Empowering Distributed Solutions in Renewable Energy Systems and Grid Optimization

• URL: http://arxiv.org/abs/2310.15468v1
• Date: Tue, 24 Oct 2023 02:45:16 GMT
• Title: Empowering Distributed Solutions in Renewable Energy Systems and Grid Optimization
• Authors: Mohammad Mohammadi and Ali Mohammadi
• Abstract summary: Machine learning (ML) advancements play a crucial role in empowering renewable energy sources and improving grid management. The incorporation of big data and ML into smart grids offers several advantages, including heightened energy efficiency. However, challenges like handling large data volumes, ensuring cybersecurity, and obtaining specialized expertise must be addressed.
• Score: 3.8979646385036175
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: This study delves into the shift from centralized to decentralized approaches in the electricity industry, with a particular focus on how machine learning (ML) advancements play a crucial role in empowering renewable energy sources and improving grid management. ML models have become increasingly important in predicting renewable energy generation and consumption, utilizing various techniques like artificial neural networks, support vector machines, and decision trees. Furthermore, data preprocessing methods, such as data splitting, normalization, decomposition, and discretization, are employed to enhance prediction accuracy. The incorporation of big data and ML into smart grids offers several advantages, including heightened energy efficiency, more effective responses to demand, and better integration of renewable energy sources. Nevertheless, challenges like handling large data volumes, ensuring cybersecurity, and obtaining specialized expertise must be addressed. The research investigates various ML applications within the realms of solar energy, wind energy, and electric distribution and storage, illustrating their potential to optimize energy systems. To sum up, this research demonstrates the evolving landscape of the electricity sector as it shifts from centralized to decentralized solutions through the application of ML innovations and distributed decision-making, ultimately shaping a more efficient and sustainable energy future.

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