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Arabian Journal for Science and Engineering

30-04-2024 | Research Article-Electrical Engineering

Adaptive Neuro-fuzzy Inference System-Based Data-Driven Model for Optimal Recharging of Electric Vehicles and Cost Prediction in Energy Hubs

Author: Muhammad Khalid

Published in: Arabian Journal for Science and Engineering

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Abstract

This study presents a hybrid neuro-fuzzy prognostic framework that develops an energy allocation method for current urban power infrastructure. This is accomplished by combining a nature-inspired intelligent optimization method with the learning capabilities, interpretability, and reasoning powers of neural networks, known as an adaptive neuro-fuzzy interface system. To align the problem’s representation with real-world situations, this study includes different charging demand tactics enforced by electric vehicles (EVs) along with the limitations of the power-generating systems at energy facilities to achieve optimal power generation. The implementation of the one-day pricing structure entails a complex optimization process aimed at reducing costs and minimizing the release of detrimental emissions. The proposed model was constructed using an adaptive neuro-fuzzy approach, with the training data derived from this optimization problem as the central component. The proposed approach effectively handled the diverse energy demand patterns demonstrated by EVs, encompassing the Electric Power Research Institute recommendations, stochastic behavior, and both peak and off-peak charging. This cooperation occurs systematically. The Crow Search Algorithm-Adaptive Neural Fuzzy Inference System achieved a reduction in operational expenditures in terms of percentages, such as 2.66%, 3.39%, 3.94%, and 2.63% for all recharging scenarios. These values are lower than those of other advanced approaches. The hybrid strategy that has been established has several benefits, such as the efficient management of various scenarios related to the demand for charging energy for EVs and the development of a predictive cost scheme. This scheme can assist policymakers in formulating cost-effective energy policies and budget plans for future EV loads. Moreover, they offer the advantage of self-reliance, allowing EV owners to charge their cars economically in many accessible situations. Another important component is the ability of urban planners to reduce greenhouse gas emissions from power generation, thereby promoting the development of an ecologically sustainable charging infrastructure. Finally, a benchmark test system was employed to evaluate the efficacy of the proposed approach across different energy consumption patterns.

