Drought driving mechanism and risk situation prediction based on machine learning models in the Yellow River Basin, China

IF 4.5 3区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
Ling Kang, Yunliang Wen, Liwei Zhou, Hao Chen, Jinwang Ye
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Abstract

Under global warming, the acceleration of the water cycle has increased the risk of drought in the Yellow River Basin. Revealing the drought driving mechanisms in the basin and understanding the risk situation of drought have become particularly important. This paper uses wavelet analysis and transfer entropy to analyze the drought driving mechanisms. In addition, an Improved Particle Swarm Optimization (IPSO) coupled with Long Short-Term Memory (LSTM) is used for drought risk prediction. The results are as follows: (1) Hydrological drought lags behind meteorological drought by 2–3 months, and they show two main periods on different time scales, which are 5–6 months and 8–14 months, respectively. (2) Rainfall, runoff, temperature, humidity, and vapor pressure are the main drought driving factors, with rainfall and humidity having the most significant impact. (3) The IPSO-LSTM model has improved the process of selecting model parameters based on empirical experiences in the LSTM model, improving the prediction accuracy by an average of 3.1%. This paper provides a scientific basis for water resource management and drought risk assessment in the basin, to better cope with future climate challenges.
基于机器学习模型的黄河流域干旱驱动机制及风险态势预测
在全球变暖的背景下,水循环的加速增加了黄河流域干旱的风险。揭示流域干旱驱动机制,认识干旱风险状况显得尤为重要。利用小波分析和传递熵分析了干旱的驱动机制。此外,将改进的粒子群优化(IPSO)与长短期记忆(LSTM)相结合,用于干旱风险预测。结果表明:①水文干旱滞后于气象干旱2 ~ 3个月,在不同时间尺度上表现为5 ~ 6个月和8 ~ 14个月两个主要周期;(2)降雨、径流、温度、湿度和水汽压是干旱的主要驱动因子,其中降雨和湿度的影响最为显著。(3) IPSO-LSTM模型改进了LSTM模型中基于经验经验选择模型参数的过程,预测精度平均提高3.1%。为流域水资源管理和干旱风险评估提供科学依据,更好地应对未来气候挑战。
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来源期刊
Geomatics Natural Hazards & Risk
Geomatics Natural Hazards & Risk GEOSCIENCES, MULTIDISCIPLINARY-METEOROLOGY & ATMOSPHERIC SCIENCES
CiteScore
7.70
自引率
4.80%
发文量
117
审稿时长
>12 weeks
期刊介绍: The aim of Geomatics, Natural Hazards and Risk is to address new concepts, approaches and case studies using geospatial and remote sensing techniques to study monitoring, mapping, risk mitigation, risk vulnerability and early warning of natural hazards. Geomatics, Natural Hazards and Risk covers the following topics: - Remote sensing techniques - Natural hazards associated with land, ocean, atmosphere, land-ocean-atmosphere coupling and climate change - Emerging problems related to multi-hazard risk assessment, multi-vulnerability risk assessment, risk quantification and the economic aspects of hazards. - Results of findings on major natural hazards
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