Model Reduction of Swing Equations with Physics Informed PDE
- URL: http://arxiv.org/abs/2110.14066v1
- Date: Tue, 26 Oct 2021 22:46:20 GMT
- Title: Model Reduction of Swing Equations with Physics Informed PDE
- Authors: Laurent Pagnier, Michael Chertkov, Julian Fritzsch, Philippe Jacquod
- Abstract summary: This manuscript is the first step towards building a robust and efficient model reduction methodology to capture transient dynamics in a transmission level electric power system.
We show that, when properly coarse-grained, i.e. with the PDE coefficients and source terms extracted from a spatial convolution procedure of the respective discrete coefficients in the swing equations, the resulting PDE reproduces faithfully and efficiently the original swing dynamics.
- Score: 3.3263205689999444
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: This manuscript is the first step towards building a robust and efficient
model reduction methodology to capture transient dynamics in a transmission
level electric power system. Such dynamics is normally modeled on
seconds-to-tens-of-seconds time scales by the so-called swing equations, which
are ordinary differential equations defined on a spatially discrete model of
the power grid. We suggest, following Seymlyen (1974) and Thorpe, Seyler and
Phadke (1999), to map the swing equations onto a linear, inhomogeneous Partial
Differential Equation (PDE) of parabolic type in two space and one time
dimensions with time-independent coefficients and properly defined boundary
conditions. The continuous two-dimensional spatial domain is defined by a
geographical map of the area served by the power grid, and associated with the
PDE coefficients derived from smoothed graph-Laplacian of susceptances, machine
inertia and damping. Inhomogeneous source terms represent spatially distributed
injection/consumption of power. We illustrate our method on PanTaGruEl
(Pan-European Transmission Grid and ELectricity generation model). We show
that, when properly coarse-grained, i.e. with the PDE coefficients and source
terms extracted from a spatial convolution procedure of the respective discrete
coefficients in the swing equations, the resulting PDE reproduces faithfully
and efficiently the original swing dynamics. We finally discuss future
extensions of this work, where the presented PDE-based reduced modeling will
initialize a physics-informed machine learning approach for real-time modeling,
$n-1$ feasibility assessment and transient stability analysis of power systems.
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