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Literature
1.
2.
Camargos, T.P.; Costa, A.O.; Junior, E.F.C.: Energy and exergy analyses of a sustainable calcination process in a vertical limekiln performing with producer gas as renewable biofuel derived from eucalyptus wood biomass gasification. Arab. J. Sci. Eng. 49, 1–33 (2023)
3.
Khalid, M.: Smart grids and renewable energy systems: Perspectives and grid integration challenges. Energ. Strat. Rev. 51, 101299 (2024)CrossRef
4.
Limon, M.H.; Debnath, B.; Bari, A.M.: Exploration of the drivers influencing the growth of hybrid electric vehicle adoption in the emerging economies: Implications towards sustainability and low-carbon economy. Sustain. Oper. Comput. 4, 76–87 (2023)CrossRef
5.
Ahmed, I.; Rehan, M.; Basit, A.; Ahmad, H.; Ahmed, W.; Ullah, N.; Piecha, M.; Blazek, V.; Prokop, L.: Review on microgrids design and monitoring approaches for sustainable green energy networks. Sci. Rep. 13(1), 21663 (2023)CrossRef
6.
Ahmed, I.; Basit, A.; Mustafa, F.; Alqahtani, M.; Khalid, M.: The nexus of energy in microgrids: a review on communication barriers in distributed networks auxiliary controls. IET Gener. Transm. Distrib. 17(22), 4907–4922 (2023)CrossRef
7.
Gong, X.; Wang, X.; Cao, B.: On data-driven modeling and control in modern power grids stability: survey and perspective. Appl. Energy 350, 121740 (2023)CrossRef
8.
Khatamianfar, A.; Khalid, M.; Savkin, A.V.; Agelidis, V.G.: Improving wind farm dispatch in the Australian electricity market with battery energy storage using model predictive control. IEEE Trans. Sustain. Energy 4(3), 745–755 (2013)CrossRef
9.
Alvi, U.-E.-H.; Ahmed, W.; Rehan, M.; Ahmed, S.; Ahmad, R.; Ahmed, I.: A novel incremental cost consensus approach for distributed economic dispatch over directed communication topologies in a smart grid. Soft. Comput. 26(14), 6685–6700 (2022)CrossRef
10.
Ahmed, I.; Alvi, U.-E.-H.; Basit, A.; Khursheed, T.; Alvi, A.; Hong, K.-S.; Rehan, M.: A novel hybrid soft computing optimization framework for dynamic economic dispatch problem of complex non-convex contiguous constrained machines. PLoS ONE 17(1), 0261709 (2022)CrossRef
11.
Duan, Y.; Zhao, Y.; Hu, J.: An initialization-free distributed algorithm for dynamic economic dispatch problems in microgrid: Modeling, optimization and analysis. Sustain. Energy Grids Netw. 34, 101004 (2023)CrossRef
12.
Yu, H.; Niu, S.; Shang, Y.; Shao, Z.; Jia, Y.; Jian, L.: Electric vehicles integration and vehicle-to-grid operation in active distribution grids: A comprehensive review on power architectures, grid connection standards and typical applications. Renew. Sustain. Energy Rev. 168, 112812 (2022)CrossRef
13.
Tian, X.; An, C.; Nik-Bakht, M.; Chen, Z.: Assessment of reductions in \({NO}_2\) emissions from thermal power plants in Canada based on the analysis of policy, inventory, and satellite data. J. Clean. Prod. 341, 130859 (2022)CrossRef
14.
Ravi, S.S.; Brace, C.; Larkin, C.; Aziz, M.; Leach, F.; Turner, J.W.: On the pursuit of emissions-free clean mobility-electric vehicles versus e-fuels. Sci. Total Environ. 875, 162688 (2023)CrossRef
15.
Robba, M.; Dotoli, M.; Paolucci, M.: Guest editorial special section on advances in automation and optimization for sustainable transportation and energy systems. IEEE Trans. Autom. Sci. Eng. 19(1), 3–6 (2022)CrossRef
16.
Ranjbar, H.; Sharifzadeh, M.: Electrification of transportation: Transition toward energy sustainability. Industry 4.0 Vision for Energy and Materials Enabling Technologies and Case Studies. 10, 269–296 (2022)CrossRef
17.
Sillman, J.; Hynynen, K.; Dyukov, I.; Ahonen, T.; Jalas, M.: Emission reduction targets and electrification of the finnish energy system with low-carbon power-to-x technologies: Potentials, barriers, and innovations-a delphi survey. Technol. Forecast. Soc. Chang. 193, 122587 (2023)CrossRef
18.
Haran, K.S.: IEEE TTE special issue on electrified aircraft technologies. IEEE Trans. Transp. Electr. 8(4), 4033–4036 (2022)CrossRef
19.
Sacchi, R.; Bauer, C.; Cox, B.; Mutel, C.: When, where and how can the electrification of passenger cars reduce greenhouse gas emissions? Renew. Sustain. Energy Rev. 162, 112475 (2022)CrossRef
20.
Zou, W.; Sun, Y.; Gao, D.-C.; Zhang, X.; Liu, J.: A review on integration of surging plug-in electric vehicles charging in energy-flexible buildings: impacts analysis, collaborative management technologies, and future perspective. Appl. Energy 331, 120393 (2023)CrossRef
21.
Mastoi, M.S.; Zhuang, S.; Munir, H.M.; Haris, M.; Hassan, M.; Alqarni, M.; Alamri, B.: A study of charging-dispatch strategies and vehicle-to-grid technologies for electric vehicles in distribution networks. Energy Rep. 9, 1777–1806 (2023)CrossRef
22.
Acharige, S.S.; Haque, M.E.; Arif, M.T.; Hosseinzadeh, N.; Hasan, K.N.; Oo, A.M.T.: Review of electric vehicle charging technologies, standards, architectures, and converter configurations. IEEE Access (2023)
23.
Thiel, C.; Amillo, A.G.; Tansini, A.; Tsakalidis, A.; Fontaras, G.; Dunlop, E.; Taylor, N.; Jäger-Waldau, A.; Araki, K.; Nishioka, K.: Impact of climatic conditions on prospects for integrated photovoltaics in electric vehicles. Renew. Sustain. Energy Rev. 158, 112109 (2022)CrossRef
