Derivative-Free Finite-Difference Homeier Method for Nonlinear Models

Yanal Al-Shorman; Obadah Said Solaiman; Ishak Hashim

doi:10.1007/978-3-031-21700-5_11

Derivative-Free Finite-Difference Homeier Method for Nonlinear Models

Yanal Al-Shorman
, Obadah Said Solaiman
, Ishak Hashim

Universiti Kebangsaan Malaysia

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

An efficient derivative-free method for determining roots with respect to nonlinear equations was implemented in this paper. The third-order Homeier’s method has been taken as the basis for this work, which can be derived by employing Newton’s theorem for the inverse function as well as deriving a new class of cubically convergent Newton-type methods. Several nonlinear problems, including nonlinear equations, complex equations, and nonlinear systems of equations, have been considered in order to perform a comparison with regard to the efficiency of the suggested method to other popular derivative-free schemes. Results show that the proposed method Derivative-Free Homeier method (DFH) outperformed the considered published methods. The DFH needs fewer iterations to achieve the desired solution, with an order of convergence of about 2.4, which is higher than the convergence order with regard to the methods that were compared. Here, one of the popular nonlinear equation solvers used to compare with our proposed method is the secant method having a convergence order of 1.618 in the derivative’s absence. Furthermore, by adhering to the steps of Broyden’s method when utilizing the DFH to solve systems of nonlinear equations, the Jacobian problem can be averted. Therefore, the DFH can be considered as an uppermost method giving faster convergence to determine the nonlinear equations’ roots with no derivative for uni-variate nonlinear equations having complex roots, including multivariate systems of nonlinear equations.

Original language	English
Title of host publication	Mathematical Methods for Engineering Applications - ICMASE 2022
Editors	Fatih Yilmaz, Araceli Queiruga-Dios, Jesús Martín Vaquero, Ion Mierluş-Mazilu, Deolinda Rasteiro, Víctor Gayoso Martínez
Publisher	Springer
Pages	105-112
Number of pages	8
ISBN (Print)	9783031216992
DOIs	https://doi.org/10.1007/978-3-031-21700-5_11
State	Published - 2023
Externally published	Yes
Event	3rd International Conference on Mathematics and its Applications in Science and Engineering, ICMASE 2022 - Bucharest, Romania Duration: 4 Jul 2022 → 7 Jul 2022

Publication series

Name	Springer Proceedings in Mathematics and Statistics
Volume	414
ISSN (Print)	2194-1009
ISSN (Electronic)	2194-1017

Conference

Conference	3rd International Conference on Mathematics and its Applications in Science and Engineering, ICMASE 2022
Country/Territory	Romania
City	Bucharest
Period	4/07/22 → 7/07/22

Keywords

Broyden’s method
Derivative-free methods
Homeier method
Iterative methods
Nonlinear equations
Order of convergence
Secant method

Access to Document

10.1007/978-3-031-21700-5_11

Cite this

Al-Shorman, Y., Said Solaiman, O., & Hashim, I. (2023). Derivative-Free Finite-Difference Homeier Method for Nonlinear Models. In F. Yilmaz, A. Queiruga-Dios, J. Martín Vaquero, I. Mierluş-Mazilu, D. Rasteiro, & V. Gayoso Martínez (Eds.), Mathematical Methods for Engineering Applications - ICMASE 2022 (pp. 105-112). (Springer Proceedings in Mathematics and Statistics; Vol. 414). Springer. https://doi.org/10.1007/978-3-031-21700-5_11

Al-Shorman, Yanal ; Said Solaiman, Obadah ; Hashim, Ishak. / Derivative-Free Finite-Difference Homeier Method for Nonlinear Models. Mathematical Methods for Engineering Applications - ICMASE 2022. editor / Fatih Yilmaz ; Araceli Queiruga-Dios ; Jesús Martín Vaquero ; Ion Mierluş-Mazilu ; Deolinda Rasteiro ; Víctor Gayoso Martínez. Springer, 2023. pp. 105-112 (Springer Proceedings in Mathematics and Statistics).

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title = "Derivative-Free Finite-Difference Homeier Method for Nonlinear Models",

abstract = "An efficient derivative-free method for determining roots with respect to nonlinear equations was implemented in this paper. The third-order Homeier{\textquoteright}s method has been taken as the basis for this work, which can be derived by employing Newton{\textquoteright}s theorem for the inverse function as well as deriving a new class of cubically convergent Newton-type methods. Several nonlinear problems, including nonlinear equations, complex equations, and nonlinear systems of equations, have been considered in order to perform a comparison with regard to the efficiency of the suggested method to other popular derivative-free schemes. Results show that the proposed method Derivative-Free Homeier method (DFH) outperformed the considered published methods. The DFH needs fewer iterations to achieve the desired solution, with an order of convergence of about 2.4, which is higher than the convergence order with regard to the methods that were compared. Here, one of the popular nonlinear equation solvers used to compare with our proposed method is the secant method having a convergence order of 1.618 in the derivative{\textquoteright}s absence. Furthermore, by adhering to the steps of Broyden{\textquoteright}s method when utilizing the DFH to solve systems of nonlinear equations, the Jacobian problem can be averted. Therefore, the DFH can be considered as an uppermost method giving faster convergence to determine the nonlinear equations{\textquoteright} roots with no derivative for uni-variate nonlinear equations having complex roots, including multivariate systems of nonlinear equations.",

keywords = "Broyden{\textquoteright}s method, Derivative-free methods, Homeier method, Iterative methods, Nonlinear equations, Order of convergence, Secant method",

