Abstract
We present a semilocal convergence study of Newton-type methods on a generalized Banach space setting to approximate a locally unique zero of an operator. Earlier studies require that the operator involved is Fréchet differentiable. In the present study we assume that the operator is only continuous. This way we extend the applicability of Newton-type methods to include fractional calculus and problems from other areas. Moreover, under the same or weaker conditions, we obtain weaker sufficient convergence criteria, tighter error bounds on the distances involved and an at least as precise information on the location of the solution. Special cases are provided where the old convergence criteria cannot apply but the new criteria can apply to locate zeros of operators. Some applications include fractional calculus involving the Riemann-Liouville fractional integral and the Caputo fractional derivative. Fractional calculus is very important for its applications in many applied sciences.
Highlights
We present a semilocal convergence analysis for Newton-type methods on a generalized Banach space setting to approximate a zero of an operator
Algorithms 2015, 8 as [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16] for Newton’s method have shown that a more precise convergence analysis is obtained when compared with the real norm theory
The main assumption is that the operator involved is Fréchet differentiable
Summary
We present a semilocal convergence analysis for Newton-type methods on a generalized Banach space setting to approximate a zero of an operator. The main assumption is that the operator involved is Fréchet differentiable This hypothesis limits the applicability of Newton’s method. In the present study we only assume the continuity of the operator This may be expand the applicability of these methods. We obtain the following advantages over the earlier mentioned studies using Newton’s method:.
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