基于便携式近红外光谱与MTFD-Unet的煤炭挥发分与发热量协同预测

doi:10. 11799/ ce202512028

摘要/Abstract

摘要：

便携式近红外光谱在煤质分析中因谱峰重叠、变量高度相关及采样条件敏感等问题,常导致建模精度与稳定性不足。针对该问题，提出了一种基于多任务特征解耦U型网络的煤炭挥发分与发热量协同预测方法。该方法首先通过迭代剔除异常样本和标准正态变换提升数据质量，再利用Unet网络提取共享特征，并引入特征解耦模块分离任务专有信息，从而兼顾指标的关联性与特异性。基于600个煤样的实验结果表明，模型对挥发分与发热量预测的相关系数分别达到0.8086和0.8584，预测精度与稳定性显著优于多种基准模型，并在噪声干扰下保持良好鲁棒性，为煤炭多指标的便携式快速在线检测提供了一条高效、精准且适应性强的技术路径。

关键词: 近红外光谱技术, 煤质快检, 深度学习, 多任务学习

Abstract:

Traditional coal quality analysis methods are often characterized by cumbersome procedures, long testing cycles, and high resource consumption, making them inadequate for the demands of modern energy systems in terms of efficient utilization and safety assurance. Portable near-infrared (NIR) spectroscopy, with advantages such as rapid, non-destructive, and on-line detection, has broad application prospects in coal quality analysis. However, issues such as spectral peak overlap, high inter-variable correlation, and sensitivity to sampling conditions still limit modeling accuracy and stability. This paper proposes a multi-task feature decoupling U-shaped network based on portable NIR spectroscopy for the collaborative prediction of coal volatile matter and calorific value. First, an iterative outlier elimination strategy is developed using the Rairda criterion and Euclidean distance to enhance the reliability of modeling data. Second, various spectral preprocessing methods are compared, verifying the superiority of standard normal variate transformation in suppressing baseline drift and scattering effects. Next, a Unet-based shared-parameter module with an encoder–decoder architecture and skip connections is employed to efficiently extract shared features. Finally, a multi-task feature decoupling module is introduced, where orthogonal constraints and auxiliary prediction heads jointly optimize the separation of task-specific features while maintaining both inter-index correlation and specificity. Experimental results on 600 coal samples show that the proposed model achieves a root mean square error (RMSE) of 1.4255, mean absolute error (MAE) of 0.9600, and correlation coefficient (R) of 0.8086 for volatile matter prediction, and an RMSE of 1.2954, MAE of 0.9320, and R of 0.8584 for calorific value prediction—significantly outperforming various traditional machine learning and deep learning models. Furthermore, noise interference experiments confirm the model’s robustness and generalization capability under complex sampling conditions. This study provides an efficient, accurate, and highly adaptable technical approach for portable, multi-index, on-line coal quality detection.

中图分类号:

TP274

张晓艳, 左玉昊, 罗汇丰, 王　宁, 邹　亮. 基于便携式近红外光谱与MTFD-Unet的煤炭挥发分与发热量协同预测[J]. 煤炭工程, 2025, 57(12): 218-227.

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