Prediction of air pollutant concentrations based on TCN-BiLSTM-DMAttention with STL decomposition

Li, Wenlin; Jiang, Xuchu

doi:10.1038/s41598-023-31569-w

Cited by 12 publications

(9 citation statements)

References 25 publications

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“…the ozone concentration model is represented exclusively as a function of time as a relevant factor without considering meteorological factors, the decomposition methods have shown great performance, since in this investigation the significant models (p < 0.05; R 2 max: 0.949) with errors less than 20% (RMSE, RMSPE, MAE, MAPE) showed great performance. These errors have been comparable to other STL decomposition studies that used root mean square error (RMSE: 6.8%) and mean absolute percentage error (MAPE: 10.49%) as benchmarks for forecast reliability for ozone [10]. This evaluation of tropospheric ozone explains its long-term and seasonal behavior with temporary ozone patterns [41], in accordance with what was demonstrated by Carbo-Bustinza [23] for the winter months in these geographic areas.…”

Section: Discussionsupporting

confidence: 85%

“…For its part, the second component, "seasonality", describes the fluctuations of the periodic seasons (decomposed), and the third, fixed by a short-term component, shows the "rest" of the random data once the first two components have been separated. In addition, other combined decomposition methods or structures have been proposed in series and time convolution and long-term short-memory bidirectional networks [10]. Other models use a non-parametric Theil-Sen estimator as a robust Kendall [11] line-fit method or locally estimated scatterplot models for smoothing to filter the data obtained and subsequently decompose the time series models into trend, seasonal, and residual components of data and then recombine them appropriately [12].…”

Section: Introductionmentioning

confidence: 99%

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Short-Term Forecasting of Ozone Concentration in Metropolitan Lima Using Hybrid Combinations of Time Series Models

Carbo-Bustinza,

Iftikhar,

Belmonte

et al. 2023

Applied Sciences

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In the modern era, air pollution is one of the most harmful environmental issues on the local, regional, and global stages. Its negative impacts go far beyond ecosystems and the economy, harming human health and environmental sustainability. Given these facts, efficient and accurate modeling and forecasting for the concentration of ozone are vital. Thus, this study explores an in-depth analysis of forecasting the concentration of ozone by comparing many hybrid combinations of time series models. To this end, in the first phase, the hourly ozone time series is decomposed into three new sub-series, including the long-term trend, the seasonal trend, and the stochastic series, by applying the seasonal trend decomposition method. In the second phase, we forecast every sub-series with three popular time series models and all their combinations In the final phase, the results of each sub-series forecast are combined to achieve the results of the final forecast. The proposed hybrid time series forecasting models were applied to four Metropolitan Lima monitoring stations—ATE, Campo de Marte, San Borja, and Santa Anita—for the years 2017, 2018, and 2019 in the winter season. Thus, the combinations of the considered time series models generated 27 combinations for each sampling station. They demonstrated significant forecasts of the sample based on highly accurate and efficient descriptive, statistical, and graphic analysis tests, as a lower mean error occurred in the optimized forecast models compared to baseline models. The most effective hybrid models for the ATE, Campo de Marte, San Borja, and Santa Anita stations were identified based on their superior out-of-sample forecast results, as measured by RMSE (4.611, 3.637, 1.495, and 1.969), RMSPE (4.464, 11.846, 1.864, and 15.924), MAE (1.711, 2.356, 1.078, and 1.462), and MAPE (14.862, 20.441, 7.668, and 76.261) errors. These models significantly outperformed other models due to their lower error values. In addition, the best models are statistically significant (p < 0.05) and superior to the rest of the combination models. Furthermore, the final proposed models show significant performance with the least mean error, which is comparatively better than the considered baseline models. Finally, the authors also recommend using the proposed hybrid time series combination forecasting models to predict ozone concentrations in other districts of Lima and other parts of Peru.

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Section: Discussionsupporting

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Short-Term Forecasting of Ozone Concentration in Metropolitan Lima Using Hybrid Combinations of Time Series Models

Carbo-Bustinza,

Iftikhar,

Belmonte

et al. 2023

Applied Sciences

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“…For complex multivariable systems, it is difficult to establish an accurate dynamic model for simple conventional networks due to the absence of feature extraction or memory function. − The LSTM network and TCN network have unique advantages in modeling time series data with long-term dependence because of their long-term memory and feature extraction capabilities . The LSTM network is a variant of the recurrent neural network (RNNS) to solve the problems of gradient disappearance and gradient explosion when processing long sequences .…”

Section: Introductionmentioning

confidence: 99%

“… 18 − 20 The LSTM network and TCN network have unique advantages in modeling time series data with long-term dependence because of their long-term memory and feature extraction capabilities. 21 The LSTM network is a variant of the recurrent neural network (RNNS) to solve the problems of gradient disappearance and gradient explosion when processing long sequences. 22 The LSTM network introduces memory cells and a number of gating units to selectively remember or ignore information from input data and transfer information in time.…”

