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Photovoltaic Short-Term Output Power Forecast Model Based on Improved Complete Ensemble Empirical Mode Decomposition with Adaptive Noise–Kernel Principal Component Analysis–Long Short-Term Memory

Lan Cao, Haoyu Yang, Chenggong Zhou, Shaochi Wang, Ying Shen, Binxia Yuan

2024Energies13 citationsDOIOpen Access PDF

Abstract

To solve the problem of photovoltaic power prediction in areas with large climate changes, this article proposes a hybrid Long Short-Term Memory method to improve the prediction accuracy and noise resistance. It combines the improved complete ensemble empirical mode decomposition with adaptive noise (ICEEMDAN) and kernel principal component analysis (KPCA) algorithm. The ICEEMDAN algorithm reduces the instability of the environmental factor sequence. The KPCA algorithm reduces the input dimensions of the model. LSTM performs dynamic time modeling of the multivariate feature sequences to predict the output PV power. The adaptability of the ICEEMDAN-KPCA-LSTM model is assessed with datasets from a PV plant in west China and evaluated by root mean squared error (RMSE), mean absolute percentage error (MAPE), and R-squared metrics. Using 70% of the datasets for output PV power estimation, the results show a good performance, with an RMSE of 4.3715, MAPE of 8.9264%, and R-squared value of 89.973%. By comparing with other prediction models, the ICEEMDAN-KPCA-LSTM photovoltaic output power model outperforms other models.

Topics & Concepts

Term (time)Hilbert–Huang transformPrincipal component analysisPhotovoltaic systemNoise (video)Component (thermodynamics)Kernel (algebra)DecompositionMode (computer interface)Kernel principal component analysisControl theory (sociology)Computer scienceMathematicsWhite noiseEngineeringArtificial intelligenceKernel methodSupport vector machinePhysicsTelecommunicationsElectrical engineeringCombinatoricsControl (management)Quantum mechanicsEcologyBiologyThermodynamicsOperating systemImage (mathematics)Energy Load and Power ForecastingSolar Radiation and PhotovoltaicsPower Systems and Renewable Energy