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Optimization of Power System Flexibility Through AI‐Driven Dynamic Load Management and Renewable Integration

Saad Hayat, Aamir Nawaz, Aftab Ahmed Almani, Zahid Javid, William Holderbaum

2025Battery energy6 citationsDOIOpen Access PDF

Abstract

ABSTRACT This paper introduces an advanced framework to enhance power system flexibility through AI‐driven dynamic load management and renewable energy integration. Leveraging a transformer‐based predictive model and MATPOWER simulations on the IEEE 14‐bus system, the study achieves significant improvements in system efficiency and stability. Key contributions include a 44% reduction in total power losses, enhanced voltage stability validated through the Fast Voltage Stability Index (FVSI), and optimized renewable energy utilization. Comparative analyses demonstrate the superiority of AI‐based approaches over traditional models such as ARIMA, with the transformer model achieving significantly lower forecasting errors. The proposed methodology highlights the transformative potential of AI in addressing the challenges of modern power grids, paving the way for more resilient, efficient, and sustainable energy systems.

Topics & Concepts

Flexibility (engineering)Renewable energyElectric power systemComputer sciencePower (physics)Dynamic demandEngineeringEconomicsElectrical engineeringManagementPhysicsQuantum mechanicsEnergy Load and Power ForecastingElectric Power System OptimizationSmart Grid Energy Management