On Josephy-Halley method for generalized equations
Abstract
We extend the classical third-order Halley iteration to the setting of generalized equations of the form \[ 0 ∈ f(x) + F(x), \] where \(f X Y\) is twice continuously Fr\'echet-differentiable on Banach spaces and \(F X Y\) is a set-valued mapping with closed graph. Building on predictor-corrector framework, our scheme first solves a partially linearized inclusion to produce a predictor \(uk+1\), then incorporates second-order information in a Halley-type corrector step to obtain \(xk+1\). Under metric regularity of the linearization at a reference solution and H\"older continuity of \(f''\), we prove that the iterates converge locally with order \(2+p\) (cubically when \(p=1\)). Moreover, by constructing a suitable scalar majorant function we derive semilocal Kantorovich-type conditions guaranteeing well-definedness and R-cubic convergence from an explicit neighbourhood of the initial guess. Numerical experiments-including one- and two-dimensional test problems confirm the theoretical convergence rates and illustrate the efficiency of the Josephy-Halley method compared to its Josephy-Newton counterpart.
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