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Al-Shorman, Y, Said Solaiman, O & Hashim, I 2023, Derivative-Free Finite-Difference Homeier Method for Nonlinear Models. in F Yilmaz, A Queiruga-Dios, J Martín Vaquero, I Mierluş-Mazilu, D Rasteiro & V Gayoso Martínez (eds), Mathematical Methods for Engineering Applications - ICMASE 2022. Springer Proceedings in Mathematics and Statistics, vol. 414, Springer, pp. 105-112, 3rd International Conference on Mathematics and its Applications in Science and Engineering, ICMASE 2022, Bucharest, Romania, 4/07/22. https://doi.org/10.1007/978-3-031-21700-5_11

Derivative-Free Finite-Difference Homeier Method for Nonlinear Models. / Al-Shorman, Yanal; Said Solaiman, Obadah; Hashim, Ishak.
Mathematical Methods for Engineering Applications - ICMASE 2022. ed. / Fatih Yilmaz; Araceli Queiruga-Dios; Jesús Martín Vaquero; Ion Mierluş-Mazilu; Deolinda Rasteiro; Víctor Gayoso Martínez. Springer, 2023. p. 105-112 (Springer Proceedings in Mathematics and Statistics; Vol. 414).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Hashim, Ishak

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N2 - An efficient derivative-free method for determining roots with respect to nonlinear equations was implemented in this paper. The third-order Homeier’s method has been taken as the basis for this work, which can be derived by employing Newton’s theorem for the inverse function as well as deriving a new class of cubically convergent Newton-type methods. Several nonlinear problems, including nonlinear equations, complex equations, and nonlinear systems of equations, have been considered in order to perform a comparison with regard to the efficiency of the suggested method to other popular derivative-free schemes. Results show that the proposed method Derivative-Free Homeier method (DFH) outperformed the considered published methods. The DFH needs fewer iterations to achieve the desired solution, with an order of convergence of about 2.4, which is higher than the convergence order with regard to the methods that were compared. Here, one of the popular nonlinear equation solvers used to compare with our proposed method is the secant method having a convergence order of 1.618 in the derivative’s absence. Furthermore, by adhering to the steps of Broyden’s method when utilizing the DFH to solve systems of nonlinear equations, the Jacobian problem can be averted. Therefore, the DFH can be considered as an uppermost method giving faster convergence to determine the nonlinear equations’ roots with no derivative for uni-variate nonlinear equations having complex roots, including multivariate systems of nonlinear equations.

AB - An efficient derivative-free method for determining roots with respect to nonlinear equations was implemented in this paper. The third-order Homeier’s method has been taken as the basis for this work, which can be derived by employing Newton’s theorem for the inverse function as well as deriving a new class of cubically convergent Newton-type methods. Several nonlinear problems, including nonlinear equations, complex equations, and nonlinear systems of equations, have been considered in order to perform a comparison with regard to the efficiency of the suggested method to other popular derivative-free schemes. Results show that the proposed method Derivative-Free Homeier method (DFH) outperformed the considered published methods. The DFH needs fewer iterations to achieve the desired solution, with an order of convergence of about 2.4, which is higher than the convergence order with regard to the methods that were compared. Here, one of the popular nonlinear equation solvers used to compare with our proposed method is the secant method having a convergence order of 1.618 in the derivative’s absence. Furthermore, by adhering to the steps of Broyden’s method when utilizing the DFH to solve systems of nonlinear equations, the Jacobian problem can be averted. Therefore, the DFH can be considered as an uppermost method giving faster convergence to determine the nonlinear equations’ roots with no derivative for uni-variate nonlinear equations having complex roots, including multivariate systems of nonlinear equations.

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KW - Derivative-free methods

KW - Homeier method

KW - Iterative methods

KW - Nonlinear equations

KW - Order of convergence

KW - Secant method

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Al-Shorman Y, Said Solaiman O, Hashim I. Derivative-Free Finite-Difference Homeier Method for Nonlinear Models. In Yilmaz F, Queiruga-Dios A, Martín Vaquero J, Mierluş-Mazilu I, Rasteiro D, Gayoso Martínez V, editors, Mathematical Methods for Engineering Applications - ICMASE 2022. Springer. 2023. p. 105-112. (Springer Proceedings in Mathematics and Statistics). doi: 10.1007/978-3-031-21700-5_11