Numerical Integration of Stiff Differential Systems Using Non-Fixed Step-Size Strategy

Abstract: Over the years, researches have shown that fixed (constant) step-size methods have been efficient in integrating a stiff differential system. It has however been observed that for some stiff differential systems, non-fixed (variable) step-size methods are required for efficiency and for accuracy to be attained. This is because such systems have solution components that decay rapidly and/or slowly than others over a given integration interval. In order to curb this challenge, there is a need to propose a method… Show more

“…Furthermore, adapted time-stepping strategies can be extremely useful to better follow the dynamics of highly deformable interfaces [72,73]. The adpted step sizes can be calculated if an appropriate local error estimate is available.…”

Computational Modeling of Individual Red Blood Cell Dynamics Using Discrete Flow Composition and Adaptive Time-Stepping Strategies

“…Furthermore, adapted time-stepping strategies can be extremely useful to better follow the dynamics of highly deformable interfaces [72,73]. The adpted step sizes can be calculated if an appropriate local error estimate is available.…”

Computational Modeling of Individual Red Blood Cell Dynamics Using Discrete Flow Composition and Adaptive Time-Stepping Strategies

“…Sunday et al [3] deal with step-size methods for integrating stiff differential systems. Hence, they present a method that can vary the step size within a defined integration interval using a Lagrange interpolation polynomial as a basis function via its integration at selected limits.…”

Symmetry in Ordinary and Partial Differential Equations and Applications

A computational approach to solving some applied rigid second-order problems