A Time Decomposition and Coordination Strategy for Power System Multi-Interval Operation
Abstract
This paper presents a time decomposition strategy to reduce the computational complexity of power system multi-interval operation problems. We focus on the economic dispatch problem. The considered scheduling horizon is decomposed into multiple smaller sub-horizons. The first time interval of each sub-horizon is modeled as the coupling interval between two consecutive sub-horizons. The interdependencies between the sub-horizons are mathematically modeled using ramp rates of generating units. A distributed coordination strategy, which is based on auxiliary problem principle, is developed to coordinate the economic dispatch solutions of the sub-horizons to find an optimal solution for the whole operation horizon. We also propose an initializing technique to start the iterative coordination algorithm from a good-enough point. This technique enhances the convergence rate significantly. The proposed algorithm is deployed to solve a week-ahead economic dispatch problem on the IEEE 118-bus system, and promising results are obtained.
Cite
@article{arxiv.1805.10185,
title = {A Time Decomposition and Coordination Strategy for Power System Multi-Interval Operation},
author = {Farnaz Safdarian and Okan Ciftci and Amin Kargarian},
journal= {arXiv preprint arXiv:1805.10185},
year = {2019}
}
Comments
5 pages, 4 figures, IEEE PES General Meeting (GM), August 5-9 2018, Portland, Oregon, USA