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利用天气综合深度学习方法预测印度的 COVID-19 病例。

Prediction of COVID-19 cases using the weather integrated deep learning approach for India.

机构信息

CSIR Fourth Paradigm Institute (CSIR-4PI), Bangalore, Karnataka, India.

ENVIS Resource Partner on Climate Change and Public Health, Applied Biology Division, CSIR-Indian Institute of Chemical Technology (CSIR-IICT), Hyderabad, Telegana, India.

出版信息

Transbound Emerg Dis. 2022 May;69(3):1349-1363. doi: 10.1111/tbed.14102. Epub 2021 Apr 20.

DOI:10.1111/tbed.14102
PMID:33837675
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8250893/
Abstract

Advanced and accurate forecasting of COVID-19 cases plays a crucial role in planning and supplying resources effectively. Artificial Intelligence (AI) techniques have proved their capability in time series forecasting non-linear problems. In the present study, the relationship between weather factor and COVID-19 cases was assessed, and also developed a forecasting model using long short-term memory (LSTM), a deep learning model. The study found that the specific humidity has a strong positive correlation, whereas there is a negative correlation with maximum temperature, and a positive correlation with minimum temperature was observed in various geographic locations of India. The weather data and COVID-19 confirmed case data (1 April to 30 June 2020) were used to optimize univariate and multivariate LSTM time series forecast models. The optimized models were utilized to forecast the daily COVID-19 cases for the period 1 July 2020 to 31 July 2020 with 1 to 14 days of lead time. The results showed that the univariate LSTM model was reasonably good for the short-term (1 day lead) forecast of COVID-19 cases (relative error <20%). Moreover, the multivariate LSTM model improved the medium-range forecast skill (1-7 days lead) after including the weather factors. The study observed that the specific humidity played a crucial role in improving the forecast skill majorly in the West and northwest region of India. Similarly, the temperature played a significant role in model enhancement in the Southern and Eastern regions of India.

摘要

对 COVID-19 病例进行先进且准确的预测对于有效地规划和供应资源至关重要。人工智能 (AI) 技术已证明其在时间序列预测非线性问题方面的能力。在本研究中,评估了气象因素与 COVID-19 病例之间的关系,并使用深度学习模型长短期记忆网络 (LSTM) 开发了一种预测模型。研究发现,在印度的各个地理位置,特定湿度与 COVID-19 病例之间具有很强的正相关关系,而与最高温度之间存在负相关关系,与最低温度之间存在正相关关系。气象数据和 COVID-19 确诊病例数据(2020 年 4 月 1 日至 6 月 30 日)用于优化单变量和多变量 LSTM 时间序列预测模型。优化后的模型用于预测 2020 年 7 月 1 日至 7 月 31 日期间的每日 COVID-19 病例,预测提前期为 1 至 14 天。结果表明,对于短期(1 天提前)的 COVID-19 病例预测,单变量 LSTM 模型表现良好(相对误差<20%)。此外,在包括气象因素后,多变量 LSTM 模型提高了中程预测的技巧(1-7 天提前)。研究观察到,特定湿度在提高预测技巧方面起着至关重要的作用,主要是在印度的西部和西北部地区。同样,温度在提高印度南部和东部地区模型性能方面发挥了重要作用。