The paper introduces an efficient data-driven approach to construct probabilistic voltage envelopes (PVEs) for power grids under network contingencies. It first uses a network-aware Gaussian process (GP) called Vertex-Degree Kernel (VDK-GP) to estimate voltage-power functions for a few network configurations.
The key contribution is the development of a novel multi-task vertex degree kernel (MT-VDK) that combines the learned VDK-GPs to determine power flows for unseen networks. This significantly reduces the computational complexity and hyperparameter requirements compared to alternate approaches.
Simulations on the IEEE 30-Bus network demonstrate the ability of the proposed MT-VDK-GP approach to retain and transfer power flow knowledge in both N-1 and N-2 contingency scenarios. Compared to the baseline VDK-GP, MT-VDK-GP achieves over 50% reduction in mean prediction error for novel N-1 contingency network configurations in low training data regimes (50-250 samples). For N-2 contingencies, MT-VDK-GP outperforms a hyperparameter-based transfer learning approach in over 75% of the network structures, even without historical N-2 outage data.
The proposed method demonstrates the ability to achieve PVEs using sixteen times fewer power flow solutions compared to Monte-Carlo sampling-based methods, while maintaining similar probabilistic bounds.
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by Parikshit Pa... kl. arxiv.org 04-05-2024
https://arxiv.org/pdf/2310.00763.pdfDybere Forespørgsler