Coronavirus Optimization Algorithm: A Bioinspired Metaheuristic Based on the COVID-19 Propagation Model

Coronavirus Optimization Algorithm: A Bioinspired Metaheuristic Based on the COVID-19 Propagation Model

This study proposes a novel bioinspired metaheuristic simulating how the coronavirus spreads and infects healthy people. From a primary infected individual (patient zero), the coronavirus rapidly infects new victims, creating large populations of infected people who will either die or spread infecti...

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Bibliographic Details
Published in:Big data Vol. 8; no. 4; p. 308
Main Authors: Martínez-Álvarez, F, Asencio-Cortés, G, Torres, J F, Gutiérrez-Avilés, D, Melgar-García, L, Pérez-Chacón, R, Rubio-Escudero, C, Riquelme, J C, Troncoso, A
Format: Journal Article
Language:English
Published: United States 01-08-2020
Subjects:
Algorithms
Betacoronavirus - isolation & purification
Coronavirus Infections - epidemiology
Coronavirus Infections - transmission
Coronavirus Infections - virology
COVID-19
Disease Outbreaks
Heuristics
Humans
Models, Theoretical
Pandemics
Pneumonia, Viral - epidemiology
Pneumonia, Viral - transmission
Pneumonia, Viral - virology
Probability
Quarantine
SARS-CoV-2
soft computing
deep learning
coronavirus
metaheuristics
big data
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Summary:This study proposes a novel bioinspired metaheuristic simulating how the coronavirus spreads and infects healthy people. From a primary infected individual (patient zero), the coronavirus rapidly infects new victims, creating large populations of infected people who will either die or spread infection. Relevant terms such as reinfection probability, super-spreading rate, social distancing measures, or traveling rate are introduced into the model to simulate the coronavirus activity as accurately as possible. The infected population initially grows exponentially over time, but taking into consideration social isolation measures, the mortality rate, and number of recoveries, the infected population gradually decreases. The coronavirus optimization algorithm has two major advantages when compared with other similar strategies. First, the input parameters are already set according to the disease statistics, preventing researchers from initializing them with arbitrary values. Second, the approach has the ability to end after several iterations, without setting this value either. Furthermore, a parallel multivirus version is proposed, where several coronavirus strains evolve over time and explore wider search space areas in less iterations. Finally, the metaheuristic has been combined with deep learning models, to find optimal hyperparameters during the training phase. As application case, the problem of electricity load time series forecasting has been addressed, showing quite remarkable performance.
ISSN:2167-647X
DOI:10.1089/big.2020.0051