Journal of Arid Meteorology ›› 2024, Vol. 42 ›› Issue (5): 661-670.DOI: 10.11755/j.issn.1006-7639-2024-05-0661
• Special Column: Application of Artificial Intelligence in Drought Meteorology and Related Fields • Previous Articles Next Articles
Construction and validation of summer drought prediction model in Hubei Province based on machine learning algorithms
WANG Yajun1,2(
), LUO Juying1, CHENG Liehai3(), LI Wei4
- 1. Enshi Tujia and Miao Autonomous Prefecture Meteorological Bureau of Hubei Province, Enshi 445000, Hubei, China
2. Hubei Key Laboratory for Heavy Rain Monitoring and Warning Research, Wuhan 430205, China
3. Shandong Electric Power Engineering Consulting Institute Company Limited, Jinan 250013, China
4. Nanjing University of Information Science and Technology, Key Laboratory of Meteorological Disaster of Ministry of Education, Collaborative Innovation Center on Forecast and Evaluation of Meteorological Disasters, Nanjing 210044, China
-
Received:2024-08-03Revised:2024-09-15Online:2024-10-31Published:2024-11-17
基于机器学习的湖北省夏季干旱预测模型构建与检验
- 1.湖北省恩施土家族苗族自治州气象局,湖北 恩施 445000
2.暴雨监测预警湖北省重点实验室,湖北 武汉 430205
3.山东电力工程咨询院有限公司,山东 济南 250013
4.南京信息工程大学,气象灾害教育部重点实验室,气象灾害预报预警与评估协同创新中心,江苏 南京 210044
-
通讯作者:程烈海(1973—),男,硕士,高级工程师,主要从事风能太阳能等新能源气候预测。E-mail:chengliehai@sdepci.com 。 -
作者简介:王雅君(1996—),女,硕士,助理工程师,主要从事季节尺度干旱预测和区域气候变化研究。E-mail:1843984032@qq.com。 -
基金资助:湖北省气象局科研项目(2023Q15);山东省工信厅课题(202350100877)
CLC Number:
Cite this article
WANG Yajun, LUO Juying, CHENG Liehai, LI Wei. Construction and validation of summer drought prediction model in Hubei Province based on machine learning algorithms[J]. Journal of Arid Meteorology, 2024, 42(5): 661-670.
王雅君, 罗菊英, 程烈海, 李伟. 基于机器学习的湖北省夏季干旱预测模型构建与检验[J]. 干旱气象, 2024, 42(5): 661-670.
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URL: http://www.ghqx.org.cn/EN/10.11755/j.issn.1006-7639-2024-05-0661
Tab.1 The drought classification standard based on SPEI
| SPEI | 干旱等级 | 是否干旱 |
|---|---|---|
| -0.5<SPEI | 无旱 | 否 |
| -1.0<SPEI≤-0.5 | 轻旱 | 是 |
| -1.5<SPEI≤-1.0 | 中旱 | 是 |
| -2.0<SPEI≤-1.5 | 重旱 | 是 |
| SPEI≤-2.0 | 特旱 | 是 |
Tab.1 The drought classification standard based on SPEI
| SPEI | 干旱等级 | 是否干旱 |
|---|---|---|
| -0.5<SPEI | 无旱 | 否 |
| -1.0<SPEI≤-0.5 | 轻旱 | 是 |
| -1.5<SPEI≤-1.0 | 中旱 | 是 |
| -2.0<SPEI≤-1.5 | 重旱 | 是 |
| SPEI≤-2.0 | 特旱 | 是 |
Fig.1 The inter-annual variation of summer SPEI in Hubei Province from 1960 to 2022 (The red dashed line denotes the critical threshold of drought)
Fig.1 The inter-annual variation of summer SPEI in Hubei Province from 1960 to 2022 (The red dashed line denotes the critical threshold of drought)
Fig.2 The spatial distribution (a, b, c) and their corresponding time coefficients (d, e, f) of the first (a, d), second (b, e), and third (c, f) modes by EOF decomposition of the summer SPEI in Hubei Province from 1960 to 2022
