A New Family of Time Series to Model the Decreasing Relative Increment of Spreading of an Outbreak

Q4 Medicine
B. Jamshidi, H. Bekrizadeh, Shahriar Jamshidi Zargaran, M. Rezaei
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引用次数: 0

Abstract

Introduction: There are different mathematical models describing the propagation of an epidemic. These models can be divided into phenomenological, compartmental, deep learning, and individual-based methods. From other viewpoints, we can classify them into macroscopic or microscopic, stochastic or deterministic, homogeneous or heterogeneous, univariate or multivariate, parsimonious or complex, or forecasting or mechanistic. This paper defines a novel univariate bi-partite time series model able to describe spreading a communicable infection in a population in terms of the relative increment of the cumulative number of confirmed cases. The introduced model can describe different stages of the first wave of the outbreak of a communicable disease from the start to the end. Results: We use it to describe the propagation of various disease outbreaks, including the SARS (2003), the MERS (2018), the Ebola (2014-2016), the HIV/AIDS (1990-2018), the Cholera (2008-2009), and the COVID-19 epidemic in Iran, Italy, the UK, the USA, China and four of its provinces; Beijing, Guangdong, Shanghai, and Hubei (2020). In all mentioned cases, the model has an acceptable performance. In addition, we compare the goodness of this model with the ARIMA models by fitting the propagation of COVID-19 in Iran, Italy, the UK, and the USA. Conclusion: The introduced model is flexible enough to describe a broad range of epidemics. In comparison with ARIMA time series models, our model is more initiative and less complicated, it has fewer parameters, the estimation of its parameters is more straightforward, and its forecasts are narrower and more accurate. Due to its simplicity and accuracy, this model is a good tool for epidemiologists and biostatisticians to model the first wave of an epidemic.
一个新的时间序列族,用于模拟疫情传播的相对增量递减
引言:有不同的数学模型描述流行病的传播。这些模型可以分为现象学、分区法、深度学习和基于个体的方法。从其他角度来看,我们可以将其分为宏观或微观、随机或确定性、同质或异质、单变量或多变量、简约或复杂、预测或机制。本文定义了一个新的单变量两党时间序列模型,该模型能够根据累计确诊病例数的相对增量来描述传染性感染在人群中的传播。引入的模型可以描述从开始到结束的第一波传染病爆发的不同阶段。结果:我们用它来描述各种疾病暴发的传播,包括SARS(2003年)、MERS(2018年)、埃博拉(2014-2016年)、艾滋病毒/艾滋病(1990-2018年)和霍乱(2008-2009年),以及新冠肺炎在伊朗、意大利、英国、美国、中国及其四个省的流行;北京、广东、上海和湖北(2020)。在所有提到的情况下,该模型都具有可接受的性能。此外,我们通过拟合新冠肺炎在伊朗、意大利、英国和美国的传播,将该模型与ARIMA模型的优度进行了比较。结论:引入的模型足够灵活,可以描述广泛的流行病。与ARIMA时间序列模型相比,我们的模型更具主动性,不那么复杂,参数更少,参数估计更直接,预测范围更窄,更准确。由于其简单准确,该模型是流行病学家和生物统计学家模拟第一波疫情的好工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
0.80
自引率
0.00%
发文量
26
审稿时长
12 weeks
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