基于PSO-BP神经网络模型的浸胶竹束干燥过程含水率预测

doi:10.11707/j.1001-7488.LYKX20240387

摘要/Abstract

摘要：

目的: 利用人工神经网络模型预测浸胶竹束干燥过程含水率变化，揭示干燥温度、干燥时间、铺装方式和初始含水率对浸胶竹束干燥过程含水率变化的影响规律，为浸胶竹束高质高效干燥提供参考依据。方法: 基于浸胶竹束干燥过程含水率实测数据，以干燥温度、干燥时间、铺装方式和初始含水率为输入变量，干燥过程含水率为输出变量，制作数据集。将数据集划分为训练集（308个测试数据，占总数据量的70%）、验证集（66个测试数据，占总数据量的15%）和测试集（66个测试数据，占总数据量的15%），采用粒子群优化算法（PSO）优化反向传播（BP）神经网络初始权重与阈值，构建PSO-BP神经网络预测模型，并进行验证分析。结果: PSO-BP神经网络模型具有较强的预测能力，在模型测试集中，决定系数（R²）、均方误差（MSE）、平均绝对误差（MAE）和剩余预测残差（RPD）分别达0.98、1.27、3.73和7.96。相较BP神经网络，PSO-BP神经网络的R²和RPD分别提高6.53%和110.2%，MSE和MAE分别降低54.0%和71.86%。模型验证表明，干燥温度和铺装方式是影响浸胶竹束干燥过程含水率变化的主要因素，二者对PSO-BP神经网络模型预测结果影响显著。干燥温度为60 ℃时，在4种不同铺装方式下PSO-BP神经网络模型展现出较好预测效果，其R²均超过0.969且MSE均低于3；铺装层数为3时，在4种不同干燥温度下PSO-BP神经网络模型表现最佳，其R²均超过0.99且MSE均低于2。干燥时间和浸胶竹束初始含水率对PSO-BP神经网络模型预测结果影响不显著。结论: PSO-BP神经网络模型在浸胶竹束干燥过程含水率预测中表现出准确性，可有效解决传统BP神经网络预测误差大、收敛速度慢等问题，为浸胶竹束高质高效干燥提供技术支撑。

关键词: 浸胶竹束, 干燥, 含水率, 粒子群优化算法, 反向传播, 神经网络

Abstract:

Objective: The present study utilized an artificial neural network model to forecast the moisture content variation during the drying process of phenolic resin impregnated heat-treated bamboo bundles (PHB), elucidating the impact of drying temperature, drying time, paving method, and initial moisture content on the moisture variation during the drying process. The findings provide a fundamental reference for achieving high-quality and efficient drying of PHB. Method: The measured data of moisture content during the drying process of PHB samples was utilized to create a dataset, with input variables including drying temperature, drying time, paving method, and initial moisture content. The output variable was the moisture content during the drying process. Subsequently, this dataset was divided into three sets: the training set, consisting of 308 data points (70% of the total data); the validation set, comprising 66 data points (15% of the total data); and the test set, containing 66 data points (15% of the total data). The particle swarm optimization (PSO) algorithm was employed to optimize the initial weights and thresholds of back propagation ropagation (BP) neural network, thereby constructing a PSO-BP neural network prediction model. This model has been verified and analyzed. Result: The PSO-BP neural network model exhibited robust predictive capabilities. In the test set, it achieved a coefficient of determination (R²) of 0.98, a mean square error (MSE) of 1.27, a mean absolute error (MAE) of 3.73, and a residual predictive deviation (RPD) of 7.96. Compared to the BP neural network, the PSO-BP neural network demonstrated an improvement in R² and RPD by 6.53% and 110.2%, respectively, while reducing MSE and MAE by 54.0% and 71.86%. The model verification demonstrated that the moisture content variation during the drying process of PHB was primarily influenced by the drying temperature and paving method. Both factors have a significant impact on the predictive accuracy of the PSO-BP neural network model. Optimal prediction performance was achieved when using a drying temperature of 60 ℃, regardless of the four different paving methods employed, resulting in R² values exceeding 0.969 and MSE staying below 3. Employing three layers of paving yielded superior outcomes under various drying temperature conditions, with R² values surpassing 0.99 and MSE remaining below 2. Additionally, neither drying time nor initial moisture content significantly affected the predictive accuracy of the model. Conclusion: The PSO-BP neural network model exhibited remarkable accuracy in predicting the moisture content during the drying process of PHB samples. It effectively addresses issues such as significant prediction errors and slow convergence rates that are commonly encountered with traditional BP neural networks, thereby providing valuable technical support for the high-quality and efficient drying of PHB.

Key words: phenolic resin impregnated heat-treated bamboo bundles (PHB), drying, moisture content, particle swarm optimization (PSO) algorithm, back propagation (BP), neural network

中图分类号:

王晓曼,吕建雄,李贤军,吴义强,李新功,郝晓峰,乔建政,徐康. 基于PSO-BP神经网络模型的浸胶竹束干燥过程含水率预测[J]. 林业科学, 2025, 61(5): 187-198.

Xiaoman Wang,Jianxiong Lü,Xianjun Li,Yiqiang Wu,Xingong Li,Xiaofeng Hao,Jianzheng Qiao,Kang Xu. Prediction of Moisture Content during Drying of Phenolic Resin Impregnated Heat-Treated Bamboo Bundles Based on PSO-BP Neural Network Modeling[J]. Scientia Silvae Sinicae, 2025, 61(5): 187-198.

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组别 Groups	线性回归方程 Linear regression equation		相关系数Correlation coefficient (R)
组别 Groups	BP	PSO-BP	BP	PSO-BP
训练集Training set	Y=0.93T+0.001 2	Y=0.98T+0.003 7	0.964	0.992
验证集Validation set	Y=0.89T+0.006 2	Y=0.95T+0.015 0	0.942	0.976
测试集Test set	Y=0.95T+0.019 0	Y=0.98T+0.010 0	0.975	0.989
总数据集All data set	Y=0.92T+0.023 0	Y=0.98T+0.006 2	0.964	0.988

组别 Groups	R²	MAE	MSE	RPD
BP	0.92	2.76 1.27	13.26 3.73	3.69
PSO-BP	0.98	2.76 1.27	13.26 3.73	7.97

编号 Number	干燥温度 Drying temperature/℃	铺装方式 Paving method	R²	MSE
1	50	P₁	0.990	1.26
2		P₃	0.994	0.53
3		P₆	0.967	1.19
4		P₁₂	0.958	2.92
5	60	P₁	0.994	1.14
6		P₃	0.992	1.16
7		P₆	0.969	2.58
8		P₁₂	0.969	2.59
9	70	P₁	0.950	3.24
10		P₃	0.998	0.08
11		P₆	0.992	0.55
12		P₁₂	0.993	1.71
13	80	P₁	0.944	3.78
14		P₃	0.996	0.52
15		P₆	0.973	2.18
16		P₁₂	0.961	2.27

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