Model-Free Primal-Dual Methods for Network Optimization with Application to Real-Time Optimal Power Flow: Preprint

Yue Chen, Andrey Bernstein, Adithya Devraj, Sean Meyn

Research output: Contribution to conferencePaper

Abstract

This paper examines the problem of real-time optimization of networked systems and develops online algorithms that steer the system towards the optimal trajectory without explicit knowledge of the system model. The problem is modeled as a dynamic optimization problem with time-varying performance objectives and engineering constraints. The design of the algorithms leverages the online zero-order primal-dual projected-gradient method. In particular, the primal step that involves the gradient of the objective function (and hence requires networked systems model) is replaced by its zero-order approximation with two function evaluations using a deterministic perturbation signal. The evaluations are performed using the measurements of the system output, hence giving rise to a feedback interconnection, with the optimization algorithm serving as a feedback controller. The paper provides some insights on the stability and tracking properties of this interconnection. Finally, the paper applies this methodology to a real-time optimal power flow problem in power systems, and shows its efficacy on the IEEE 37-node distribution test feeder for reference power tracking and voltage regulation.
Original languageAmerican English
Number of pages11
StatePublished - 2020
Event2020 American Control Conference (ACC) -
Duration: 1 Jul 20203 Jul 2020

Conference

Conference2020 American Control Conference (ACC)
Period1/07/203/07/20

Bibliographical note

See NREL/CP-5D00-77797 for paper as published in proceedings

NREL Publication Number

  • NREL/CP-5D00-76338

Keywords

  • model-free
  • OPF
  • optimal power flow
  • optimization
  • primal-dual

Fingerprint

Dive into the research topics of 'Model-Free Primal-Dual Methods for Network Optimization with Application to Real-Time Optimal Power Flow: Preprint'. Together they form a unique fingerprint.

Cite this