English

Simulation and application of COVID-19 compartment model using physics-informed neural network

Quantitative Methods 2022-10-13 v4 Machine Learning Physics and Society Populations and Evolution

Abstract

COVID-19 pandemic has had a disruptive and irreversible impact globally, yet traditional epidemiological modeling approaches such as the susceptible-infected-recovered (SIR) model have exhibited limited effectiveness in forecasting of the up-to-date pandemic situation. In this work, susceptible-vaccinated-exposed-infected-dead-recovered (SVEIDR) model and its variants -- aged and vaccination-structured SVEIDR models -- are introduced to encode the effect of social contact for different age groups and vaccination status. Then, we implement the physics-informed neural network (PiNN) on both simulated and real-world data. The PiNN model enables robust analysis of the dynamic spread, prediction, and parameter optimization of the COVID-19 compartmental models. The models exhibit relative root mean square error (RRMSE) of <4%<4\% for all components and provide incubation, death, and recovery rates of γ=0.0130\gamma= 0.0130, λ=0.0001\lambda=0.0001, and ρ=0.0037\rho=0.0037, respectively, for the first 310 days of the epidemic in the US with RRMSE of <0.35%<0.35\% for all components. To further improve the model performance, temporally varying parameters can be included, such as vaccination, transmission, and incubation rates. Our implementation highlights PiNN as a reliable candidate approach for forecasting real-world data and can be applied to other compartmental model variants of interest.

Keywords

Cite

@article{arxiv.2208.02433,
  title  = {Simulation and application of COVID-19 compartment model using physics-informed neural network},
  author = {Jinhuan Ke and Jiahao Ma and Xiyu Yin and Robin Singh},
  journal= {arXiv preprint arXiv:2208.02433},
  year   = {2022}
}
R2 v1 2026-06-25T01:28:02.152Z