.