Control of cascading failures in dynamical models of power grids

In this paper, we introduce a distributed control strategy to prevent dynamically-induced cascading failures in power grids. We model power grids using complex networks and nonlinear dynamics to provide a coarse-grained description of the electro-mechanical phenomena taking place on them (in particular, we use coupled swing equations) and restrict our analysis to cascades of line failures, i.e., failures due to power flows exceeding the maximum capacity of a line. We formulate a distributed control protocol relying on the same topology of the physical layer and apply it to several power grid models, including a small-size illustrative example with five nodes, the Italian high-voltage (380kV) power grid, and the IEEE 118-bus system. Our results indicate that the approach is capable of preventing cascading failures, either controlling each node of the network or a suitable subset of them. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

This paper introduces a distributed control strategy to prevent dynamically-induced cascading failures in power grids. By modeling power grids using complex networks and nonlinear dynamics, the approach successfully prevents cascading failures in various power grid models.