OPTIMIZATION AND MODELING OF SOLAR ENERGY WITH ARTIFICIAL NEURAL NETWORKS
DOI:
https://doi.org/10.4314/njt.v43i1.15Keywords:
Renewable energy, Solar energy, Artificial Neural Networks, Optimal Prediction, Radiation, Area of Panel, Hourly prediction, Average Monthly prediction, August Break, Mean Absolute Error, Mean Squared Error, Root Mean Squared ErrorAbstract
Solar energy represents one of the emerging frontiers in renewable energy, offering significant potential to address the issues of energy unavailability and instability in Uyo (Nigeria). A crucial step in overcoming these challenges is accurately predicting the amount of solar energy that can be harnessed at a specific location. This research focused on achieving optimal solar power prediction, with the following objectives; identifying and investigating the mathematical relationships between relevant variables and parameters. To ensure precise predictions, artificial neural networks (ANN) were employed, utilizing both forward and backward propagation techniques. The input data for the ANN comprised radiation data obtained from a secondary source, the solar panel's size or area from the manufacturer, the panel's efficiency, and its performance ratio – all of which determined the electricity produced in kilowatts. The ANN was trained and tested using meteorological data, enabling accurate predictions of optimal electricity generation for the location. Notably, the hourly predictions reached their peak by 1 PM at the geographic location (5.2N and 7.5E), indicating that the highest levels of solar power were attainable during this daily period. Moreover, the pattern of monthly average solar power exhibited optimal predictions in January. Influenced by meteorological factors, a significant rise and fall in August, commonly referred to as the 'August Break’ featured. The results demonstrated exceptional accuracy with minimal error margins (mean absolute error (MAE) of 0.03, mean squared error (MSE) of 0.0, and root mean squared error (RMSE) of 0.03). This high level of accuracy rendered the predictions reliable, making them suitable for consultancy services. Additionally, the potential for future work and expansion was evident, as the ANN could incorporate five or more years of radiation data for further improvements and insights.
References
Alfredo, N., Sonia, L., Marco, M., and Emanuele, G. C. O. “A Selective Ensemble Approach for Accuracy Improvement and Computational Load Reduction in ANN-Based PV Power Forecasting”, 2022; IEEE Access, Milan Italy, DOI: 10.1109/ACCESS.2022.3158 364
ChérifaKara, M. K., Badia, A., Kamel, K., and Aissa, C. “The impact of the ANN’s choice on PV systems diagnosis quality”, Volume 240, 15 July 2021, Energy Conversion and Management, https://doi.org/10.1016/j.enconm an.2021.114278
Srivignesh, R. “A Walk-through of Regression Analysis Using Artificial Neural Networks in Tensorflow”, (2021), Data Science Blogathon. Date accessed 6/1/24
Zahraa, E. M. “Using the artificial neural networks for prediction and validating solar radiation”, Journal of the Egyptian Mathemati-cal Society, 2019; Egypt., Pages 1-13. https://doi.org/10.1186/s42787-019-0043-8, Date accessed 6/1/24
Valerio, L. B., Giuseppina, C., and Mariavittoria, D. F. “Artificial Neural Networks to Predict the Power Output of a PV Panel”, International Journal of Photoenergy, Volume 2014, Pages 1-12. https://doi.org/10.1155/2014/ 193083. Date accessed 6/1/24
Agbulut, U., Gurel, A., and Yunus, B. “Predicti-on of daily global solar radiation using different machine learning algorithms: Evaluation and comparison”, Semantic Scholar, 2021; https://doi.org/10.1016/j.rser.2020.1101 14. Accessed: 21/07/23
Umit, A., Ali, E. G., and Yunus B. “Prediction of daily global solar radiation using different machine learning algorithms: Evaluation and comparison”, Renewable and Sustainable Energy Reviews, 2020, Elsevier Ltd. Turkey. https://doi.org/10.1016/j.rser.2020.110114
Gurel, A. E., Agbulut, U., and Biçen Y. “Assessment of machine learning, time series, response surface methodology and empirical models in prediction of global solar radiation”, Journal of Cleaner Production on Science Direct, 2020; Volume 277, 122353 https://doi.o rg/10.1016/j.jclepro.2020.122353
Pragati, B. “Activation Functions in Neural Networks [12 Types & Use Cases]”, 2021; Microsoft V7 Ltd, London HQ. https://www.v7labs.com/. Date accessed 6/1/24
Uppin, C. “Study of Cloud Computing: Significance & Impact”, The International Journal Research Publications, 2018; ISSN: 2251 1563; Research Journal of Science & IT Management (RJSIM) UGC Approved Index Journal. www.theinternationaljournal.org RJS ITM: Volume: 07, Number: 04. Date accessed 9/7/23
European Commission. Joint Research Centre, Energy Efficiency and Renewables Unit, (2023) via E. Fermi 2749, TP 450, I-21027 Ispra (VA), Italy. [email protected] Date accessed 6/1/24
George, G., and Uppin C. “A Proactive Approach to Network Forensics Intrusion (Denial of Service Flood Attack) Using Dynamic Features, Selection and Convolution Neural Network”, Open Journal of Physical Science (OJPS) Nigeria, 2021; ISSN: 2734-2123, Volume: 2; Issue: 2, Pages: 01 - 09 (2021), DOI: 10.52417/ojps. v2i2.237, www.op enjournalsnigeria.org.ng. Date accessed 9/7/23
Photovoltaic-Software. “How to calculate the annual solar energy output of a photovoltaic system?”, Photovoltaic-software.com. (2023) https://photovoltaic-software.com/principle-res sources/howcalculate-solar-energy-power-pv-s ystems. Date accessed 6/1/24
Solar Solar. “Solar Power Efficiency”, Solar by nature, (2022) Page 1, North Carolina. https://so larbynatureinc.com/category/solar-energy/. Dat e: accessed 6/1/24
Henderson, M. “Solar Panel Efficiency”, Solar Calculator, (2023) Balnarring VIC, Australia. https://solarcalculator.com.au/about-us/ Date accessed 6/1/24
International Geophysics. “An Introduction to Atmospheric Radiation”, ScienceDirect.com, (2024), Volume 84; Pages 1-583. Date accessed 6/1/24
Sharma, U. “Why Do We Need Data Splitting?”, Faculty (Big Data Analytical), (2021), Technical… , Date accessed 11/4/23 (Utkarsh Sharm… in.linkedin.com)
Jaiswal, S. “Train and Test datasets in Machine Learning”, Javatpoint. Noida, (2021), India. https://www.javatpoint.com/train-and-test-data sets-in-machine-learning. Date accessed 6/1/24
Downloads
Published
Issue
Section
License
Copyright (c) 2024 Nigerian Journal of Technology
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
The contents of the articles are the sole opinion of the author(s) and not of NIJOTECH.
NIJOTECH allows open access for distribution of the published articles in any media so long as whole (not part) of articles are distributed.
A copyright and statement of originality documents will need to be filled out clearly and signed prior to publication of an accepted article. The Copyright form can be downloaded from http://nijotech.com/downloads/COPYRIGHT%20FORM.pdf while the Statement of Originality is in http://nijotech.com/downloads/Statement%20of%20Originality.pdf
For articles that were developed from funded research, a clear acknowledgement of such support should be mentioned in the article with relevant references. Authors are expected to provide complete information on the sponsorship and intellectual property rights of the article together with all exceptions.
It is forbidden to publish the same research report in more than one journal.
How to Cite
