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Scalable Designs for Reinforcement Learning-Based Wide-Area Damping Control

Sayak Mukherjee, Aranya Chakrabortty, He Bai, Atena Darvishi, B. Fardanesh

2021IEEE Transactions on Smart Grid30 citationsDOI

Abstract

This article discusses how techniques from reinforcement learning (RL) can be exploited to transition to a model-free and scalable wide-area oscillation damping control of power grids. We present two control architectures with distinct features. Performing full-dimensional RL control designs for any practical grid would require an unacceptably long learning time and result in a dense communication architecture. Our designs avoid the curse of dimensionality by employing ideas from model reduction. The first design exploits time-scale separation in the generator electro-mechanical dynamics arising from coherent clustering, and learns a controller using both electro-mechanical and non-electro-mechanical states while compensating for the error in incorporating the latter through the RL loop. The second design presents an output-feedback approach enabled by a neuro-adaptive observer using measurements of only the generator frequencies. The controller exhibits an adaptive behavior that updates the control gains whenever there is a notable change in the loads. Theoretical guarantees for closed-loop stability and performance are provided for both designs. Numerical simulations are shown for the IEEE 68-bus power system model.

Topics & Concepts

Reinforcement learningComputer scienceController (irrigation)ScalabilityControl theory (sociology)Curse of dimensionalityControl engineeringGridAdaptive controlEngineeringControl (management)Artificial intelligenceMathematicsGeometryDatabaseAgronomyBiologyPower System Optimization and StabilityMicrogrid Control and OptimizationAdaptive Dynamic Programming Control
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