Multivariate time series short term forecasting using cumulative data of coronavirus

Multivariate time series short term forecasting using cumulative data of coronavirus

Coronavirus emerged as a highly contagious, pathogenic virus that severely affects the respiratory system of humans. The epidemic-related data is collected regularly, which machine learning algorithms can employ to comprehend and estimate valuable information. The analysis of the gathered data throu...

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Bibliographic Details
Published in:Evolving systems Vol. 15; no. 3; pp. 811 - 828
Main Authors: Mishra, Suryanshi, Singh, Tinku, Kumar, Manish, Satakshi
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 04-06-2023
Springer Nature B.V
Subjects:
Accuracy
Algorithms
Ambient temperature
Artificial Intelligence
Complex Systems
Complexity
Coronaviruses
COVID-19 vaccines
Deep learning
Disease transmission
Engineering
Epidemics
Fatalities
Forecasting
Humidity
Immunization
Literature reviews
Machine learning
Mortality
Multivariate analysis
Ordinary differential equations
Original Paper
Pandemics
Pathogens
Relative humidity
Respiratory system
Root-mean-square errors
Support vector machines
Time series
Viruses
India
Extended SEIR
Coronavirus
LSTM
Forecasting
Machine learning
Classification
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Summary:Coronavirus emerged as a highly contagious, pathogenic virus that severely affects the respiratory system of humans. The epidemic-related data is collected regularly, which machine learning algorithms can employ to comprehend and estimate valuable information. The analysis of the gathered data through time series approaches may assist in developing more accurate forecasting models and strategies to combat the disease. This paper focuses on short-term forecasting of cumulative reported incidences and mortality. Forecasting is conducted utilizing state-of-the-art mathematical and deep learning models for multivariate time series forecasting, including extended susceptible-exposed-infected-recovered (SEIR), long-short-term memory (LSTM), and vector autoregression (VAR). The SEIR model has been extended by integrating additional information such as hospitalization, mortality, vaccination, and quarantine incidences. Extensive experiments have been conducted to compare deep learning and mathematical models that enable us to estimate fatalities and incidences more precisely based on mortality in the eight most affected nations during the time of this research. The metrics like mean absolute error (MAE), root mean square error (RMSE), and mean absolute percentage error (MAPE) are employed to gauge the model’s effectiveness. The deep learning model LSTM outperformed all others in terms of forecasting accuracy. Additionally, the study explores the impact of vaccination on reported epidemics and deaths worldwide. Furthermore, the detrimental effects of ambient temperature and relative humidity on pathogenic virus dissemination have been analyzed.
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ISSN:1868-6478
1868-6486
1868-6486
DOI:10.1007/s12530-023-09509-w