Fig.2 The spatial distribution (a, b, c) and their corresponding time coefficients (d, e, f) of the first (a, d), second (b, e), and third (c, f) modes by EOF decomposition of the summer SPEI in Hubei Province from 1960 to 2022
Tab.2 The definition of summer drought impact factors and their correlation coefficient with SPEI in Hubei Province from 1960 to 2022
| 特征编号 | 影响因子 | 定义 | 相关 系数 |
|---|---|---|---|
| 1 | 热带南大西洋海温指数 | 30°W—10°E、20°S—0°区域内海表温度距平的区域平均值 | 0.19 |
| 2 | 亲潮区海温指数 | 165°E—175°E、40°N—45°N区域内海表温度距平的区域平均值 | -0.15 |
| 3 | 西风漂流区海温指数 | 160°E—160°W、35°N—45°N区域内海表温度距平的区域平均值 | -0.09 |
| 4 | 西太平洋副高脊线位置指数 | 110°E—150°E、10°N—60°N区域内500 hPa高度场逐条经线上副热带高压中心位置所在纬度的平均值 | -0.37** |
| 5 | 北美副高脊线位置指数 | 110°W—60°W、10°N—60°N区域内500 hPa高度场逐条经线上副热带高压中心位置所在纬度的平均值 | -0.24* |
| 6 | 北大西洋副高北界位置指数 | 55°W—25°W、10°N—60°N区域内500 hPa高度场逐条经线上副热带高压北侧5 880 gpm等值线所在纬度的平均值 | 0.26** |
| 7 | 亚洲区极涡面积指数 | 北半球60°E—150°E区域内500 hPa高度场极涡南界特征等高线以北所包围的扇形面积 | -0.30** |
| 8 | 亚洲纬向环流指数 | 60°E—150°E、45°N—65°N区域内500 hPa高度场以30个经度为间隔划分为3个区,计算平均纬向指数 | 0.07 |
| 9 | 斯堪的纳维亚遥相关型指数 | 0°—360°、20°N—90°N区域内,标准化500 hPa高度场经验正交函数分析所得的第九模态的时间系数 | -0.32** |
| 10 | AMO | 80°W—0°、0°—60°N区域内平均的海表面温度距平 | 0.26** |
| 11 | NAO | 90°W—50°E、20°N—85°N大西洋地区海平面气压距平场的经验正交函数分解第一主成分 | -0.24* |
Tab.2 The definition of summer drought impact factors and their correlation coefficient with SPEI in Hubei Province from 1960 to 2022
| 特征编号 | 影响因子 | 定义 | 相关 系数 |
|---|---|---|---|
| 1 | 热带南大西洋海温指数 | 30°W—10°E、20°S—0°区域内海表温度距平的区域平均值 | 0.19 |
| 2 | 亲潮区海温指数 | 165°E—175°E、40°N—45°N区域内海表温度距平的区域平均值 | -0.15 |
| 3 | 西风漂流区海温指数 | 160°E—160°W、35°N—45°N区域内海表温度距平的区域平均值 | -0.09 |
| 4 | 西太平洋副高脊线位置指数 | 110°E—150°E、10°N—60°N区域内500 hPa高度场逐条经线上副热带高压中心位置所在纬度的平均值 | -0.37** |
| 5 | 北美副高脊线位置指数 | 110°W—60°W、10°N—60°N区域内500 hPa高度场逐条经线上副热带高压中心位置所在纬度的平均值 | -0.24* |
| 6 | 北大西洋副高北界位置指数 | 55°W—25°W、10°N—60°N区域内500 hPa高度场逐条经线上副热带高压北侧5 880 gpm等值线所在纬度的平均值 | 0.26** |
| 7 | 亚洲区极涡面积指数 | 北半球60°E—150°E区域内500 hPa高度场极涡南界特征等高线以北所包围的扇形面积 | -0.30** |
| 8 | 亚洲纬向环流指数 | 60°E—150°E、45°N—65°N区域内500 hPa高度场以30个经度为间隔划分为3个区,计算平均纬向指数 | 0.07 |
| 9 | 斯堪的纳维亚遥相关型指数 | 0°—360°、20°N—90°N区域内,标准化500 hPa高度场经验正交函数分析所得的第九模态的时间系数 | -0.32** |
| 10 | AMO | 80°W—0°、0°—60°N区域内平均的海表面温度距平 | 0.26** |
| 11 | NAO | 90°W—50°E、20°N—85°N大西洋地区海平面气压距平场的经验正交函数分解第一主成分 | -0.24* |
Fig.3 Prediction model for summer drought in Hubei Province based on classification and regression tree algorithm
Fig.3 Prediction model for summer drought in Hubei Province based on classification and regression tree algorithm
Fig.4 The confusion matrix of training set (a) and test set (b) in classification and regression tree algorithm model
Fig.4 The confusion matrix of training set (a) and test set (b) in classification and regression tree algorithm model
Tab.3 Comparison of the actual values and predict drought based on classification and regression tree algorithm and random forest algorithm in the test set
| 年份 | 分类回归树算法预测 | 随机森林算法预测 | 实况 |
|---|---|---|---|
| 1962 | 无旱 | 无旱 | 无旱 |
| 1963 | 无旱 | 无旱 | 无旱 |
| 1966 | 无旱 | 无旱 | 干旱 |
