T. Sujeeth, C. Ramesh, Sushila Palwe, Gandikota Ramu, S. J. Basha, Deepak Upadhyay, K. Chanthirasekaran, K. Sivasankari, A. Rajaram
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The proposed model is evaluated using real-world solar power generation data, and the results demonstrate its superior performance compared to traditional methods and other machine learning approaches. The Enhanced ANN model achieves an impressive Root Mean Square Error (RMSE) of 0.116 and a Mean Absolute Percentage Error (MAPE) of 36.26% . The integration of Weather Modulation allows the model to adapt to changing weather conditions, ensuring reliable forecasts even during adverse scenarios. Leveraging Prior Forecasts enables the model to capture short-term trends, reducing forecasting errors arising from abrupt weather changes. 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引用次数: 0
摘要
太阳能发电预测在优化电网管理和稳定性方面发挥着至关重要的作用,尤其是在可再生能源集成电力系统中。本研究论文对太阳能发电预测进行了全面研究,评估了传统和先进的机器学习方法,包括ARIMA、指数平滑、支持向量回归、随机森林、梯度提升和基于物理的模型。此外,我们还提出了一种创新的增强型人工神经网络(ANN)模型,该模型结合了天气调制和利用先前预测来提高预测精度。我们使用真实世界的太阳能发电数据对所提出的模型进行了评估,结果表明,与传统方法和其他机器学习方法相比,该模型性能优越。增强型 ANN 模型的均方根误差 (RMSE) 为 0.116,平均绝对误差 (MAPE) 为 36.26%,令人印象深刻。天气调制的集成使模型能够适应不断变化的天气条件,确保即使在不利情况下也能做出可靠的预测。利用事先预测,该模型能够捕捉短期趋势,减少因天气突变而产生的预测误差。所提出的增强型 ANN 模型展示了其作为精确可靠的太阳能发电预测工具的潜力,有助于将太阳能有效地纳入电网,并推进可持续能源实践。
Adaptive solar power generation forecasting using enhanced neural network with weather modulation
Solar power generation forecasting plays a vital role in optimizing grid management and stability, particularly in renewable energy-integrated power systems. This research paper presents a comprehensive study on solar power generation forecasting, evaluating traditional and advanced machine learning methods, including ARIMA, Exponential Smoothing, Support Vector Regression, Random Forest, Gradient Boosting, and Physics-based Models. Moreover, we propose an innovative Enhanced Artificial Neural Network (ANN) model, which incorporates Weather Modulation and Leveraging Prior Forecasts to enhance prediction accuracy. The proposed model is evaluated using real-world solar power generation data, and the results demonstrate its superior performance compared to traditional methods and other machine learning approaches. The Enhanced ANN model achieves an impressive Root Mean Square Error (RMSE) of 0.116 and a Mean Absolute Percentage Error (MAPE) of 36.26% . The integration of Weather Modulation allows the model to adapt to changing weather conditions, ensuring reliable forecasts even during adverse scenarios. Leveraging Prior Forecasts enables the model to capture short-term trends, reducing forecasting errors arising from abrupt weather changes. The proposed Enhanced ANN model showcases its potential as a promising tool for precise and reliable solar power generation forecasting, contributing to the efficient integration of solar energy into the power grid and advancing sustainable energy practices.