Rare desynchronization events in power grids: On data implementation and dimensional reductions

TL;DR

This paper investigates the frequency of desynchronization events in power grids caused by overloads, introducing new methods for data implementation and dimensional reduction to efficiently predict rare events considering realistic data correlations.

Contribution

It proposes a novel colored noise implementation method and two dimensional reduction techniques that simplify high-dimensional power grid models for predicting rare desynchronization events.

Findings

Desynchronization events are largely insensitive to inertia and damping under realistic conditions.

The number of rare events does not necessarily increase with non-Gaussian fluctuations.

Average time to desynchronization is sensitive to the correlation time of power fluctuations.

Abstract

We discuss the frequency of desynchronization events in power grids for realistic data input. We focus on the role of time correlations in the fluctuating power production and propose a new method for implementing colored noise that reproduces non-Gaussian data by means of cumulants of data increment distributions. Our desynchronization events are caused by overloads. We extend known and propose different methods of dimensional reduction to considerably reduce the high-dimensional phase space and to predict the rare desynchronization events with reasonable computational costs. The first method splits the system into two areas, connected by heavily loaded lines, and treats each area as a single node. The second method considers a separation of the timescales of power fluctuations and phase angle dynamics and completely disregards the latter. The fact that this separation turns out to be justified, albeit only to exponential accuracy in the strength of fluctuations, means that the number of rare events does not sensitively depend on inertia or damping for realistic heterogeneous parameters and long correlation times. Neither does the number of desynchronization events automatically increase with non-Gaussian fluctuations in the power production as one might have expected. On the other hand, the analytical expressions for the average time to desynchronization depend sensitively on the finite correlation time of the fluctuating power input.