The occurrence of flood disasters is related to persistent heavy rainfall anomalies. Under the influence of climate anomalies, the rainfall, rainfall intensity and frequency in Zhengzhou have been rising in recent decades. In order to further describe the rainfall characteristics in Zhengzhou area, Pearson correlation analysis and moving average method are used to analyze the characteristics of precipitation in Zhengzhou from 1973 to 2020 from the Total amount, intensity and duration of precision. The results show that during this period, the average annual precision in Zhengzhou was 660 mm, and the top three years were 2003, 2016 and 1983. The annual average precipitation intensity in Zhengzhou is 3.12 mm/d, And the linear tendentiousness trends of heavy rain and torrential rain are -0.0008 d/a and -0.005 d/a respectfully. The above research in this paper can provide reference for the urban response plan and long-term construction planning under extreme precipitation conditions.

Liqi Zhou, Lu Zhang. Research on Rainfall Characteristics in Zhengzhou Based on Pearson Correlation Analysis and Moving Average Method. Academic Journal of Mathematical Sciences (2023) Vol. 4, Issue 1: 7-11. https://doi.org/10.25236/AJMS.2023.040102.

[1] Meng Xiaojing, Chen Xin, Chen Jiajing, Yang Honggang. The application of combination weighting -TOPSIS in urban regional resilience assessment under flood disaster [J/OL]. Journal of Safety and Environment: 1-9 [January 14, 2023]. http://kns.cnki.net/kcms/detail

[2] Chen Jiaxin, Wang Juanle. Analysis and suggestions on defensive countermeasures of typical flood disasters abroad in recent years [J]. Disaster Reduction in China, 2022(21): 46-49.

[3] Shu Liangliang, He Xiaosai. Research progress of urban flood disaster risk assessment [J/OL]. Flood Control and Drought Relief in China: 1-6 [January 14, 2023]. doi: 10. 6867/ j. issn. 1673- 19983. 100000000616

[4] Jin Ting. Study on the evaluation of urban flood resilience based on network structure model [D]. Wuhan University of Science and Technology, 2022. doi: 10.27380/d.cnki.gwkju.20000.100001000005

[5] Liu Jiafu, Zhang Yuxin, Wang Lili, Gao Xuan, Zhang Yuqi. Temporal and spatial pattern evolution and driving forces of flood disasters in three northeastern provinces [J]. Journal of Jilin Normal University (Natural Science Edition), 2022, 43(03): 129-140. doi: 10.16862/j.cnki.ISSN.

[6] Huang Yafei, Guan Zhaoyong, Cai Qian, Lv Chunyue. Analysis of temporal and spatial variation characteristics of rainstorm and flood disasters in Jiangnan area in recent 41 years [J]. Journal of Meteorology, 2021, 79(04): 582-597.

[7] Chen Chuanlei, Guan Zhaoyong, Xiao Guangliang, Cheng Pan, Yang Lei, Huang Hailiang. Temporal and spatial distribution of extremely long rainstorm in Liaoning Province and its impact system characteristics [J]. Journal of Meteorology and Environment, 2018, 34(02): 28-34.

[8] Yu Xuan, Xu Ying, Zhang Yongxiang. Temporal and spatial variation characteristics of rainstorm in China in recent 25 years and its impact on rainstorm and flood disaster [J]. Rainstorm Ddisaster, 2018, 37(01): 67-72.

[9] Wang Yi, Du Fu, Mao Rui. Possible impact of large-scale climatic factors on flood disaster in China in recent 40 years [J]. Journal of Beijing Normal University (Natural Science Edition), 2021, 57(06): 825-833.

[10] Ye Minghua, Chen Kang. Urban catastrophe risk: meteorological characteristics, loss status and optimization of management countermeasures-taking Zhengzhou "July 20" torrential rain and typhoon "fireworks" as examples [J]. Shanghai Insurance, 2021(08): 18-22.