Same storm, different boats: a reflection on COVID-19 models
From left to right, Professor Mikhail Prokopenko, Dr Cameron Zachreson, Sheryl Chang, Nathan Harding and Dr Oliver Cliff from the Centre for Complex Systems.
In March 2020, as the pandemic was sweeping the globe and establishing roots in Australia, the听听at the University of Sydney modelled how varying rates of social distancing could affect the spread of the COVID-19 pandemic across a very diverse Australian population.
Over the next three months, Australia鈥檚 pandemic spread followed a similar pattern to the scenario modelled by Professor Mikhail Prokopenko and his team 鈥 which predicted a pandemic peak in April.
Their research became one of the most highly cited and reported COVID-19 models (with more than 160 citations according to on November 11th, 2020).
Eight months on, he and his team reflect on the research, what they learnt, and how they can continue to use modelling to safeguard Australia鈥檚 future health security.
The research was released via pre-print in March and was this week published in听.听
Pandemic's early stages required quick thinking听
The team's March modelling identified a pandemic tipping point in Australia, which was the minimal level of effective social distancing (80 percent) required to contain the pandemic spread.
鈥淲e had to act quickly, and in March the virus was not yet well understood. Some approximations had to be made in our model, while retaining our focus on actionable interventions," said Professor Mikhail Prokopenko.
鈥淣ot only do we now understand the virus better and how it behaves, but we also understand how human movement, social interaction and government policy influence its spread.
鈥淎s the fight against COVID-19 continues, we hope that many contentious and rhetoric-rich debates can be resolved by sharp quantitative modelling.鈥
Calibration key for modelling
The research team's main aim was to investigate how compliance with non-pharmaceutical interventions in population affected the dynamics of the COVID-19 pandemic.听
鈥淲e faced many challenges as many of the pandemic's characteristics were unknown in February-March 2020," said听, who led the study and is a PhD candidate.听
鈥淐alibration is always vital in agent-based modelling (models which听simulate the actions and interactions of individuals or organisations)."
鈥淭he tipping point identified for effective social distancing level (80 percent) is the highlight of this study. It is also striking that an earlier introduction of social distancing, even by just three days, could make a significant difference in epidemic containment, lengthening the duration of suppression measures by over three weeks on average.
鈥淪everal COVID-19 vaccines are now rapidly being developed. We plan to investigate how different vaccination approaches would affect the epidemic dynamics. This will shed some light on optimal vaccination priorities and strategies for Australia.
Agent-based modelling allows for highly detailed simulations
鈥淎gent-based simulations allow us to model the pandemic and potential government interventions at the scale of individuals and households through to cities, states, and territories," said Dr Oliver Cliff.听
鈥淭hese layered models enable key questions to be asked about the effect of local (suburb- or state-wide) and national restrictions on the public's health and economy.
鈥淲e believe that such high-resolution models are the way forward for policy making, facilitating quantitative analysis at each level of the state and national government.鈥
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