Neural Network aided quarantine control model estimation of global Covid-19 spread

TL;DR

This study uses a neural network-enhanced epidemiological model to analyze and predict the impact of quarantine measures on COVID-19 spread across different countries, highlighting the importance of strict interventions.

Contribution

It introduces a neural network augmented model combining epidemiological equations with data-driven techniques to evaluate quarantine effectiveness and predict infection trends.

Findings

Strict quarantine measures effectively halted exponential spread.

Model accurately predicted infection curves for Wuhan, Italy, South Korea.

Relaxing quarantine measures risks exponential growth in cases.

Abstract

Since the first recording of what we now call Covid-19 infection in Wuhan, Hubei province, China on Dec 31, 2019, the disease has spread worldwide and met with a wide variety of social distancing and quarantine policies. The effectiveness of these responses is notoriously difficult to quantify as individuals travel, violate policies deliberately or inadvertently, and infect others without themselves being detected. In this paper, we attempt to interpret and extrapolate from publicly available data using a mixed first-principles epidemiological equations and data-driven neural network model. Leveraging our neural network augmented model, we focus our analysis on four locales: Wuhan, Italy, South Korea and the United States of America, and compare the role played by the quarantine and isolation measures in each of these countries in controlling the effective reproduction number $R_{t}$ of the virus. Our results unequivocally indicate that the countries in which rapid government interventions and strict public health measures for quarantine and isolation were implemented were successful in halting the spread of infection and prevent it from exploding exponentially. We test the predictive ability of our model by matching predictions in the duration 3 March - 1 April 2020 for Wuhan and in the duration 25 March - 1 April 2020 for Italy and South Korea. In the case of the US, our model captures well the current infected curve growth and predicts a halting of infection spread by 20 April 2020. We further demonstrate that relaxing or reversing quarantine measures right now will lead to an exponential explosion in the infected case count, thus nullifying the role played by all measures implemented in the US since mid March 2020.