Abstract

Rate of change of frequency (RoCoF) and frequency nadir should be considered in real-time frequency-constrained optimal power flow (FCOPF) to ensure frequency stability of the modern power systems. Since calculating the frequency response is complex, deep neural network (DNN) could be adopted to capture the nonlinearities and estimate those two metrics accurately. Therefore, in this paper, a DNN-based frequency predictor is developed with the training data obtained from time-domain simulations using PSCAD/EMTDC. Subsequently, it is reformulated using a set of mixed-integer linear programming formulations and then embedded into the FCOPF framework as constraints to ensure grid frequency stability, creating the proposed DNN-FCOPF model. Two benchmark models, a traditional OPF without any frequency constraints and a linear system-wide RoCoF-constrained FCOPF, are also implemented to gauge the proposed DNN-FCOPF. Finally, the solutions obtained with these three models are compared and evaluated with time-domain simulations using PSCAD under various load profiles, demonstrating the effectiveness of the proposed DNN-FCOPF.

Index Terms

Deep neural network, frequency nadir, grid synchronous inertia, optimal power flow, rate of change of frequency, system frequency response.

Cite this paper:

Fan Jiang, Xingpeng Li, and Pascal Van Hentenryck, “A Deep Neural Network-based Frequency Predictor for Frequency-Constrained Optimal Power Flow”, IEEE IAS Annual Meeting, New Taipei, Jun. 2025.