English

Cascading Failures in AC Electricity Grids

Adaptation and Self-Organizing Systems 2016-09-14 v3 Systems and Control

Abstract

Sudden failure of a single transmission element in a power grid can induce a domino effect of cascading failures, which can lead to the isolation of a large number of consumers or even to the failure of the entire grid. Here we present results of the simulation of cascading failures in power grids, using an alternating current (AC) model. We first apply this model to a regular square grid topology. For a random placement of consumers and generators on the grid, the probability to find more than a certain number of unsupplied consumers decays as a power law and obeys a scaling law with respect to system size. Varying the transmitted power threshold above which a transmission line fails does not seem to change the power law exponent q1.6q \approx 1.6. Furthermore, we study the influence of the placement of generators and consumers on the number of affected consumers and demonstrate that large clusters of generators and consumers are especially vulnerable to cascading failures. As a real-world topology we consider the German high-voltage transmission grid. Applying the dynamic AC model and considering a random placement of consumers, we find that the probability to disconnect more than a certain number of consumers depends strongly on the threshold. For large thresholds the decay is clearly exponential, while for small ones the decay is slow, indicating a power law decay.

Keywords

Cite

@article{arxiv.1604.06733,
  title  = {Cascading Failures in AC Electricity Grids},
  author = {Martin Rohden and Daniel Jung and Samyak Tamrakar and Stefan Kettemann},
  journal= {arXiv preprint arXiv:1604.06733},
  year   = {2016}
}

Comments

submitted to Phys. Rev. E, 7 pages, 7 figures

R2 v1 2026-06-22T13:38:48.254Z