Deep-Learning-Enhanced Static Risk-Oriented Security Assessment under Uncertainty

A power system's ability to supply resources to maintain continuous service to demand, known as generation (resource) adequacy, is an essential constituent of power system planning. Tools and methods to quantify adequacy are fundamental to launching emergency control actions beforehand. As the...

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Published in2024 IEEE Power & Energy Society General Meeting (PESGM) pp. 1 - 5
Main Authors Masoumi, Amin, Korkali, Mert
Format Conference Proceeding
LanguageEnglish
Published IEEE 21.07.2024
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Abstract A power system's ability to supply resources to maintain continuous service to demand, known as generation (resource) adequacy, is an essential constituent of power system planning. Tools and methods to quantify adequacy are fundamental to launching emergency control actions beforehand. As the role of variable renewable energy grows in a decarbonized environment, managing resource diversity over large geographic areas is becoming increasingly critical to maintaining reliability and security, requiring one to revisit the methods to keep up with the changing resource mix and demand. This complexity is exacerbated by prolonged contingencies, inducing system risks. To this end, we propose a fully deep-learning (DL) architecture to overcome the complexity by striking a balance between accuracy and computational speed. The simulation results on the IEEE RTS-GMLC test system strongly favor the DL-based assessment compared to conventional and machine-learning-based counter-parts.
AbstractList A power system's ability to supply resources to maintain continuous service to demand, known as generation (resource) adequacy, is an essential constituent of power system planning. Tools and methods to quantify adequacy are fundamental to launching emergency control actions beforehand. As the role of variable renewable energy grows in a decarbonized environment, managing resource diversity over large geographic areas is becoming increasingly critical to maintaining reliability and security, requiring one to revisit the methods to keep up with the changing resource mix and demand. This complexity is exacerbated by prolonged contingencies, inducing system risks. To this end, we propose a fully deep-learning (DL) architecture to overcome the complexity by striking a balance between accuracy and computational speed. The simulation results on the IEEE RTS-GMLC test system strongly favor the DL-based assessment compared to conventional and machine-learning-based counter-parts.
Author Korkali, Mert
Masoumi, Amin
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  givenname: Mert
  surname: Korkali
  fullname: Korkali, Mert
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  organization: University of Missouri,Columbia,MO,USA,65211
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Snippet A power system's ability to supply resources to maintain continuous service to demand, known as generation (resource) adequacy, is an essential constituent of...
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SubjectTerms Accuracy
Complexity theory
Computer architecture
Contingency management
deep learning
generation (resource) adequacy
Power system reliability
Reliability
Scalability
Security
Simulation
Static security assessment
Uncertainty
uncertainty and contingency modeling
Title Deep-Learning-Enhanced Static Risk-Oriented Security Assessment under Uncertainty
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