Section: Introductionmentioning

confidence: 99%

Multivariable System Prediction Based on TCN-LSTM Networks with Self-Attention Mechanism and LASSO Variable Selection

Shao,

Tang,

Liu

et al. 2023

ACS Omega

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Intelligent prediction of key output variables that are difficult to measure online in complex systems has important research significance. In this paper, by using the least absolute shrinkage and selection operator (LASSO) algorithm to analyze the principal elements of input variables, a temporal convolutional network fused with long short-term memory (TCN-LSTM) network and self-attention mechanism (SAM) is designed to realize dynamic modeling of multivariate feature sequences. For complex processes with multiple input variables, each variable has different effects on the output, so it is necessary to use the LASSO algorithm to perform regression analysis on the input and output data for selecting the principal component variables and reducing the redundancy and computation burden of the network. The TCN network is used to extract the features of the input variables efficiently. The long-term memory performance of time series is enhanced by applying an LSTM network. The multihead SAM is used to optimize the network, and the role of key features is enhanced by assigning weights with probability to further improve the accuracy of sequence prediction. Finally, by comparison with the existing network model, the offline data generated by the high and low converters in the synthetic ammonia industry is used to predict the CO content so as to verify the superiority and applicability of the proposed network model.

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“…Chen and Liang 14 combined the empirical modal decomposition method (EMD), attention mechanism, and BiLSTM neural network to predict the daily longitudinal flow at the Qingxi River site in Xuanhan County, obtaining accurate results that met prediction requirements. Regarding the study of bidirectional long short-term memory neural networks, Li and Jiang 15 used STL for sequence decomposition, temporal convolution, a bidirectional long short-term memory network (TCN-BiLSTM) for feature leaning the decomposed series, and interdependent moment feature emphasisation using DMAttention to predict the concentration of air pollutants, achieving accurate prediction accuracy. Sathi et al 16 used a CNN-BiLSTM model to predict the attention to the induced electric field of a transcranial magnetic stimulation coil with similarly excellent results.Current research on monthly runoff prediction models, both domestically and internationally, mainly focuses on coupling optimization algorithms with neural networks to improve prediction accuracy by constructing coupled models.…”

Section: Introductionmentioning

confidence: 99%

Monthly runoff prediction based on a coupled VMD-SSA-BiLSTM model

Zhang

Wang

et al. 2023

Sci Rep

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The accurate prediction of monthly runoff in the lower reaches of the Yellow River is crucial for the rational utilization of regional water resources, optimal allocation, and flood prevention. This study proposes a VMD-SSA-BiLSTM coupled model for monthly runoff volume prediction, which combines the advantages of Variational Modal Decomposition (VMD) for signal decomposition and preprocessing, Sparrow Search Algorithm (SSA) for BiLSTM model parameter optimization, and Bi-directional Long and Short-Term Memory Neural Network (BiLSTM) for exploiting the bi-directional linkage and advanced characteristics of the runoff process. The proposed model was applied to predict monthly runoff at GaoCun hydrological station in the lower Yellow River. The results demonstrate that the VMD-SSA-BiLSTM model outperforms both the BiLSTM model and the VMD-BiLSTM model in terms of prediction accuracy during both the training and validation periods. The Root-mean-square deviation of VMD-SSA-BiLSTM model is 30.6601, which is 242.5124 and 39.9835 lower compared to the BiLSTM model and the VMD-BiLSTM model respectively; the mean absolute percentage error is 5.6832%, which is 35.5937% and 6.3856% lower compared to the other two models, respectively; the mean absolute error was 19.8992, which decreased by 136.7288 and 25.7274 respectively; the square of the correlation coefficient (R2) is 0.93775, which increases by 0.53059 and 0.14739 respectively; the Nash–Sutcliffe efficiency coefficient was 0.9886, which increased by 0.4994 and 0.1122 respectively. In conclusion, the proposed VMD-SSA-BiLSTM model, utilizing the sparrow search algorithm and bidirectional long and short-term memory neural network, enhances the smoothness of the monthly runoff series and improves the accuracy of point predictions. This model holds promise for the effective prediction of monthly runoff in the lower Yellow River.

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Prediction of air pollutant concentrations based on TCN-BiLSTM-DMAttention with STL decomposition

Cited by 12 publications

References 25 publications

Short-Term Forecasting of Ozone Concentration in Metropolitan Lima Using Hybrid Combinations of Time Series Models

Short-Term Forecasting of Ozone Concentration in Metropolitan Lima Using Hybrid Combinations of Time Series Models

Multivariable System Prediction Based on TCN-LSTM Networks with Self-Attention Mechanism and LASSO Variable Selection

Monthly runoff prediction based on a coupled VMD-SSA-BiLSTM model

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