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Your search keyword '"Misyris, Georgios S."' showing total 8 results
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8 results on '"Misyris, Georgios S."'

1. Transient Stability Analysis with Physics-Informed Neural Networks

Author

Stiasny, Jochen, Misyris, Georgios S., and Chatzivasileiadis, Spyros

Subjects
Computer Science - Machine Learning, Electrical Engineering and Systems Science - Systems and Control
Abstract

We explore the possibility to use physics-informed neural networks to drastically accelerate the solution of ordinary differential-algebraic equations that govern the power system dynamics. When it comes to transient stability assessment, the traditionally applied methods either carry a significant computational burden, require model simplifications, or use overly conservative surrogate models. Conventional neural networks can circumvent these limitations but are faced with high demand of high-quality training datasets, while they ignore the underlying governing equations. Physics-informed neural networks are different: they incorporate the power system differential algebraic equations directly into the neural network training and drastically reduce the need for training data. This paper takes a deep dive into the performance of physics-informed neural networks for power system transient stability assessment. Introducing a new neural network training procedure to facilitate a thorough comparison, we explore how physics-informed neural networks compare with conventional differential-algebraic solvers and classical neural networks in terms of computation time, requirements in data, and prediction accuracy. We illustrate the findings on the Kundur two-area system, and assess the opportunities and challenges of physics-informed neural networks to serve as a transient stability analysis tool, highlighting possible pathways to further develop this method., Comment: 9 pages, 8 figures

Published
2021

2. Capturing Power System Dynamics by Physics-Informed Neural Networks and Optimization

Author

Misyris, Georgios S., Stiasny, Jochen, and Chatzivasileiadis, Spyros

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

This paper proposes a tractable framework to determine key characteristics of non-linear dynamic systems by converting physics-informed neural networks to a mixed integer linear program. Our focus is on power system applications. Traditional methods in power systems require the use of a large number of simulations and other heuristics to determine parameters such as the critical clearing time, i.e. the maximum allowable time within which a disturbance must be cleared before the system moves to instability. The work proposed in this paper uses physics-informed neural networks to capture the power system dynamic behavior and, through an exact transformation, converts them to a tractable optimization problem which can be used to determine critical system indices. By converting neural networks to mixed integer linear programs, our framework also allows to adjust the conservativeness of the neural network output with respect to the existing stability boundaries. We demonstrate the performance of our methods on the non-linear dynamics of converter-based generation in response to voltage disturbances., Comment: 6 pages, 5 figures, submitted to the 60th IEEE conference on Decision and Control (CDC), 2021, Austin, Texas, USA

Published
2021

3. Zero-inertia Offshore Grids: N-1 Security and Active Power Sharing

Author

Misyris, Georgios S., Tosatto, Andrea, Chatzivasileiadis, Spyros, and Weckesser, Tilman

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

With Denmark dedicated to maintaining its leading position in the integration of massive shares of wind energy, the construction of new offshore energy islands has been recently approved by the Danish government. These new islands will be zero-inertia systems, meaning that no synchronous generation will be installed in the island and that power imbalances will be shared only among converters. To this end, this paper proposes a methodology to calculate and update the frequency droops gains of the offshore converters in compliance with the N-1 security criterion in case of converter outage. The frequency droop gains are calculated solving an optimization problem which takes into consideration the power limitations of the converters as well as the stability of the system. As a consequence, the proposed controller ensures safe operation of off-shore systems in the event of any power imbalance and allows for greater loadability at pre-fault state, as confirmed by the simulation results., Comment: Submitted to "IEEE Transactions on Power Systems" on February 19, 2021 - Revised on July 21, 2021

Published
2020

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