English

Viscosity approximation method for a variational problem

Dynamical Systems 2022-09-22 v1

Abstract

Let QQ be a nonempty closed and convex subset of a real Hilbert space % \mathcal{H}, S:QQS:Q\rightarrow Q a nonexpansive mapping, A:QQA:Q\rightarrow Q an inverse strongly monotone operator, and f:QQf:Q\rightarrow Q a contraction mapping. We prove, under appropriate conditions on the real sequences % \{\alpha_{n}\} and {λn},\{\lambda_{n}\}, that for any starting point x1x_{1} in Q,Q, the sequence {xn}\{x_{n}\} generated by the iterative process \begin{equation} x_{n+1}=\alpha_{n}f(x_{n})+(1-\alpha_{n})SP_{Q}(x_{n}-\lambda_{n}Ax_{n}) \label{Alg} \end{equation} converges strongly to a particular element of the set Fix(S)SVI(A,Q)F_{ix}(S)\cap S_{VI(A,Q)} which we suppose that it is nonempty, where Fix(S)F_{ix}(S) is the set of fixed point of the mapping % S and SVI(A,Q)S_{VI(A,Q)} is the set of qQq\in Q such that Aq,xq0\langle Aq,x-q\rangle\geq0 for every xQ.x\in 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}\{\alpha_{n}\} on the convergence rate of this algorithm.

Keywords

Cite

@article{arxiv.2209.10202,
  title  = {Viscosity approximation method for a variational problem},
  author = {Ramzi May},
  journal= {arXiv preprint arXiv:2209.10202},
  year   = {2022}
}

Comments

16 pages, 1 figure

R2 v1 2026-06-28T01:48:00.362Z