A Proximal Method for Composite Optimization with Smooth and Convex Components

Abstract

We introduce prox-convex for minimizing F(x)=g(x)+h(C(x))+s(R(x)), where g and h are convex, C and s are smooth, and each component of R is convex (possibly nonsmooth). Here g captures general convex objectives and indicator functions for convex constraints, while the composite template simultaneously models convex penalties on smooth features (h C) and smooth couplings of convex (possibly nonsmooth) features (s R). Each prox-convex step forms a convex subproblem by linearizing only the smooth maps while preserving the existing convex structure. The resulting subproblem is made strongly convex with the proximal metric Qk=μk I+Hk+ 0 where μk is adapted using an implicit trust-region strategy, and Hk+ 0 is an optional curvature term for local acceleration. Under mild Lipschitz/smoothness and a per-coordinate monotone-or-smooth condition, we prove subdifferential regularity, derive two-sided quadratic model error bounds with explicit constants, and obtain sufficient decrease with O(-2) complexity for driving the norm of the metric prox-gradient below . Furthermore, a local error-bound condition for F guarantees a metric step-size error bound and hence local Q-linear convergence of the function values. Using the Taylor-like model framework of Drusvyatskiy, Ioffe, and Lewis, we show that every cluster point of the iterates is limiting-stationary; under our regularity conditions, this further implies Fr\'echet stationarity. The same framework also establishes robustness to inexact subproblem solves and justifies a model-decrease termination rule.

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