Golden Ratio Algorithms for Variational Inequalities
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The paper presents a fully explicit algorithm for monotone variational inequalities. The method uses variable stepsizes that are computed using two previous iterates as an approximation of the local Lipschitz constant without running a linesearch. Thus, each iteration of the method requires only one evaluation of a monotone operator $F$ and a proximal mapping $g$. The operator $F$ need not be Lipschitz-continuous, which also makes the algorithm interesting in the area of composite minimization where one cannot use the descent lemma. The method exhibits an ergodic $O(1/k)$ convergence rate and $R$-linear rate, if $F, g$ satisfy the error bound condition. We discuss possible applications of the method to fixed point problems. We discuss possible applications of the method to fixed point problems as well as its different generalizations.
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Modified golden ratio algorithms for solving equilibrium problems
A modified golden ratio proximal algorithm solves pseudomonotone equilibrium problems with explicit steplengths, proven convergence, and R-linear rate under strong pseudomonotonicity.
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