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access icon openaccess A Markov chain-based model for wind power prediction in congested electrical grids

This is an open access article published by the IET under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0/)
Received 26/10/2018, Accepted 05/12/2018, Published 15/03/2019

The large penetration of wind generators in existing electrical grids induces critical issues that are pushing the system operators to improve several critical operation functions, such as the security analysis and the spinning reserve assessment, with the purpose of mitigating the effects induced by the injected power profiles, which are ruled by the intermittent and not-programmable wind dynamics. Although numerous forecasting tools have been proposed in the literature to predict the generated power profiles in function of the estimated wind speed, further and more complex phenomena need to be investigated in order to take into account the effects of the forecasting uncertainty on power system operation. In order to deal with this issue, this paper proposes a probabilistic model based on Markov chains, which predicts the wind power profiles injected into the grid, considering the real generator model and the effects of the power curtailments imposed by the grid operator. Experimental results obtained on a real case study are presented and discussed in order to prove the effectiveness of the proposed method.

Inspec keywords: wind power; wind power plants; probability; power grids; Markov processes; power engineering computing

Other keywords: power system operation; generated power profiles; spinning reserve assessment; system operators; estimated wind speed; critical operation functions; wind generators; grid operator; injected power profiles; numerous forecasting tools; security analysis; congested electrical grids; Markov chains; generator model; Markov chain-based model; power curtailments; critical issues; penetration; forecasting uncertainty; complex phenomena; probabilistic model; wind power profiles; wind power prediction; not-programmable wind dynamics

Subjects: Other topics in statistics; Wind power plants; Probability theory, stochastic processes, and statistics; Power system management, operation and economics; Power engineering computing

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