English

Dual Prediction-Correction Methods for Linearly Constrained Time-Varying Convex Programs

Optimization and Control 2020-01-09 v2

Abstract

Devising efficient algorithms to solve continuously-varying strongly convex optimization programs is key in many applications, from control systems to signal processing and machine learning. In this context, solving means to find and track the optimizer trajectory of the continuously-varying convex optimization program. Recently, a novel prediction-correction methodology has been put forward to set up iterative algorithms that sample the continuously-varying optimization program at discrete time steps and perform a limited amount of computations to correct their approximate optimizer with the new sampled problem and predict how the optimizer will change at the next time step. Prediction-correction algorithms have been shown to outperform more classical strategies, i.e., correction-only methods. Typically, prediction-correction methods have asymptotic tracking errors of the order of h2h^2, where hh is the sampling period, whereas classical strategies have order of hh. Up to now, Prediction-correction algorithms have been developed in the primal space, both for unconstrained and simply constrained convex programs. In this paper, we show how to tackle linearly constrained continuously-varying problem by prediction-correction in the dual space and we prove similar asymptotic error bounds as their primal versions.

Keywords

Cite

@article{arxiv.1709.05850,
  title  = {Dual Prediction-Correction Methods for Linearly Constrained Time-Varying Convex Programs},
  author = {Andrea Simonetto},
  journal= {arXiv preprint arXiv:1709.05850},
  year   = {2020}
}

Comments

14 pages, 5 figures; updated version of v1 with corrected typos and new simulations

R2 v1 2026-06-22T21:46:38.684Z