Abstract
This paper proposes an analytic neural network Gaussian process (NNGP)-based chance-constrained real-time voltage regulation method for active distribution systems with photovoltaics (PVs), batteries, and electric vehicles (EVs). NNGP can utilize historical measurement data to achieve real-time probabilistic node voltage estimation through Bayesian inference. Then, NNGP is fully analytically embedded into the optimal power flow model to perform voltage regulation and adapt to various topological changes. The uncertainties of voltage estimations are easily considered via the chance constraint, and it has been shown that the adoption of this chance constraint can significantly improve the reliability of voltage regulation under various scenarios. The comparison results with other methods, carried out on a real 759-node distribution system located in western Colorado, U.S., show that the proposed method can achieve accurate voltage estimation across different topologies and reliably perform voltage regulation considering PVs, batteries, and EVs.
Original language | American English |
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Journal | IEEE Transactions on Power Systems |
DOIs | |
State | Published - 2024 |
NREL Publication Number
- NREL/JA-5D00-92415
Keywords
- active distribution systems
- Bayesian inference
- chance constraint
- EVs
- neural network Gaussian process
- probabilistic voltage estimation
- PVs
- voltage regulation