Optimal Power System Topology Control Under Uncertain Wildfire Risk

Wildfires pose a significant threat to the safe and reliable operation of electric power systems. They can quickly spread and cause severe damage to power infrastructure. To reduce the risk, public safety power shutoffs are often used to restore power balance and prevent widespread blackouts. However, the unpredictability of wildfires makes it challenging to implement effective counter-measures in a timely manner. This paper proposes an optimization-based topology control problem as a solution to mitigate the impact of wildfires. The goal is to find the optimal network topology that minimizes total operating costs and prevents load shedding during power shutoffs under uncertain line shutoff scenarios caused by uncertain spreading wildfires. The solution involves solving two-stage stochastic mixed-integer linear programs, with preventive and corrective control actions taken when the risk of a wildfire and corresponding outage line scenarios are known with low and high confidence, respectively. The Progressive Hedging algorithm is used to solve both problems. The effectiveness of the proposed approach is demonstrated using data from the RTS-GMLC system that is artificially geo-located in Southern California, including actual wildfire incidents and risk maps. Our work provides a crucial study of the comparative benefits due to accurate risk forecast and corresponding preventive control over real-time corrective control that may not be realistic.