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Voltage Stability Margin Index Estimation Using a Hybrid Kernel Extreme Learning Machine Approach

Walter M. Villa-Acevedo, Jesús M. López‐Lezama, D. G. Colomé

2020Energies26 citationsDOIOpen Access PDF

Abstract

This paper presents a novel approach for Voltage Stability Margin (VSM) estimation that combines a Kernel Extreme Learning Machine (KELM) with a Mean-Variance Mapping Optimization (MVMO) algorithm. Since the performance of a KELM depends on a proper parameter selection, the MVMO is used to optimize such task. In the proposed MVMO-KELM model the inputs and output are the magnitudes of voltage phasors and the VSM index, respectively. A Monte Carlo simulation was implemented to build a data base for the training and validation of the model. The data base considers different operative scenarios for three type of customers (residential commercial and industrial) as well as N-1 contingencies. The proposed MVMO-KELM model was validated with the IEEE 39 bus power system comparing its performance with a support vector machine (SVM) and an Artificial Neural Network (ANN) approach. Results evidenced a better performance of the proposed MVMO-KELM model when compared to such techniques. Furthermore, the higher robustness of the MVMO-KELM was also evidenced when considering noise in the input data.

Topics & Concepts

Support vector machineRobustness (evolution)Extreme learning machineComputer scienceArtificial neural networkMargin (machine learning)Stability (learning theory)Electric power systemKernel (algebra)VoltageFeature selectionArtificial intelligenceMachine learningEngineeringPower (physics)MathematicsGeneQuantum mechanicsPhysicsCombinatoricsElectrical engineeringBiochemistryChemistryMachine Learning and ELMOptimal Power Flow DistributionMicrogrid Control and Optimization