Abstract
This paper proposes an effective Photovoltaic (PV) Power Forecasting (PVPF) technique based on hierarchical learning combining Nonlinear Auto-Regressive Neural Networks with exogenous input (NARXNN) with Long Short-Term Memory (LSTM) model. First, the NARXNN model acquires the data to generate a residual error vector. Then, the stacked LSTM model, optimized by Tabu search algorithm, uses the residual error correction associated with the original data to produce a point and interval PVPF. The performance of the proposed PVPF technique was investigated using two real datasets with different scales and locations. The comparative analysis of the NARX-LSTM with twelve existing benchmarks confirms its superiority in terms of accuracy measures. In summary, the proposed NARX-LSTM technique has the following major achievements: 1) Improves the prediction performance of the original LSTM and NARXNN models; 2) Evaluates the uncertainties associated with point forecasts with high accuracy; 3) Provides a high generalization capability for PV systems with different scales. Numerical results of the comparison of the proposed NARX-LSTM method with two real-world PV systems in Australia and USA demonstrate its improved prediction accuracy, outperforming the benchmark approaches with an overall normalized Rooted Mean Squared Error (nRMSE) of 1.98% and 1.33% respectively.
Highlights
Energy transition towards renewables is a global trend in the twenty-first century
We assume that the additional tapped time delays from neural networks with exogenous input (NARXNN) improve the accuracy of the prediction engine using the error Hankel matrix to increase the weight of the residual error correction
This paper proposed a new computing framework based on the combination of Nonlinear Auto-Regressive Exogenous Neural Network (NARXNN) and Long Short-Term Memory (LSTM) optimized by Tabu search algorithm
Summary
Data set for the 1st case study Data set for the 2nd case study Station pressure (bar) Altimeter indication Average Coverage Error Adaptive Moment Estimation optimizer Autoencoder Cloud coverage Convolutional Neural Network Diffuse horizontal radiation(W /m2) Dew point Empirical Mode Decomposition. The associate editor coordinating the review of this manuscript and approving it for publication was Giambattista Gruosso. M. Massaoudi et al.: Effective Hybrid NARX-LSTM Model for Point and Interval PV Power Forecasting. Persistence Model Photovoltaic power forecasting Relative humidity (%) Recurrent Neural Network Sine Cosine Algorithm Standard derivation Support Vector Machine Ambient temperature (◦C) Time Correlation Modification Tabu Search Algorithm Visibility Wind direction (Â◦) Weighted Gaussian Process Regression Wind speed (m/s)
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