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Higher-order families of multiple root finding methods suitable for non-convergent cases and their dynamics

    Ramandeep Behl Affiliation
    ; Vinay Kanwar Affiliation
    ; Young Ik Kim Affiliation

Abstract

In this paper, we present many new one-parameter families of classical Rall’s method (modified Newton’s method), Schröder’s method, Halley’s method and super-Halley method for the first time which will converge even though the guess is far away from the desired root or the derivative is small in the vicinity of the root and have the same error equations as those of their original methods respectively, for multiple roots. Further, we also propose an optimal family of iterative methods of fourth-order convergence and converging to a required root in a stable manner without divergence, oscillation or jumping problems. All the methods considered here are found to be more effective than the similar robust methods available in the literature. In their dynamical study, it has been observed that the proposed methods have equal or better stability and robustness as compared to the other methods.

Keyword : multiple roots, Rall’s method, Schröder’s method, super-Halley’s method, basins of attraction

How to Cite
Behl, R., Kanwar, V., & Kim, Y. I. (2019). Higher-order families of multiple root finding methods suitable for non-convergent cases and their dynamics. Mathematical Modelling and Analysis, 24(3), 422-444. https://doi.org/10.3846/mma.2019.026
Published in Issue
Jun 6, 2019
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This work is licensed under a Creative Commons Attribution 4.0 International License.

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