Article
Open Access
Faedo-Galerkin approximation of mild solutions of fractional functional differential equations
-
J. Vanterler da C. Sousa
,
Michal Fečkan
Published/Copyright:
January 29, 2021
Received: 2019-12-20
Accepted: 2021-01-17
Published Online: 2021-01-29
Published in Print: 2021-01-01
© 2021 J. Vanterler da C. Sousa et al., published by De Gruyter
Articles in the same Issue
- Faedo-Galerkin approximation of mild solutions of fractional functional differential equations
- The mutual singularity of the relative multifractal measures
- Quasi-stability and continuity of attractors for nonlinear system of wave equations
- Reduction principle at work
- Analysis of infectious disease transmission and prediction through SEIQR epidemic model
- Nonlocal Initial Value Problem for Hybrid Generalized Hilfer-type Fractional Implicit Differential Equations
- Existence results to a ψ- Hilfer neutral fractional evolution equation with infinite delay
- A General Multipatch Model of Ebola Dynamics
- Multi-dimensional (ω, c)-almost periodic type functions and applications
- Prey-predator model in drainage system with migration and harvesting
- Delay-Dependent Stability Conditions for Non-autonomous Functional Differential Equations with Several Delays in a Banach Space
- Existence of renormalized solutions for some quasilinear elliptic Neumann problems
- Polynomial stability of the wave equation with distributed delay term on the dynamical control
- Oscillation Results for Third-Order Semi-Canonical Quasi-Linear Delay Differential Equations
- Non-Oscillating solutions of a generalized system of ODEs with derivative terms
- Effect of population migration and punctuated lockdown on the spread of infectious diseases
- A temperature-dependent mathematical model of malaria transmission with stage-structured mosquito population dynamics
- Positive solutions of nonlinear fourth order iterative differential equations with two-point and integral boundary conditions
- A study of stability of SEIHR model of infectious disease transmission
- Resonant mixed fractional-order p-Laplacian boundary value problem on the half-line
Keywords for this article
Fractional differential equations;
existence and uniqueness;
mild solution;
Faedo-Galerkin approximation;
Gronwall inequality
Creative Commons
BY 4.0
Articles in the same Issue
- Faedo-Galerkin approximation of mild solutions of fractional functional differential equations
- The mutual singularity of the relative multifractal measures
- Quasi-stability and continuity of attractors for nonlinear system of wave equations
- Reduction principle at work
- Analysis of infectious disease transmission and prediction through SEIQR epidemic model
- Nonlocal Initial Value Problem for Hybrid Generalized Hilfer-type Fractional Implicit Differential Equations
- Existence results to a ψ- Hilfer neutral fractional evolution equation with infinite delay
- A General Multipatch Model of Ebola Dynamics
- Multi-dimensional (ω, c)-almost periodic type functions and applications
- Prey-predator model in drainage system with migration and harvesting
- Delay-Dependent Stability Conditions for Non-autonomous Functional Differential Equations with Several Delays in a Banach Space
- Existence of renormalized solutions for some quasilinear elliptic Neumann problems
- Polynomial stability of the wave equation with distributed delay term on the dynamical control
- Oscillation Results for Third-Order Semi-Canonical Quasi-Linear Delay Differential Equations
- Non-Oscillating solutions of a generalized system of ODEs with derivative terms
- Effect of population migration and punctuated lockdown on the spread of infectious diseases
- A temperature-dependent mathematical model of malaria transmission with stage-structured mosquito population dynamics
- Positive solutions of nonlinear fourth order iterative differential equations with two-point and integral boundary conditions
- A study of stability of SEIHR model of infectious disease transmission
- Resonant mixed fractional-order p-Laplacian boundary value problem on the half-line
