[1] Yang Mian, Wang Yin. Spatial-temporal characteristics of PM2.5 and its influencing factors in the Yangtze River Economic Belt[J].China Population Resources and Environment, 2017, 27(1): 91-100.

[2] Jiang Yuncong, Yang Yuanjian, Wang Hong, et al. Urban-rural differences in PM2.5 concentrations in the representative cities of China during 2015~2018[J]. China Environmental Science, 2019, 39(11): 4552-4560.

[3] Liu Shengdong, Shi junnan, Cheng Yong, et al. Review of pollution characteristics of PM2.5 in Chinese representative megacities[J]. Environmental Science Research, 2020, 33(2): 243-251.

[4] Yao Xuefeng, Ge Baozhu, Zheng Haitao, et al. Spatiotemporal distribution characteristics of PM2.5 concentration and its main control factors in China based on multivariate data analysis[J]. Climatic and Environmental Research, 2018, 23(5): 596-606.

[5] Wei Chunxuan, Huang He, Zhai Zhenfang, et al. Analysis of meteorological elements and forecast method of haze day in Hefei, China[J]. Journal of Atmospheric and Environmental Optics, 2019, 14(6): 419-430.

[6] Luo Hongyuan, Wang Deyun, Liu Yanling, et al. PM2.5 concentration prediction based on two-layer decomposition technique and improved extreme learning machine[J]. System Engineering Theory and Practice, 2018, 38(5): 1321-1330.

[7] Qiao Junfei, Cai Jie, Han Honggui. Study on prediction of PM2.5 based on T-S fuzzy neural network[J]. English Translation of Control Engineering, 2018, 25(3): 391-395.

[8] Wu Chunlin, Li Qi, Hou Junxiong, et al. PM2.5 concentration prediction using convolutional neural networks[J]. Mapping Science, 2018, 43(8): 72-79.

[9] Li Xiaoli, Mei Jianxiang, Zhang Shan. PM2.5 concentration prediction using BP_Adaboost neural network based on modified particle swarm optimization[J]. Journal of the Dalian University of Technology, 2018, 58(3): 99-106.

[10] Zhou Shanshan, Li Wenjing, Qiao Junfei. Prediction of PM2.5 concentration based on self-organizing recurrent fuzzy neural network[J]. Journal of Intelligent Systems, 2018, 13(4): 21-28.

[11] Cui Xianghui, Xie Jianfeng, Zhang Feng, et al. Establishment of PM2.5 prediction model based on deep learning[J]. Beijing Surveying and Mapping, 2017, (6): 22-27.

[12] Fan Junxiang, Li Qi, Zhu Yajie, et al. Aspatio-temporal prediction framework for air pollution based on deep RNN[J]. Surveying and Mapping Science, 2017, 42(7): 76-83, 120.

[13] Hu Xinchen. Research on Semantic Relationship Classification Based on LSTM[D].Harbin: Harbin University of Technology, 2015.

[14] Xie Yi, Rao Wenbi, Duan Pengfei, et al. A Chinese POS tagging approach using CNN and LSTM-based hybrid model[J]. Journal of Wuhan University (Science Edition), 2017, 63(3): 246-250.

[15] Zhao Xiaoqiang, Song Zhaoyang. Adam optimized CNN super-resolution reconstruction[J]. Computer Science and Exploration, 2019, 13(5): 858-865.

[16] Huang Liwei, Jiang Bitao, Lv Shouye, et al. Survey on deep learning based recommender systems[J]. Journal of Computer Science, 2018, 41(7): 1619-1647.

[17] Yang Bo, Su Xiaohong, Wang Yadong. A hybrid algorithm based on attention model[J]. Journal of Software, 2005, (6): 1073-1080.

[18] Yang Guanci, Yang Jing, Li Shaobo, et al. Modified CNN algorithm based on Dropout and ADAM optimizer[J]. Journal of Huazhong University of Science and Technology (Natural Science Edition), 2018, 46(7): 122-127.

[19] Chang Zihan. Electricity Price Prediction Based on Hybrid Model of Adam optimized LSTM Neural Network and Wavelet Transform[D].Lanzhou: Lanzhou University, 2019.

[20] Breathe freely[EB/OL]. (2008-05-16) [2018-12-31]. http:// www.pm25.com.

[21] Wu yunyun, Zhu Jianjun, Zuo Tingying. Investigation on the square root of the linear combination of the squre of RMSE and smoothness for the Vondrak filter′s evaluation[J]. Journal of Wuhan University (Information Science Edition), 2012, 37(10): 1212-1214.