The inherent unpredictability and fluctuation of renewable energy systems make it very difficult to precisely estimate power output and manage distribution, which is a major obstacle to their widespread use. Current forecasting techniques often fall short, struggling to effectively handle unexpected spikes or changes in demand, which can lead to inefficiencies and even system instability. To better anticipate short-term demand, optimize the balance between generation and distribution states, and dynamically detect and differentiate inappropriate surges in power distribution, this article proposes the Probabilistic Systematic Processing Method (PSPM), which utilizes reward-based state model learning. To anticipate demand and intervene proactively, the approach utilizes real-time and historical characteristics, including consumption, peak generation, and disconnection occurrences. To provide a robust and trustworthy assessment, we validate our results using the Smart Grid Data set from the ARRA projects dataset. Comparing PSPM to current methods, empirical data show that it improves forecast success rate by 20%, increases distribution efficiency by 25%, and reduces analytical latency by 35%. These enhancements showcase PSPM's innovative approach to improving the resilience and operational efficiency of renewable energy systems. Since adaptive energy distribution is not a frequently investigated topic in the existing literature, this study stands out by combining probabilistic analysis with reinforcement learning. Renewable energy systems may be made more intelligent and resilient with the help of the suggested method, which is both practical and scalable. Sustainable power infrastructure automation, energy policy planning, and smart grid management are among its many potential applications.
Keywords: Data analysis; Forward recurring process; Peak generation; Power distribution; Renewable energy; State learning.
© 2025. The Author(s).