Mathematical Modeling And Artificial Intelligence For Predictive Analysis In Complex Biological And Computational Systems
DOI:
https://doi.org/10.4238/1x0qg528Keywords:
Mathematical modeling; Artificial intelligence; SEIR model; Random Forest; COVID-19 dynamics; Hybrid modeling.Abstract
Complex biological and computational systems involve nonlinear interactions, dynamic feedback, uncertainty, and multiscale processes that make accurate prediction difficult using a single modeling approach. Mathematical models provide mechanistic interpretability, whereas artificial intelligence supports flexible prediction from complex data. This research develops a hybrid SEIR–AI framework for predictive analysis using COVID-19 transmission dynamics in India as a representative case study. Publicly available data from Our World in Data were used, with seven-day smoothed new cases selected as the primary prediction target. An SEIR compartmental model was fitted to represent susceptible, exposed, infectious, and recovered or removed population dynamics. A Random Forest model was then used for AI-only prediction and for residual correction in the hybrid model. The hybrid framework was evaluated against a naive baseline, SEIR-only model, and AI-only model using MAE, RMSE, MAPE, and . Results showed that the naive baseline performed best during the low-transmission testing period, but the hybrid SEIR–AI model improved RMSE and MAPE compared with the SEIR-only and AI-only models. The findings indicate that hybrid mathematical–AI modeling can improve mechanistic prediction while preserving biological interpretability, supporting its broader use in biomathematics, epidemiology, digital health, and complex biological forecasting.
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