Extended Convergence of a Two-Step-Secant-Type Method Under a Restricted Convergence Domain
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Authors: I. K. ARGYROS AND S. GEORGE
DOI: 10.46793/KgJMat2101.155A
Abstract:
We present a local as well as a semi-local convergence analysis of a two-step secant-type method for solving nonlinear equations involving Banach space valued operators. By using weakened Lipschitz and center Lipschitz conditions in combination with a more precise domain containing the iterates, we obtain tighter Lipschitz constants than in earlier studies. This technique lead to an extended convergence domain, more precise information on the location of the solution and tighter error bounds on the distances involved. These advantages are obtained under the same computational effort, since the new constants are special cases of the old ones used in earlier studies. The new technique can be used on other iterative methods. The numerical examples further illustrate the theoretical results.
Keywords:
Two step secant-type method, local convergence, Banach space, restricted convergence domain, divided difference.
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