Application of LAPM and ABM methods to a fractional SCIR model of pneumonia diseases
Muflih Alhazmi, Safa M. Mirgani, Abdullah Alahmari, Sayed Saber
Abstract
We develop a fractional SCIR (susceptible-carrier-infected-recovered) model for pneumococcal pneumonia using Caputo derivatives of order $ 0 < \varrho \leq 1 $ to capture memory effects from long carriage, waning immunity, and reinfection. The force of infection explicitly accounts for carriers' transmissibility. Using a next-generation approach, we derive the basic reproduction number $ \mathscr{R}_0 $ and prove the global asymptotic stability of the disease-free equilibrium when $ \mathscr{R}_0 < 1 $ and of the endemic equilibrium when $ \mathscr{R}_0 > 1 $ via Lyapunov functionals and a fractional LaSalle principle. Numerically, we combine the Laplace-Adomian-Padé method (LAPM) with a fractional Adams-Bashforth-Moulton scheme (ABM) to capture memory-driven transients. A sensitivity analysis identifies transmission intensity and routing into carriage as the dominant epidemic drivers, while treatment and mortality exert mitigating effects. A control extension yields a closed-form, control-adjusted $ \mathscr{R}_0 $; a minimal vaccination threshold; and an optimal control problem solved numerically. Finally, we outline a calibration workflow linking the model-predicted incidence to surveillance data, permitting a statistical estimation of the fractional order. Altogether, incorporating carriers and fractional memory modifies the thresholds and persistence conditions, producing dynamics that are more consistent with pneumococcal epidemiology.