CovSyn: an agent-based model for synthesizing COVID-19 course of disease and contact tracing data
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The COVID-19 pandemic has demonstrated the shortcomings of epidemiological modelling for guiding policy decisions. Moreover, the modelling efforts resulted in many models yielding different predictions, creating a need to compare these predictions to determine which model is most accurate. We introduce a data synthesis algorithm, CovSyn, designed to generate synthetic COVID-19 datasets providing sufficiently detailed information for benchmarking epidemiological models against a known synthetic ground truth. CovSyn utilizes observed infections with contact tracing, testing, course of disease data, and a contact network based on municipality statistics, which categorises connections into household, school, workplace, healthcare, and municipality. The model’s initial parameters and boundaries are derived from empirical data, including the first community outbreak of COVID-19 in Taiwan and clinical observations. Comprehensive parameter space exploration for optimal results is done by the Firefly algorithm. We demonstrate it and validate our estimates by comparing state transition times, daily social contacts, and associated secondary attack rates against a structured dataset and clinical observations. Our simulations align with prior research and this dataset. Most state transition times from 10,000 simulations are within uncertainty ranges. Daily contact numbers and their distribution across layers match empirical findings. Our model accurately reproduced the first COVID-19 outbreak in Taiwan, achieving high accuracy with observed cumulative confirmed cases ( R 2 = 0.9) across daily, 7-day moving average, and 31-day moving average levels. Each synthetic subject contains demographic data (age, gender, occupation), course of disease (latent/incubation periods, testing, isolation, critical illness, recovery, and death dates), and contact network data including daily interactions with infected and uninfected individuals. Our algorithm offers a valid alternative for developing and benchmarking epidemiological models to advance COVID-19 forecasting research.
Author summary
We present a novel approach to enhance the testing of epidemiological infection modelling and demonstrate spread prediction accuracy by testing COVID-19 simulation models on Taiwanese synthetic data with known ground truth. CovSyn generates comprehensive synthetic data at the individual level, encompassing demographic characteristics (age, gender, occupation), course of disease (infection dates, symptom onset, recovery dates), and contact tracing information (daily social interactions including household, school, workplace, healthcare, and municipality). It can provide a consistent, standardized synthetic dataset for model evaluation, addressing the previous challenge of comparing COVID-19 models that used disparate data sources and different time periods. In this study, we detail the algorithm and demonstrate its reliability by creating a synthetic dataset for the first outbreak of SARS-CoV-2 in Taiwan and comparing it with the collected Taiwan COVID-19 dataset. Future work will focus on benchmarking state-of-the-art forecasting models using our synthetic data. Through CovSyn’s detailed individual-level data, we aim to advance the development of more accurate epidemiological models.
