1
Electrical Engineering Department, College of Engineering, University of Business and Technology, Jeddah 23847, Saudi Arabia
(M.alqarni@ubt.edu.sa)
2
Department of Computer Science, College of Computing and Information Technology, University of Bisha, Bisha 61922, P. O. Box 551, Saudi Arabia.
(ahismail@ub.edu.sa)
3
Department of Mathematics, Faculty of Science, New Valley University, El-Kharga 72511, Egypt, Egypt.
(safaasobhy1982@scinv.au.edu.eg)
4
Department of Computer Science, College of Science and Arts in Gurayat, Jouf University, Saudi Arabia; Computer Science Department, Faculty of Computers and Information Assiut University, Egypt
(rashamahmoud@aun.edu.eg)
5
Information System Department, Faculty of Computers and Information, Assiut University, Assiut, Egypt
( Taloba@aun.edu.eg)
Abstract :
One of the primary sources of renewable energy in the coming years is thought to be solar energy. Solar energy and other renewable energy sources do, moreover, have a disadvantage in that it is hard to forecast when they will be available. The best use of solar energy is impacted by this issue, particularly when it is combined with other sources. As a result, the organization and economy of solar energy depend on accurate solar energy forecasting techniques. Predicting solar energy shortly is the study’s major goal. This paper describes the study of Neutrosophic fuzzy logic with artificial neural networks (NFL-ANN) to anticipate solar photovoltaic (PV) plant output power with the use of specified input factors known as meteorological information, such as sunshine length, humidity levels, temperature, air pressure, and others, artificial neural networks are used to forecast the outcome. NFL represents a generalised logic, which can manage stochasticity learning mistakes and unpredictability that fuzzy logic lacks. It offers the results of the calculation section. Excellent performance computer processors and NFL provide reasonable accuracy estimates of solar plant outputs as well as system reliability to consider environmental factors. The investigation was carried out with the use of MATLAB programming. With the assistance of statistical markers like mean absolute percentage error (MAPE), mean absolute error (MAE), root means square error (RMSE), and determinant coefficient, the suggested NFL-ANN approach is evaluated and compared to other approaches that are already in use. In comparison to existing techniques, the suggested NFL-ANN provides superior accuracy and lesser prediction error, according to the study’s findings. This research will be enhanced to forecast power without any loss.
Keywords :
Solar energy; short-term; fuzzy logic; neutrosophic logic; prediction; ANN; photovoltaic plant; meteorological; NFL classifier
References :
[1] Rasha M Abd El-Aziz. Renewable power source energy consumption by hybrid machine learning model. Alexandria Engineering Journal, 61(12):9447–9455, 2022.
[2] Amr Abozeid, Rayan Alanazi, Ahmed Elhadad, Ahmed I Taloba, Abd El-Aziz, and M Rasha. A largescale dataset and deep learning model for detecting and counting olive trees in satellite imagery. Computational Intelligence and Neuroscience, 2022, 2022.
[3] Muhammad Naveed Akhter, Saad Mekhilef, Hazlie Mokhlis, Lanre Olatomiwa, and Munir Azam Muhammad. Performance assessment of three grid-connected photovoltaic systems with combined capacity of 6.575 kwp in malaysia. Journal of Cleaner Production, 277:123242, 2020.
[4] Faisal Al-Sharqi and Ashraf Al-Quran Abd Ghafur Ahmad. Mapping on interval complex neutrosophic soft sets. International Journal of Neutrosophic Science, 19(4):77–85, 2022.
[5] Majed G Alharbi and Hamiden Abd El-Wahed Khalifa. On solutions of fully fuzzy linear fractional programming problems using close interval approximation for normalized heptagonal fuzzy numbers. Appl. Math, 15(4):471–477, 2021.
[6] Muhammad Umair Ali, Hafiz Farhaj Khan, Manzar Masud, Karam Dad Kallu, and Amad Zafar. A machine learning framework to identify the hotspot in photovoltaic module using infrared thermography. Solar Energy, 208:643–651, 2020.
[7] Badia Amrouche and Xavier Le Pivert. Artificial neural network based daily local forecasting for global solar radiation. Applied energy, 130:333–341, 2014.
