AI model from University of Virginia enhances power grid reliability as renewables dominate
by Clarence Oxford
Los Angeles CA (SPX) Oct 28, 2024
As renewable energy sources like wind and solar expand, managing the power grid’s reliability becomes more challenging. Researchers at the University of Virginia have introduced an advanced artificial intelligence model that addresses the uncertainties of renewable energy generation and the growing demand from electric vehicles, enhancing power grid reliability and efficiency.
Introducing Multi-Fidelity Graph Neural Networks for Grid Management
The model uses a novel approach based on multi-fidelity graph neural networks (GNNs) to improve power flow analysis, which is critical to distributing electricity safely and efficiently across the grid. The model’s “multi-fidelity” system allows it to draw from vast amounts of lower-quality data while integrating smaller quantities of highly accurate data, speeding up model training and bolstering accuracy and reliability.
Adapting to Real-Time Grid Needs
With the application of GNNs, the AI model adjusts to different grid configurations and withstands fluctuations, such as power line disruptions. It addresses the “optimal power flow” challenge – deciding the power levels needed from various sources to maintain stability. Renewable energy sources introduce unpredictability in supply, while electrification efforts, like the increased use of electric vehicles, add demand-side uncertainty. Traditional grid management approaches are not as effective in adapting to these real-time changes. By integrating detailed and streamlined simulations, the model finds optimized solutions within seconds, significantly improving grid performance in dynamic conditions.
“With renewable energy and electric vehicles changing the landscape, we need smarter solutions to manage the grid,” said Negin Alemazkoor, assistant professor of civil and environmental engineering and lead researcher on the project. “Our model helps make quick, reliable decisions, even when unexpected changes happen.”
Key Advantages of the Model:
– Scalability: Requires less computational power for training, enabling application to large, complex power systems. This may interest you : Researchers develop a new source of quantum light.
– Enhanced Accuracy: Uses extensive low-fidelity simulations to improve the reliability of power flow predictions.
– Greater Generalizability: Adapts to changes in grid configurations, like line failures, which are limitations for conventional machine learning models.
This AI development is poised to play a key role in bolstering grid stability amid growing energy uncertainties.
Looking Toward a Stable Energy Future
“Managing the uncertainty of renewable energy is a big challenge, but our model makes it easier,” said Ph.D. student Mehdi Taghizadeh, a researcher in Alemazkoor’s lab. Ph.D. student Kamiar Khayambashi, specializing in renewable integration, added, “It’s a step toward a more stable and cleaner energy future.”
Research Report:Multi-fidelity Graph Neural Networks for Efficient Power Flow Analysis Under High-Dimensional Demand and Renewable Generation Uncertainty
Research Report:Hybrid Chance-Constrained Optimal Power Flow under Load and Renewable Generation Uncertainty Using Enhanced Multi-Fidelity Graph Neural Networks
Related Links
University of Virginia School of Engineering and Applied Science
All About Solar Energy at SolarDaily.com