Adekunle A. Adeleke , Adeyinka Adedigba , Steve A. Adeshina , Peter P. Ikubanni , Mohammed S. Lawal , Adebayo I. Olosho , Halima S. Yakubu , Temitayo S. Ogedengbe , Petrus Nzerem , Jude A. Okolie
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Up to 200 datasets were compiled from literature and used for the ML models. Our results demonstrate the effectiveness of all ML models in accurately predicting the HHV of biomass materials. Notably, the XGBoost model exhibited superior performance with the highest R-squared (R<sup>2</sup>) values for both training (0.9683) and test datasets (0.7309), along with the lowest root mean squared error (RSME) of 0.3558. Key influential input features identified for HHV prediction include carbon (C), volatile matter (Vm), ash, and hydrogen (H). 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引用次数: 0
摘要
本研究解决了有效测定生物质高热值(HHV)的难题,这是大规模生物质能源系统中的一个关键参数。使用氧弹热量计测量 HHV 的传统方法耗时长、成本高,而且研究人员较难获得,尤其是在发展中国家。为了克服这些局限性,我们采用了四种机器学习(ML)模型,即随机森林(RF)、决策树(DT)、支持向量机(SVM)和极梯度提升(XGBoost)。这些模型是利用近似和最终分析参数作为输入特征而开发的。我们从文献中汇编了多达 200 个数据集,并将其用于 ML 模型。结果表明,所有 ML 模型在准确预测生物质材料的 HHV 方面都非常有效。值得注意的是,XGBoost 模型表现出卓越的性能,在训练数据集(0.9683)和测试数据集(0.7309)上的 R 平方(R2)值最高,均方根误差(RSME)最低,为 0.3558。对 HHV 预测有影响的关键输入特征包括碳(C)、挥发性物质(Vm)、灰分和氢(H)。因此,这项研究为预测 HHV 提供了一种可靠的替代方法,无需进行昂贵且耗时的实验测量,从而为生物质能源研究提供了更广泛的可能性。
Comparative studies of machine learning models for predicting higher heating values of biomass
This study addresses the challenge of efficiently determining the higher heating value (HHV) of biomass, a crucial parameter in large-scale biomass-based energy systems. The conventional method of measuring HHV using an oxygen bomb calorimeter is time-consuming, expensive, and less accessible to researchers, particularly in developing nations. To overcome these limitations, we employed four machine learning (ML) models, namely Random Forest (RF), Decision Tree (DT), Support Vector Machine (SVM), and Extreme Gradient Boosting (XGBoost). These models were developed by using proximate and ultimate analysis parameters as input features. Up to 200 datasets were compiled from literature and used for the ML models. Our results demonstrate the effectiveness of all ML models in accurately predicting the HHV of biomass materials. Notably, the XGBoost model exhibited superior performance with the highest R-squared (R2) values for both training (0.9683) and test datasets (0.7309), along with the lowest root mean squared error (RSME) of 0.3558. Key influential input features identified for HHV prediction include carbon (C), volatile matter (Vm), ash, and hydrogen (H). Consequently, this research provides a reliable alternative for predicting HHV without the need for costly and time-intensive experimental measurements, facilitating broader accessibility in biomass energy research.
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