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Contingency Analysis Based on Partitioned and Parallel Holomorphic Embedding

Rui Yao, Feng Qiu, Kai Sun

2021IEEE Transactions on Power Systems15 citationsDOIOpen Access PDF

Abstract

In the steady-state contingency analysis, the traditional Newton-Raphson method suffers from non-convergence issues when solving post-outage power flow problems, which hinders the integrity and accuracy of security assessment. In this paper, we propose a novel robust contingency analysis approach based on holomorphic embedding (HE). The HE-based simulator provides theoretical convergence guarantee, which is desirable because it avoids the influence of numerical issues and provides a credible security assessment conclusion. In addition, based on the multi-area characteristics of real-world power systems, a partitioned HE (PHE) method is proposed with an interface-based partitioning of HE formulation. The PHE method does not undermine the numerical robustness of HE and significantly reduces the computation burden in large-scale contingency analysis. The PHE method is further enhanced by parallel or distributed computation to become parallel PHE (P <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sup> HE). Tests on a 458-bus system, a synthetic 419-bus system and a large-scale 21 447-bus system demonstrate the advantages of the proposed methods in robustness and efficiency.

Topics & Concepts

Robustness (evolution)ComputationComputer scienceEmbeddingElectric power systemContingencyNewton's methodMathematical optimizationConvergence (economics)Power flowAlgorithmPower (physics)MathematicsArtificial intelligenceLinguisticsEconomicsEconomic growthGeneNonlinear systemChemistryPhilosophyBiochemistryQuantum mechanicsPhysicsPower System Optimization and StabilityOptimal Power Flow DistributionHVDC Systems and Fault Protection