Load- and Renewable-Following Control of Linearization-Free Differential Algebraic Equation Power System Models

Electromechanical transients in power networks are mostly caused by a mismatch between power consumption and production, causing generators to deviate from the nominal frequency. To that end, feedback control algorithms have been designed to perform frequency and load/renewable-following control. In...

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Bibliographic Details
Published in:IEEE transactions on control systems technology 2023-07, Vol.31 (4), p.1774-1786
Main Authors: Nugroho, Sebastian A., Taha, Ahmad F.
Format: Article
Language:English
Subjects:
Algebra
Algorithms
Constraint modelling
Control algorithms
Control systems design
Control theory
Controllers
Differential algebraic equations (DAEs)
Differential equations
Feedback control
Frequency control
frequency regulation
Generators
Linear quadratic regulator
Linearization
load-following control (LFC)
Mathematical models
Power consumption
Power flow
power networks
Power system dynamics
Power system stability
Renewable energy sources
Stability analysis
System theory
Systems theory
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Summary:Electromechanical transients in power networks are mostly caused by a mismatch between power consumption and production, causing generators to deviate from the nominal frequency. To that end, feedback control algorithms have been designed to perform frequency and load/renewable-following control. In particular, the literature addressed a plethora of grid- and frequency-control challenges with a focus on linearized, differential equation models whereby algebraic constraints [i.e., power flows (PFs)] are eliminated. This is in contrast to the more realistic nonlinear differential algebraic equation (NDAE) models. Yet, as grids are increasingly pushed to their limits via intermittent renewables and varying loads, their physical states risk escaping operating regions due to either a poor prediction or sudden changes in renewables or demands-deeming a feedback controller based on a linearization point virtually unusable. In lieu of linearized differential equation models, the objective of this article is to design a simple, purely decentralized, linearization-free, feedback control law for the NDAE models of power networks. The aim of such a controller is to primarily stabilize frequency oscillations after a significant, unknown disturbance in renewables or loads. Although the controller design involves advanced NDAE system theory, the controller itself is as simple as a decentralized proportional or linear quadratic regulator (LQR) in its implementation. Case studies demonstrate that the proposed controller is able to stabilize dynamic and algebraic states under significant disturbances.
ISSN:1063-6536
1558-0865
DOI:10.1109/TCST.2023.3244492