Viscosity approximation method for a variational problem

Abstract

Let Q be a nonempty closed and convex subset of a real Hilbert space % H, S:Q→ Q a nonexpansive mapping, A:Q→ Q an inverse strongly monotone operator, and f:Q→ Q a contraction mapping. We prove, under appropriate conditions on the real sequences % \αn\ and \λn\, that for any starting point x1 in Q, the sequence \xn\ generated by the iterative process equation xn+1=αnf(xn)+(1-αn)SPQ(xn-λnAxn) Alg equation converges strongly to a particular element of the set Fix(S) SVI(A,Q) which we suppose that it is nonempty, where Fix(S) is the set of fixed point of the mapping % S and SVI(A,Q) is the set of q∈ Q such that Aq,x-q≥0 for every x∈ Q. Moreover, we study the strong convergence of a perturbed version of the algorithm generated by the above process. Finally, we apply the main result to construct an algorithm associated to a constrained convex optimization problem and we provide a numerical experiment to emphasize the effect of the parameter \αn\ on the convergence rate of this algorithm.