[8] Yingbo An and Huasen Zhou. Short term effect evaluation model of rural energy construction revitalization based on id3 decision tree algorithm. Energy Reports, 8:1004–1012, 2022.
[9] A Azadeh, A Maghsoudi, and S Sohrabkhani. An integrated artificial neural networks approach for predicting global radiation. Energy conversion and management, 50(6):1497–1505, 2009.
[10] Jatin Bedi and Durga Toshniwal. Deep learning framework to forecast electricity demand. Applied energy, 238:1312–1326, 2019.
[11] Manoja Kumar Behera and Niranjan Nayak. A comparative study on short-term pv power forecasting using decomposition based optimized extreme learning machine algorithm. Engineering Science and Technology, an International Journal, 23(1):156–167, 2020.
[12] Taqiy Eddine Boukelia, Mohamed-Salah Mecibah, and Imad Eddine Meriche. General models for estimation of the monthly mean daily diffuse solar radiation (case study: Algeria). Energy Conversion and Management, 81:211–219, 2014.
[13] VS Chandrika, Alagar Karthick, Nallapaneni Manoj Kumar, P Manoj Kumar, B Stalin, and M Ravichandran. Experimental analysis of solar concrete collector for residential buildings. International Journal of Green Energy, 18(6):615–623, 2021.
[14] Juan Chang, Genxu Wang, and Tianxu Mao. Simulation and prediction of suprapermafrost groundwater level variation in response to climate change using a neural network model. Journal of Hydrology, 529:1211–1220, 2015.
[15] Tsai-Ping Chu, Jia-Hong Guo, Yih-Guang Leu, and Li-Fen Chou. Estimation of solar irradiance and solar power based on all-sky images. Solar Energy, 249:495–506, 2023.
[16] Emilian Gelu Cojocaru, Jos´ e Manuel Bravo, Manuel Jes ´ us Vasallo, and Diego Mar´ ın Santos. Optimal scheduling in concentrating solar power plants oriented to low generation cycling. Renewable Energy, 135:789–799, 2019.
[17] Stephen Comello, Stefan Reichelstein, and Anshuman Sahoo. The road ahead for solar pv power. Renewable and Sustainable Energy Reviews, 92:744–756, 2018.
[18] Bhatti Darshana, Sachin Parikh, and Manan Shah. Potential of ag–fe co-doped tio 2 nanocomposite for solar photocatalysis of high cod pharmaceutical effluent and influencing factors. Energy, Ecology and Environment, 5:344–358, 2020.
[19] Alberto Dolara, Sonia Leva, Marco Mussetta, and E Ogliari. Pv hourly day-ahead power forecasting in a micro grid context. In 2016 IEEE 16th International Conference on Environment and Electrical Engineering (EEEIC), pages 1–5. IEEE, 2016.
[20] AI Dounis, CC Lefas, and A Argiriou. Knowledge-based versus classical control for solar-building designs. Applied Energy, 50(4):281–292, 1995.
[21] Amir El-Komy, Osama R Shahin, Rasha M Abd El-Aziz, and Ahmed I Taloba. Integration of computer vision and natural language processing in multimedia robotics application. IInformation Sciences Letters, 11(3):765–775, 2022.
[22] Mourad Elloumi, Mostafa A Ahmad, Ahmed H Samak, Ali M Al-Sharafi, Daisuke Kihara, and Ahmed I Taloba. Error correction algorithms in non-null aspheric testing next generation sequencing data. Alexandria Engineering Journal, 61(12):9819–9829, 2022.
[23] Mohamed A Fouly, Taysir Hassan A Soliman, and Ahmed I Taloba. Developing an efficient secure query processing algorithm for unstructured data on encrypted databases. In 2022 10th International Japan-Africa Conference on Electronics, Communications, and Computations (JAC-ECC), pages 252– 257. IEEE, 2022.
[24] Zvonimir Glasnovic and Jure Margeta. Sustainable electric power system: Is it possible? case study: Croatia. Journal of Energy Engineering, 136(4):103–113, 2010.
[25] H-M Groscurth and K-P Kress. Fuzzy data compression for energy optimization models. Energy, 23(1):1–9, 1998.
