Predicting Total Nitrogen Concentration in Poyang Lake Using a Hybrid Network Integrating Residual and VMD-TCN-BiLSTM

doi:10.11988/ckyyb.20231425

Abstract

Abstract:

Accurately and efficiently predicting lake water quality is vital for water resource protection, ecological balance, and economic development. We propose a combined prediction model for total nitrogen (TN) concentration in lakes, integrating modal decomposition, multidimensional feature selection, Temporal Convolutional Network (TCN), self-attention mechanism, bidirectional long short-term memory (BiLSTM), and bidirectional Gate Recurrent Unit (BiGRU). First, we apply variational mode decomposition to break down the original TN sequence into intrinsic mode functions (IMFs) of different frequencies. This step effectively reduces the complexity and non-stationarity of the original sequence. Next, we use the random forest algorithm to select highly correlated features for each IMF. Then, we feed the filtered feature matrix into the TCN-BiLSTM hybrid network equipped with a self-attention mechanism for modeling. This network extracts key temporal information from the hidden data. Finally, to enhance the model’s prediction accuracy, we employ the BiGRU network to learn the detailed features of the residual sequence. We then fuse the residuals with the model’s prediction results to obtain the final prediction value. We conduct an experimental analysis using the water quality data from the Duchang Monitoring Station in Poyang Lake. The results demonstrate that, compared with other models, our model significantly improves the prediction accuracy of TN concentration. Specifically, its mean absolute error (MAE) is 0.03 mg/L, root mean square error (RMSE) is 0.049 mg/L, and coefficient of determination (R²) is 0.992.

Key words: water quality prediction, total nitrogen, variational mode decomposition, temporal convolutional network, integrated prediction

CLC Number:

TP18人工智能理论

HUANG Xue-ping, XIN Pan, WU Yong-ming, WU Liu-xing, DENG Mi, YAO Zhong. Predicting Total Nitrogen Concentration in Poyang Lake Using a Hybrid Network Integrating Residual and VMD-TCN-BiLSTM[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(3): 59-67.

Figures/Tables 16

Fig.1 Dilated causal convolution

Fig.2 Structure of BiLSTM network

Fig.3 Dot-product correlation calculation

Fig.4 Processes of model prediction

Fig.5 Structure of the hybrid network

Fig.6 TN concentration data distribution

Fig.7 VMD results

Fig.8 Heat map of RF coefficients

Table 1 Input characteristics of each IMF

模态分量	输入特征
IMF1	M(t)、WT(t)、COD_Mn(t)、NH₃-N(t)、TP(t)、TU(t)
IMF2	M(t)、COD_Mn(t)、NH₃-N(t)、TP(t)、TU(t)
IMF3	M(t)、COD_Mn(t)、NH₃-N(t)、TP(t)
IMF4	M(t)、NH₃-N(t)、TP(t)
IMF5	M(t)、NH₃-N(t)、TP(t)

Fig.9 Comparison of model performance under different time windows

Fig.10 Comparison of TN concentration prediction results among different models

Table 2 Comparison of performance with other models

预测模型	RMSE/ (mg·L^-1)	MSE/ (mg·L^-1)	MAE/ (mg·L^-1)	R²
TCN	0.249	0.062	0.219	0.794
BiLSTM	0.223	0.050	0.141	0.835
VMD-BiLSTM	0.177	0.031	0.120	0.895
VMD^*-BiLSTM	0.152	0.023	0.094	0.923
混合模型	0.128	0.017	0.088	0.945
VMD^*-混合模型	0.088	0.008	0.069	0.974

Fig.11 Residual sequences

Fig.12 ACF and PACF of residual sequences

Fig.13 Comparison of final prediction results

Table 3 Performance comparison after fusing residuals

预测模型	RMSE/ (mg·L^-1)	MSE/ (mg·L^-1)	MAE/ (mg·L^-1)	R²
VMD^*-混合模?汀肌?.088	0.008	0.069	0.974
本文最终模型	0.049	0.002	0.030	0.992

[1]	LAN Xiao-ji, HE Yong-lan, WU Shuai-wen. River Water Quality Prediction Based on RF-BiLSTM Model [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(7): 57-63.
[2]	GUO Li-jin, XU Rui-wei. Application of LSTM Model Combining Improved Fruit-Fly Algorithm after Seasonal-Trend Decomposition using LOESS to Water Quality Prediction [J]. Journal of Changjiang River Scientific Research Institute, 2023, 40(8): 57-63.
[3]	WANG Bo-quan, JIN Chuan-xin, ZHOU Lun, SHEN Di, JIANG Zhi-qiang. Water Quality Prediction for Xili Reservoir Based on Long-Short Term Memory [J]. Journal of Changjiang River Scientific Research Institute, 2023, 40(6): 64-70.
[4]	AI Sen, YANG YA-hong, XU Guang-lian, ZAI Ying-han, ZHANG Hui-ning, BAI Zhi-hui. Removal of Total Nitrogen and COD from Industrial Tail Water by Biofilm Floating Bed Strengthened with Rice Straw [J]. Journal of Changjiang River Scientific Research Institute, 2020, 37(9): 13-17.
[5]	HAN Fei, NIU Rui-qing, LI Shi-yao, ZHAO Ling-ran, BAI Xing-yu. Landslide Displacement Prediction Based on Variational ModeDecomposition and Deep Confidence Neural Network Model [J]. Journal of Changjiang River Scientific Research Institute, 2020, 37(8): 61-68.
[6]	ZHAO Li-xue, HUANG Jie-jun, CHENG Xue-jun, SHEN Shao-hong, YUAN Yan-bin. A Method of River Flow Prediction Based on VMD-BP Model [J]. Journal of Changjiang River Scientific Research Institute, 2020, 37(7): 47-52.
[7]	LUO Xue-ke, HE Yun-xiao, LIU Peng, LI Wen. Water Quality Prediction Using an ARIMA-SVR Hybrid Model [J]. Journal of Changjiang River Scientific Research Institute, 2020, 37(10): 21-27.
[8]	ZHOU Jian-zhong, PENG Tian. Chaotic Dynamic Characteristics and Integrated Prediction of Runoff in the Upper Reaches of Yangtze River [J]. Journal of Changjiang River Scientific Research Institute, 2018, 35(10): 1-9.
[9]	ZHOU Yan-chen,HU Tie-song,CHEN Jin,XU Ji-jun,ZHOU Yan-lai. Application of Neural Network Model Coupled with Dynamic Equationin Water Quality Prediction [J]. Journal of Changjiang River Scientific Research Institute, 2017, 34(9): 1-5.
[10]	LIU Jun-Wei, 吕Hui-Jin . Artificial Neural Network Applied in Water Quality Prediction [J]. Journal of Changjiang River Scientific Research Institute, 2012, 29(9): 95-97.
[11]	WANG Wen-jie , AN Li-na . Establishment and Application of 2-D Water Quality and Water Quantity Numerical Simulation Model Based on WASP5 Nitrogen Reaction Principle [J]. Journal of Changjiang River Scientific Research Institute, 2011, 28(1): 16-20.
[12]	ZHANG Shu-yu ， CHENG Hang-ping . Argumentation on Water Quality of New Water Intake in Hangzhou City [J]. Journal of Changjiang River Scientific Research Institute, 2010, 27(6): 14-17.