Novel Attacks against Contingency Analysis in Power Grids

TL;DR

This paper uncovers new cyber-attack methods targeting contingency analysis in power grids by manipulating state estimation data, potentially causing system overloads and operational failures.

Contribution

It introduces a formal model for analyzing attacks on contingency analysis, revealing how adversaries can evade detection and induce overloads in power grid systems.

Findings

Identified attack vectors that can bypass contingency analysis defenses.

Demonstrated attack impact on IEEE 14 bus system case study.

Validated attack strategies with PowerWorld simulations.

Abstract

Contingency Analysis (CA) is a core component of the Energy Management System (EMS) in the power grid. The goal of CA is to operate the power system in a secure manner by analyzing the system subject to a contingency (e.g., the outage of a transmission line or a power generator) to determine the setpoints that will allow system operation without violation of constraints. The analysis in CA is conducted based on the output from State Estimation (SE), another core EMS module. However, it is also shown that an adversary can alter certain power measurements to corrupt the system states estimated by SE without being detected. Such a corrupted estimation can severely skew the results of the contingency analysis as it will provide a fake model to deal with. In this research, we formally model necessary interdependency relationships and systematically analyze these novel attacks on the contingency analysis. In particular, this research focuses on Security Constrained Optimal Power Flow (SCOPF) that finds out the optimal economic dispatches considering a single line failure (based on the $n - 1$ contingency analysis) and transmission line capacities. The proposed model is implemented and solved to find out potential threat vectors (i.e., a set of measurements to be altered) that can evade CA so that the system will face overloading situation on one or more transmission lines when some specific contingencies happen. We demonstrate our formal model on an IEEE 14 bus system-based case study and verify the results with a standard PowerWorld model. We further evaluate the model with respect to various attacks and grid characteristics.