A computational framework for risk-based power system operations under uncertainty. Part II: Case studies

Camille Hamon, Magnus Perninge, Lennart Söder

Research output: Contribution to journalArticlepeer-review

Abstract

With larger penetrations of wind power, the uncertainty increases in power systems operations. The wind power forecast errors must be accounted for by adapting existing operating tools or designing new ones. A switch from the deterministic framework used today to a probabilistic one has been advocated. This two-part paper presents a framework for risk-based operations of power systems. This framework builds on the operating risk defined as the probability of the system to be outside the stable operation domain, given probabilistic forecasts for the uncertainty, load and wind power generation levels. This operating risk can be seen as a probabilistic formulation of the N − 1 criterion. In Part I, the definition of the operating risk and a method to estimate it were presented. A new way of modeling the uncertain wind power injections was presented. In Part II of the paper, the method's accuracy and computational requirements are assessed for both models. It is shown that the new model for wind power introduced in Part I significantly decreases the computation time of the method, which allows for the use of later and more accurate forecasts. The method developed in this paper is able to tackle the two challenges associated with risk-based real-time operations: accurately estimating very low operating risks and doing so in a very limited amount of time.
Original languageEnglish
Pages (from-to)66-75
JournalElectric Power Systems Research
Volume119
DOIs
Publication statusPublished - 2015

Subject classification (UKÄ)

  • Electrical Engineering, Electronic Engineering, Information Engineering

Free keywords

  • Wind power
  • Stochastic optimal power flow
  • Risk-limiting dispatch
  • Chance-constrained optimal power flow
  • Edgeworth expansions
  • Risk-based methods ☆

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