[26] Jiansheng Guan, Jie Lin, JianJie Guan, and Elham Mokaramian. A novel probabilistic short-term wind energy forecasting model based on an improved kernel density estimation. International Journal of Hydrogen Energy, 45(43):23791–23808, 2020.
[27] Eunnyeong Heo, Jinsoo Kim, and Kyung-Jin Boo. Analysis of the assessment factors for renewable energy dissemination program evaluation using fuzzy ahp. Renewable and sustainable energy reviews, 14(8):2214–2220, 2010.
[28] JO Jaber, QM Jaber, SA Sawalha, and MS Mohsen. Evaluation of conventional and renewable energy sources for space heating in the household sector. Renewable and sustainable energy reviews, 12(1):278– 289, 2008.
[29] SD Kaminaris, TD Tsoutsos, D Agoris, and AV Machias. Assessing renewables-to-electricity systems: a fuzzy expert system model. Energy policy, 34(12):1357–1366, 2006.
[30] Engin Karatepe, Mutlu Boztepe, and Metin Colak. Neural network based solar cell model. Energy conversion and management, 47(9-10):1159–1178, 2006.
[31] Mohamed HR Khalaf, ZM Abdel Azim, Walid HAH Elkhateeb, Osama R Shahin, and Ahmed I Taloba. Explore the e-learning management system lower usage during covid-19 pandemic. Information Sciences Letters, 11(2):537–548, 2022.
[32] Vladimir Kostylev, Alexandre Pavlovski, et al. Solar power forecasting performance–towards industry standards. In 1st international workshop on the integration of solar power into power systems, Aarhus, Denmark. Energynautics GmbH M ¨ uhlstraße Langen, Germany, 2011.
[33] AM Kozae, Mohamed Shokry, and Manar Omran. Comparison between fuzzy soft expert system and
intuitionistic fuzzy set in prediction of luge cancer. Information Sciences Letters, 10(2):167–176, 2021.
[34] Hitoshi Kusama, Yoshinari Konishi, and Hideki Sugihara. Data mining assisted by theoretical calculations for improving dye-sensitized solar cell performance. Solar energy materials and solar cells, 91(1):76–78, 2007.
[35] George Kyriakarakos, Konstantinos Patlitzianas, Markos Damasiotis, and Dimitrios Papastefanakis. A fuzzy cognitive maps decision support system for renewables local planning. Renewable and Sustainable Energy Reviews, 39:209–222, 2014.
[36] M Lashin and A Malibari. Using fuzzy logic control system as an artificial intelligence tool to design soap bubbles robot as a type of interactive games. Inf. Sci. Lett, 11:15–19, 2022.
[37] M Leyva, P Del Pozo, and A Pe˜ nafiel. Neutrosophic dematel in the analysis of the causal factors of youth violence. International Journal of Neutrosophic Science, 18(3):199–207, 2022.
[38] Bjørn Ludwig. On the sustainability of future energy systems. Energy conversion and management, 38(15-17):1765–1775, 1997.
[39] Rasha M Abd El-Aziz, Rayan Alanazi, Osama R Shahin, Ahmed Elhadad, Amr Abozeid, Ahmed I Taloba, and Riyad Alshalabi. An effective data science technique for iot-assisted healthcare monitoring system with a rapid adoption of cloud computing. Computational Intelligence and Neuroscience, 2022, 2022.
[40] Ajjaz Maqbool, Chitranjan Sharma, Mushtaq A Lone, and Riyad Alshalabi. Intuitionistic fuzzy programming technique to solve multi-objective transportation problem. Res Rev J Stat Math Sci, 7(6):1–9, 2021.
[41] Manal Marzouq, Hakim El Fadili, Khalid Zenkouar, Zakia Lakhliai, and Mohammed Amouzg. Short term solar irradiance forecasting via a novel evolutionary multi-model framework and performance assessment for sites with no solar irradiance data. Renewable Energy, 157:214–231, 2020.
[42] Elena Mocanu, Phuong H Nguyen, Madeleine Gibescu, and Wil L Kling. Deep learning for estimating building energy consumption. Sustainable Energy, Grids and Networks, 6:91–99, 2016.
