Achieving Optimal Order in a Novel Family of Numerical Methods: Insights from Convergence and Dynamical Analysis Results

In this manuscript, we introduce a novel parametric family of multistep iterative methods designed to solve nonlinear equations. This family is derived from a damped Newton’s scheme but includes an additional Newton step with a weight function and a “frozen” derivative, that is, the same derivative...

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Bibliographic Details
Published inAxioms Vol. 13; no. 7; p. 458
Main Authors Moscoso-Martínez, Marlon, Chicharro, Francisco I., Cordero, Alicia, Torregrosa, Juan R., Ureña-Callay, Gabriela
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.07.2024
Subjects
Convergence
convergence analysis
Derivatives
Differential equations, Nonlinear
dynamical study
Efficiency
Fixed points (mathematics)
Iterative methods
Iterative methods (Mathematics)
Mathematical analysis
Methods
Nonlinear equations
Numerical analysis
Numerical methods
optimal iterative methods
Orbital stability
Polynomials
Problem solving
stability
Surface stability
Weighting functions
Spain
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Summary:In this manuscript, we introduce a novel parametric family of multistep iterative methods designed to solve nonlinear equations. This family is derived from a damped Newton’s scheme but includes an additional Newton step with a weight function and a “frozen” derivative, that is, the same derivative than in the previous step. Initially, we develop a quad-parametric class with a first-order convergence rate. Subsequently, by restricting one of its parameters, we accelerate the convergence to achieve a third-order uni-parametric family. We thoroughly investigate the convergence properties of this final class of iterative methods, assess its stability through dynamical tools, and evaluate its performance on a set of test problems. We conclude that there exists one optimal fourth-order member of this class, in the sense of Kung–Traub’s conjecture. Our analysis includes stability surfaces and dynamical planes, revealing the intricate nature of this family. Notably, our exploration of stability surfaces enables the identification of specific family members suitable for scalar functions with a challenging convergence behavior, as they may exhibit periodical orbits and fixed points with attracting behavior in their corresponding dynamical planes. Furthermore, our dynamical study finds members of the family of iterative methods with exceptional stability. This property allows us to converge to the solution of practical problem-solving applications even from initial estimations very far from the solution. We confirm our findings with various numerical tests, demonstrating the efficiency and reliability of the presented family of iterative methods.
ISSN:2075-1680
2075-1680
DOI:10.3390/axioms13070458