In the past four decades, Texas has experienced more than 80 hurricanes, including Harvey, which alone caused damages costing over $130B. Given this history and predictions of more frequent and/or more intense storms in the future, it is of paramount importance to make prudent investment decisions to enhance the resilience of the electric grid against such extreme weather events. In this work, we explore two storm-surge models and integration of these models with an inland flooding model to create representative future flood scenarios for the state of Texas. We then discuss how these flood scenarios can further be integrated with a synthetic power system model that accurately quantifies the loss of power in all contingencies for the same geographical region, using a stochastic optimization framework. Our proposed two-stage scenario-based stochastic optimization approach helps identify substations susceptible to flooding due to storm surge and inland flooding, and recommends optimal substation hardening solutions given a finite investment budget. The insights from our work can be used to decide substation hardening strategies to enhance the electric grid’s resilience against a multitude of future storm scenarios.

Our research team is involved in several projects that seek to integrate the science-based prediction models of flood-causing events such as hurricanes with the decision-making models for critical infrastructure resilience. To this end, we use the state-of-the-art hydrological models such as WRF-Hydro and ADCIRC to simulate potential realizations of inland and coastal flooding events caused by tropical storms. We use these simulations to generate statistically sound scenarios to populate the inputs of several resilience-based decision making models, all developed using the state-of-the-art scenario-based stochastic and robust optimization methodologies. We identify three time lines where these models can be used to improve the quality of decision making processes: (1) Short-term preemptive resource allocation (preparedness) just before impending tropical storms, (2) Mid-term hardening and resilience investment strategies (mitigation) within a multi-season horizon considering multitudes of potential storms, and (3) Long-term resilience investment and infrastructure design strategy development considering potentially increasing flooding risks due to climate change and sea level rise. We present the overall framework that our team developed relying on the team’s in-progress work, particularly for the short- and mid-term prediction-optimization models. We use two specific infrastructures as examples to instantiate our models: (1) Evacuation of patients from healthcare facilities (hospitals and nursing homes), and (2) Substation hardening and preparation for power grids. To create realistic, high-resolution case studies, we consider historical and synthetic storms that impact actual healthcare facilities and power grid for Texas.