University of Virginia’s AI model improves grid reliability as renewable energy sources dominate
As renewable energy sources such as wind and solar power expand, managing the reliability of the electricity grid becomes increasingly challenging. Researchers from the University of Virginia have introduced an advanced artificial intelligence model that addresses the uncertainties of renewable energy generation and the growing demand for electric vehicles, improving the reliability and efficiency of the electric grid.
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 for the safe and efficient distribution of electricity across the grid. The model’s ‘multi-fidelity’ system allows it to draw on large amounts of lower quality data while integrating smaller amounts of high-precision data, speeding up model training and increasing accuracy and reliability.
Adaptation to real-time network needs
With the application of GNNs, the AI model adapts to different network configurations and is resilient to fluctuations such as power line disruptions. It addresses the challenge of ‘optimal energy flow’: determining the energy levels required from different sources to maintain stability. Renewable energy sources create unpredictability in supply, while electrification efforts, such as the increased use of electric vehicles, increase demand-side uncertainty. Traditional approaches to grid management are not as effective at adapting to these real-time changes. By integrating detailed and streamlined simulations, the model finds optimized solutions in seconds, significantly improving network performance under dynamic conditions.
“As renewable energy and electric vehicles change the landscape, we need smarter solutions to manage the power grid,” said Negin Alemazkoor, assistant professor of civil and environmental engineering and principal investigator of the project. “Our model helps make fast, reliable decisions, even when unexpected changes occur.”
Main advantages of the model:
– Scalability: Requires less computing power for training, allowing application to large, complex energy systems.
– Improved Accuracy: Uses extensive low-fidelity simulations to improve the reliability of power flow predictions.
– Greater generalizability: adapts to changes in network configurations, such as line outages, which are limitations for conventional machine learning models.
This AI development is poised to play a key role in strengthening grid stability amid growing energy uncertainties.
Looking towards a stable energy future
“Managing the uncertainty of renewable energy is a major challenge, but our model makes it easier,” said Ph.D. student Mehdi Taghizadeh, a researcher in Alemazkoor’s laboratory. Ph.D. Student Kamiar Khayambashi, who specializes in sustainable integration, added: “It is a step towards a more stable and cleaner energy future.”
Research report:Multi-fidelity graph neural networks for efficient energy flow analysis under high-dimensional demand and renewable energy uncertainty