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基于ConvGRU深度学习网络模型的PM2.5浓度预测
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Abstract:
针对于大气污染输送对PM2.5浓度预测影响的问题,本文以珠江三角洲作为研究区域,采用珠江三角洲PM2.5小时浓度数据作为研究数据,基于卷积操作和GRU模型构建了一种能够同时考虑时间依赖特征和空间特征的ConvGRU模型。并使用ConvGRU模型预测了珠海市PM2.5小时浓度,结果表明:ConvGRU模型预测PM2.5浓度和真实PM2.5浓度相关系数高达0.83,均方误差(MSE)、平均绝对误差(MAE)、平均绝对百分比误差(MAPR)、均方根误差(RMSE)均显著小于SVM和RF和ConvLSTM、LSTM和GRU。
In response to the issue of predicting the impact of atmospheric pollution transport on PM2.5 con-centrations, this paper takes the Pearl River Delta as the research area. Hourly PM2.5 concentration data from the Pearl River Delta were used as the research dataset. A ConvGRU model, which com-bines convolutional operations and GRU (Gated Recurrent Unit), was developed to account for both temporal dependencies and spatial features. The ConvGRU model was employed to predict the hourly PM2.5 concentrations in Zhuhai. The results showed that the ConvGRU model achieved a high correlation coefficient of 0.83 between the predicted PM2.5 concentrations and the actual values. Moreover, it outperformed other models such as SVM, RF, ConvLSTM, LSTM, and GRU, with signifi-cantly lower values of mean squared error (MSE), mean absolute error (MAE), mean absolute per-centage error (MAPR), and root mean squared error (RMSE).
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