Convergence analysis of a proximal-type algorithm for DC programs with applications to variable selection

Abstract

We consider a minimization problem of the form P(, g, h): \f(x):= (x) + g(x) - h(x) x ∈ Rn\, where is a differentiable function and g, h are convex functions, and introduce iterative methods to finding a critical point of f when f is differentiable. We show that the point computed by proximal point algorithm at each iteration can be used to determine a descent direction for the objective function at this point. This algorithm can be considered as a combination of proximal point algorithm together with a linesearch step that uses this descent direction. We also study convergence results of these algorithms and the inertial proximal methods proposed by Mainge and Moudafi (SIAM J. Optim. 19(2008), 397--413) under the main assumption that the objective function satisfies the Kurdika--ojasiewicz property. The proposed algorithm is then applied to solve the variable selection problem in linear regression.