The paper introduces and compares two-stage stochastic programming (SP) and robust optimization (RO) models for informing the deployment of temporary flood mitigation resources to protect electrical substations before an imminent hurricane.
The first-stage decisions involve allocating a limited budget to reinforce substations to different resilience levels. The second-stage recourse problems capture the operation of the potentially degraded power grid, with the primary goal of minimizing load shed. The authors adapt the classical DC power flow approximation and several variants of the more sophisticated LPAC approximation to model the grid operation.
The authors investigate the impact of the mitigation budget, the choice of power flow model, and the uncertainty perspective (SP vs. RO) on the optimal mitigation strategy. Their results indicate that the mitigation budget and uncertainty perspective are impactful, whereas the choice between the DC and LPAC power flow models has little to no consequence. To validate their models, the authors assess the performance of the mitigation solutions prescribed by their models in an AC power flow model.
The authors also introduce an "infeasibility indicator variable" in their recourse problems to ensure relatively complete recourse when the power flow model does not admit a feasible solution for certain contingencies.
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