| 1977 | 无旱 | 无旱 | 无旱 |
| 1979 | 无旱 | 无旱 | 无旱 |
| 1980 | 无旱 | 无旱 | 无旱 |
| 1981 | 无旱 | 无旱 | 干旱 |
| 1983 | 无旱 | 无旱 | 无旱 |
| 1986 | 无旱 | 无旱 | 无旱 |
| 1987 | 无旱 | 无旱 | 无旱 |
| 1991 | 无旱 | 无旱 | 无旱 |
| 1995 | 无旱 | 无旱 | 无旱 |
| 1997 | 无旱 | 无旱 | 无旱 |
| 1999 | 无旱 | 无旱 | 无旱 |
| 2001 | 干旱 | 无旱 | 干旱 |
| 2013 | 干旱 | 干旱 | 干旱 |
Tab.3 Comparison of the actual values and predict drought based on classification and regression tree algorithm and random forest algorithm in the test set
| 年份 | 分类回归树算法预测 | 随机森林算法预测 | 实况 |
|---|---|---|---|
| 1962 | 无旱 | 无旱 | 无旱 |
| 1963 | 无旱 | 无旱 | 无旱 |
| 1966 | 无旱 | 无旱 | 干旱 |
| 1977 | 无旱 | 无旱 | 无旱 |
| 1979 | 无旱 | 无旱 | 无旱 |
| 1980 | 无旱 | 无旱 | 无旱 |
| 1981 | 无旱 | 无旱 | 干旱 |
| 1983 | 无旱 | 无旱 | 无旱 |
| 1986 | 无旱 | 无旱 | 无旱 |
| 1987 | 无旱 | 无旱 | 无旱 |
| 1991 | 无旱 | 无旱 | 无旱 |
| 1995 | 无旱 | 无旱 | 无旱 |
| 1997 | 无旱 | 无旱 | 无旱 |
| 1999 | 无旱 | 无旱 | 无旱 |
| 2001 | 干旱 | 无旱 | 干旱 |
| 2013 | 干旱 | 干旱 | 干旱 |
Fig.5 The confusion matrix of training set (a) and test set (b) in random forest algorithm model
Fig.5 The confusion matrix of training set (a) and test set (b) in random forest algorithm model
Tab.4 Comparison between the actual drought and the two machine learning algorithms prediction and operational prediction from 2011 to 2022
| 年份 | 分类回归树算法预测 | 随机森林算法预测 | 业务发布预测 | 实况 |
|---|---|---|---|---|
| 2011 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2012 | 干旱 | 干旱 | 干旱 | 干旱 |
| 2013 | 干旱 | 干旱 | 干旱 | 干旱 |
| 2014 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2015 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2016 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2017 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2018 | 干旱 | 干旱 | 干旱 | 干旱 |
| 2019 | 干旱 | 无旱 | 无旱 | 干旱 |
| 2020 | 无旱 | 无旱 | 干旱 | 无旱 |
| 2021 | 无旱 | 无旱 | 干旱 | 无旱 |
| 2022 | 干旱 | 干旱 | 无旱 | 干旱 |
Tab.4 Comparison between the actual drought and the two machine learning algorithms prediction and operational prediction from 2011 to 2022
| 年份 | 分类回归树算法预测 | 随机森林算法预测 | 业务发布预测 | 实况 |
|---|---|---|---|---|
| 2011 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2012 | 干旱 | 干旱 | 干旱 | 干旱 |
| 2013 | 干旱 | 干旱 | 干旱 | 干旱 |
| 2014 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2015 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2016 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2017 | 无旱 | 无旱 | 无旱 | 无旱 |
| 2018 | 干旱 | 干旱 | 干旱 | 干旱 |
| 2019 | 干旱 | 无旱 | 无旱 | 干旱 |
| 2020 | 无旱 | 无旱 | 干旱 | 无旱 |
| 2021 | 无旱 | 无旱 | 干旱 | 无旱 |
| 2022 | 干旱 | 干旱 | 无旱 | 干旱 |
Fig.6 Importance scores of features in the prediction model based on classification and regression tree (a) and random forest (b) (The number of features corresponds to the influencing factors in table 2)
Fig.6 Importance scores of features in the prediction model based on classification and regression tree (a) and random forest (b) (The number of features corresponds to the influencing factors in table 2)
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