Cascading Failure Prediction via Causal Inference
This addresses the problem of improving failure prediction for power grid operators, but it appears incremental as it builds on existing causal inference methods applied to a specific domain.
The paper tackles the problem of predicting cascading failures in power transmission networks by developing a causal inference framework that identifies cause-and-effect relationships among transmission lines, and it demonstrates effectiveness on IEEE 14-bus, 39-bus, and 118-bus systems.
Causal inference provides an analytical framework to identify and quantify cause-and-effect relationships among a network of interacting agents. This paper offers a novel framework for analyzing cascading failures in power transmission networks. This framework generates a directed latent graph in which the nodes represent the transmission lines and the directed edges encode the cause-effect relationships. This graph has a structure distinct from the system's topology, signifying the intricate fact that both local and non-local interdependencies exist among transmission lines, which are more general than only the local interdependencies that topological graphs can present. This paper formalizes a causal inference framework for predicting how an emerging anomaly propagates throughout the system. Using this framework, two algorithms are designed, providing an analytical framework to identify the most likely and most costly cascading scenarios. The framework's effectiveness is evaluated compared to the pertinent literature on the IEEE 14-bus, 39-bus, and 118-bus systems.