Abstract
Smart grids integrate advanced information and communication technologies (ICTs) into traditional power grids for more efficient and resilient power delivery and management, but also introduce new security vulnerabilities that can be exploited by adversaries to launch cyber attacks, causing severe consequences such as massive blackout and infrastructure damages. Existing machine learning-based methods for detecting cyber attacks in smart grids are mostly based on supervised learning, which need the instances of both normal and attack events for training. In addition, supervised learning requires that the training dataset includes representative instances of various types of attack events to train a good model, which is sometimes hard if not impossible. This paper presents a new method for detecting cyber attacks in smart grids using PMU data, which is based on semi-supervised anomaly detection and deep representation learning. Semi-supervised anomaly detection only employs the instances of normal events to train detection models, making it suitable for finding unknown attack events. A number of popular semi-supervised anomaly detection algorithms were investigated in our study using publicly available power system cyber attack datasets to identify the best-performing ones. The performance comparison with popular supervised algorithms demonstrates that semi-supervised algorithms are more capable of finding attack events than supervised algorithms. Our results also show that the performance of semi-supervised anomaly detection algorithms can be further improved by augmenting with deep representation learning.
Highlights
There are a number of existing problems in traditional power grids such as a lack of automated analysis and situational awareness, poor visibility, and slow response time, which make them unable to meet the greatly increased demand for and consumption of electricity in the 21st century [1]
We proposed a scheme for detecting cyber attacks in smart grids with semi-supervised anomaly detection
We investigated a number of representative semi-supervised anomaly detection algorithms and identified the best-performing ones for detecting cyber attacks in smart grids
Summary
There are a number of existing problems in traditional power grids such as a lack of automated analysis and situational awareness, poor visibility, and slow response time, which make them unable to meet the greatly increased demand for and consumption of electricity in the 21st century [1]. There are four main components in a smart grid: generation, transmission, distribution, and consumption, as shown in Figure 1 [2], which are connected through a three-tier hierarchical structured communication network [4]. The first level of the communication network is the home area network (HAN) which is responsible for the communication of the consumption stage to connect smart appliances in consumers’ homes to the smart grid through smart meters for more efficient energy management and demand response. The second level of the communication network, the neighborhood area network (NAN), is responsible for the communication of the distribution stage, which collects data from smart meters and sends back control commands for advanced metering applications. The wide area network (WAN) links NANs to utility control centers to form the backbone of the smart grid for the communication needs of power generation and transmission stages
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