A Novel Renewable Power Generation Prediction through Enhanced Artificial Orcas Assisted Ensemble Dilated Deep Learning Network

The different energy resource generation tends to have high-level variation, making the power supply complex for the end-users. Because of the intermittent nature, the variations occur by time, weather conditions, and output energy. Hence, this research aims to develop a new "Renewable Power Ge...

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Bibliographic Details
Published in:IEEE access 2024-01, Vol.12, p.1-1
Main Authors: Che, Zhifeng, Amirthasaravanan, A., Al-Razgan, Muna, Awwad, Emad Mahrous, Mohamed, Mohamed Yasin Noor, Tyagi, Vaibhav Bhushan
Format: Article
Language:English
Subjects:
Algorithms
Artificial neural networks
Belief networks
Cleaning
Data aggregation
Data management
Deep learning
Electric power generation
Empirical analysis
Energy management
Energy resources
Energy sources
enhanced artificial orcas algorithm
higher order statistical features
Higher order statistics
Long short term memory
Machine learning
Meteorology
Neural networks
optimal weight computation ensemble dilated deep network
Optimization
Outliers (statistics)
Power generation planning
Power supplies
Power supply
Prediction models
Predictive models
Recurrent neural networks
Renewable energy sources
Renewable power generation prediction
Weather
Weight measurement
Whale optimization algorithms
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Summary:The different energy resource generation tends to have high-level variation, making the power supply complex for the end-users. Because of the intermittent nature, the variations occur by time, weather conditions, and output energy. Hence, this research aims to develop a new "Renewable Power Generation Prediction (RPGP)" model using Deep Learning (DL) to give the end user a reliable power supply. The data aggregation process initially accumulated the data in a normalized and structured format. Then, the data cleaning and scaling are performed to decrease the outliers and varying ranges of values. A higher-order statistical feature was attained from the cleaned and scaled data. This statistical feature was given to "Optimal Weight Computation Ensemble Dilated Deep Network (OWC-EDDNet)" to predict generated power. In this EDDLNet, networks such as "Recurrent Neural Networks (RNN), Long Short-Term Memory (LSTM), Deep Belief Networks (DBN), and Deep Neural Networks (DNN)" are employed to predict the renewable generated power. Finally, the prediction score attained from all deep networks is multiplied by the optimized weight to get the final prediction outcome, where the weights are optimally determined with the support of the Enhanced Artificial Orcas Algorithm (EAOA). The extensive empirical results were analyzed among traditional algorithms and prediction models to showcase the efficacy of the designed energy generation prediction scheme.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2024.3375870