Bessel-quasilinearization technique to solve the fractional-order HIV-1 infection of CD\(4^+\) T-cells considering the impact of antiviral drug treatment
DOI10.1016/j.amc.2022.127319OpenAlexW4283592854WikidataQ113880710 ScholiaQ113880710MaRDI QIDQ2152718
Publication date: 11 July 2022
Published in: Applied Mathematics and Computation (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.amc.2022.127319
nonlinear differential equationsBessel polynomialsCaputo's fractional derivativecollocation pointstechnique of quasilinearizationerror and convergence analysisfractional-order HIV-1 infection model of CD\(4^+\) T-cells
Numerical methods for ordinary differential equations (65Lxx) General theory for ordinary differential equations (34Axx) Physiological, cellular and medical topics (92Cxx)
Related Items (2)
Cites Work
- A numerical approach to solve the model for HIV infection of CD4\(^{+}\)T cells
- Numerical solutions of fractional Riccati type differential equations by means of the Bernstein polynomials
- The Laplace Adomian decomposition method for solving a model for HIV infection of \(CD4^{+}T\) cells
- On the numerical solution of the model for HIV infection of \(CD4^{+}\) T cells
- Numerical treatment of the model for HIV infection of CD4\(^{+}\)T cells by using multistep Laplace Adomian decomposition method
- The modeling dynamics of HIV and CD4\(^{+}\) T-cells during primary infection in fractional order: numerical simulation
- Generalized Taylor's formula
- Stability analysis of an HIV/AIDS epidemic model with treatment
- A delay-differential equation model of HIV infection of \(\text{CD}4^+\) T-cells
- The fractional differential model of HIV-1 infection of CD4\(^+\) T-cells with description of the effect of antiviral drug treatment
- Numerical solutions of hyperbolic telegraph equation by using the Bessel functions of first kind and residual correction
- A new fractional analysis on the interaction of HIV with \(\text{CD4}^+\) T-cells
- A Galerkin-type method for solving a delayed model on HIV infection of CD4\(^+\) T-cells
- Dynamics of HIV infection of CD4\(^ +\) T cells
- A novel algorithm based on the Legendre wavelets spectral technique for solving the Lane-Emden equations
- Analysis of the model of HIV-1 infection of \(CD4^+\) T-cell with a new approach of fractional derivative
- Two novel Bessel matrix techniques to solve the squeezing flow problem between infinite parallel plates
- Study of HIV mathematical model under nonsingular kernel type derivative of fractional order
- Investigating a nonlinear dynamical model of COVID-19 disease under fuzzy Caputo, random and ABC fractional order derivative
- A discontinuous finite element approximation to singular Lane-Emden type equations
- An efficient approximation technique applied to a non-linear Lane-Emden pantograph delay differential model
- Collocation method based on rational Legendre functions for solving the magneto-hydrodynamic flow over a nonlinear stretching sheet
- An exponential collocation method for the solutions of the HIV infection model of CD4+T cells
- MODELING THE DRUG THERAPY FOR HIV INFECTION
- Lucas polynomial solution of nonlinear differential equations with variable delays
- Mathematical analysis of HIV/AIDS infection model with Caputo-Fabrizio fractional derivative
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