[43] Khalida Inayat Noor. Fuzzy differential subordination involving generalized noor-salagean operator. Inf. Sci. Lett, 11:1–7, 2022.
[44] Hiral N Pandya, Sachin P Parikh, and Manan Shah. Comprehensive review on application of various nanoparticles for the production of biodiesel. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 44(1):1945–1958, 2022.
[45] Lu Peng, Shan Liu, Rui Liu, and Lin Wang. Effective long short-term memory with differential evolution algorithm for electricity price prediction. Energy, 162:1301–1314, 2018.
[46] Atika Qazi, H Fayaz, Ali Wadi, Ram Gopal Raj, NA Rahim, and Waleed Ahmed Khan. The artificial neural network for solar radiation prediction and designing solar systems: a systematic literature review. Journal of cleaner production, 104:1–12, 2015.
[47] Zeynab Ramedani, Mahmoud Omid, Alireza Keyhani, Benyamin Khoshnevisan, and Hadi Saboohi. A comparative study between fuzzy linear regression and support vector regression for global solar radiation prediction in iran. Solar Energy, 109:135–143, 2014.
[48] Jingzheng Ren and Benjamin K Sovacool. Enhancing china’s energy security: Determining influential factors and effective strategic measures. Energy conversion and management, 88:589–597, 2014.
| Style | # |
|---|---|
| MLA | Mohammed Alqarni, Ahmed H. Samak, Safaa S. I. Ismail, Rasha M. Abd El-Aziz, Ahmed I. Taloba. "Utilizing a Neutrosophic Fuzzy Logic System with ANN for Short-Term Estimation of Solar Energy." International Journal of Neutrosophic Science, Vol. 20, No. 4, 2023 ,PP. 240-259 (Doi : https://doi.org/10.54216/IJNS.200422) |
| APA | Mohammed Alqarni, Ahmed H. Samak, Safaa S. I. Ismail, Rasha M. Abd El-Aziz, Ahmed I. Taloba. (2023). Utilizing a Neutrosophic Fuzzy Logic System with ANN for Short-Term Estimation of Solar Energy. Journal of International Journal of Neutrosophic Science, 20 ( 4 ), 240-259 (Doi : https://doi.org/10.54216/IJNS.200422) |
| Chicago | Mohammed Alqarni, Ahmed H. Samak, Safaa S. I. Ismail, Rasha M. Abd El-Aziz, Ahmed I. Taloba. "Utilizing a Neutrosophic Fuzzy Logic System with ANN for Short-Term Estimation of Solar Energy." Journal of International Journal of Neutrosophic Science, 20 no. 4 (2023): 240-259 (Doi : https://doi.org/10.54216/IJNS.200422) |
| Harvard | Mohammed Alqarni, Ahmed H. Samak, Safaa S. I. Ismail, Rasha M. Abd El-Aziz, Ahmed I. Taloba. (2023). Utilizing a Neutrosophic Fuzzy Logic System with ANN for Short-Term Estimation of Solar Energy. Journal of International Journal of Neutrosophic Science, 20 ( 4 ), 240-259 (Doi : https://doi.org/10.54216/IJNS.200422) |
| Vancouver | Mohammed Alqarni, Ahmed H. Samak, Safaa S. I. Ismail, Rasha M. Abd El-Aziz, Ahmed I. Taloba. Utilizing a Neutrosophic Fuzzy Logic System with ANN for Short-Term Estimation of Solar Energy. Journal of International Journal of Neutrosophic Science, (2023); 20 ( 4 ): 240-259 (Doi : https://doi.org/10.54216/IJNS.200422) |
| IEEE | Mohammed Alqarni, Ahmed H. Samak, Safaa S. I. Ismail, Rasha M. Abd El-Aziz, Ahmed I. Taloba, Utilizing a Neutrosophic Fuzzy Logic System with ANN for Short-Term Estimation of Solar Energy, Journal of International Journal of Neutrosophic Science, Vol. 20 , No. 4 , (2023) : 240-259 (Doi : https://doi.org/10.54216/IJNS.200422) |