24.
Jeyaraj, P.R.; Asokan, S.P.; Karthiresan, A.C.: Optimum power flow in DC microgrid employing Bayesian regularized deep neural network. Electr. Power Syst. Res. 205, 107730 (2022)CrossRef
25.
Athanasopoulou, L.; Bikas, H.; Papacharalampopoulos, A.; Stavropoulos, P.; Chryssolouris, G.: An industry 4.0 approach to electric vehicles. Int. J. Comput. Integr. Manuf. 36(2), 334–348 (2023)CrossRef
26.
Guo, G.; Xu, P.; Bai, Z.; Zhou, S.; Xu, G.; Cao, B.: Optimization of ni-mh battery fast charging in electric vehicles using dynamic data mining and anfis. In: Advanced Intelligent Computing Theories and Applications. With Aspects of Artificial Intelligence: 4th International Conference on Intelligent Computing, ICIC 2008 Shanghai, China, September 15-18, 2008 Proceedings 4, pp. 468–475 (2008). Springer
27.
Ray, S.; Kasturi, K.; Patnaik, S.; Nayak, M.R.: Review of electric vehicles integration impacts in distribution networks: placement, charging/discharging strategies, objectives and optimisation models. J. Energy Stor. 72, 108672 (2023)CrossRef
28.
Cao, S.: The impact of electric vehicles and mobile boundary expansions on the realization of zero-emission office buildings. Appl. Energy 251, 113347 (2019)CrossRef
29.
Okwu, M.O.; Emovon, I.; Oyejide, O.J.; Ezekiel, K.C.; Messiah, O.; Jones-Iwuagwu, P.C.: Performance analysis of a light weight ground robotic vehicle by implementing adaptive neuro-fuzzy inference system (anfis). In: 2023 International Conference on Artificial Intelligence, Big Data, Computing and Data Communication Systems (icABCD), pp. 1–7 (2023). IEEE
30.
George, S.; Rajeev, T.: Fuzzy-based control strategy for supercapacitor assisted battery powered ev. In: 2023 International Conference on Control, Communication and Computing (ICCC), pp. 1–6 (2023). IEEE
31.
Pozzi, A.; Raimondo, D.M.: Stochastic model predictive control for optimal charging of electric vehicles battery packs. J. Energy Stor. 55, 105332 (2022)CrossRef
32.
Zou, Y.; Zhao, J.; Ding, D.; Miao, F.; Sobhani, B.: Solving dynamic economic and emission dispatch in power system integrated electric vehicle and wind turbine using multi-objective virus colony search algorithm. Sustain. Cities Soc. 67, 102722 (2021)CrossRef
33.
Navin, N.K.: A multiagent fuzzy reinforcement learning approach for economic power dispatch considering multiple plug-in electric vehicle loads. Arab. J. Sci. Eng. 46(2), 1431–1449 (2021)CrossRef
34.
Basu, M.: Dynamic economic emission dispatch using nondominated sorting genetic algorithm-ii. Int. J. Electr. Power Energy Syst. 30(2), 140–149 (2008)CrossRef
35.
Pandit, N.; Tripathi, A.; Tapaswi, S.; Pandit, M.: An improved bacterial foraging algorithm for combined static/dynamic environmental economic dispatch. Appl. Soft Comput. 12(11), 3500–3513 (2012)CrossRef
36.
Ahmed, I.; Rehan, M.; Basit, A.; Hong, K.-S.: Greenhouse gases emission reduction for electric power generation sector by efficient dispatching of thermal plants integrated with renewable systems. Sci. Rep. 12(1), 12380 (2022)CrossRef
37.
Ghasemi, M.; Akbari, E.; Zand, M.; Hadipour, M.; Ghavidel, S.; Li, L.: An efficient modified HPSO-TVAC-based dynamic economic dispatch of generating units. Electr. Power Compon. Syst. 47(19–20), 1826–1840 (2019)CrossRef
38.
Ahmed, I.; Basit, A.; Rehan, M.; Hong, K.-S.: Multi-objective whale optimization approach for cost and emissions scheduling of thermal plants in energy hubs. Energy Rep. 8, 9158–9174 (2022)CrossRef
39.
40.
Ahmed, I.; Rehan, M.; Basit, A.; Malik, S.H.; Ahmed, W.; Hong, K.-S.: Adaptive SALP swarm algorithm for sustainable economic and environmental dispatch under renewable energy sources. Renew. Energy 223, 119944 (2024)CrossRef
41.
Ahmed, I.; Rehan, M.; Basit, A.; Tufail, M.; Ullah, N.; Piecha, M.; Blazek, V.; Prokop, L.: A novel distributed approach for event-triggered economic dispatch of energy hubs under ramp-rate limits integrated with sustainable energy networks. Energy Rep. 10, 4097–4111 (2023)CrossRef
42.
Mastoi, M.S.; Zhuang, S.; Munir, H.M.; Haris, M.; Hassan, M.; Alqarni, M.; Alamri, B.: A study of charging-dispatch strategies and vehicle-to-grid technologies for electric vehicles in distribution networks. Energy Rep. 9, 1777–1806 (2023)CrossRef
43.
Inci, M.; Savrun, M.M.; Çelik, Ö.: Integrating electric vehicles as virtual power plants: a comprehensive review on vehicle-to-grid (v2g) concepts, interface topologies, marketing and future prospects. J. Energy Stor. 55, 105579 (2022)CrossRef
44.
Khan, K.A.; Quamar, M.M.; Al-Qahtani, F.H.; Asif, M.; Alqahtani, M.; Khalid, M.: Smart grid infrastructure and renewable energy deployment: A conceptual review of Saudi Arabia. Energ. Strat. Rev. 50, 101247 (2023)CrossRef
45.
Hemavathi, S.; Shinisha, A.: A study on trends and developments in electric vehicle charging technologies. J. Energy Stor. 52, 105013 (2022)CrossRef
46.
Acharige, S.S.; Haque, M.E.; Arif, M.T.; Hosseinzadeh, N.; Hasan, K.N.; Oo, A.M.T.: Review of electric vehicle charging technologies, standards, architectures, and converter configurations. IEEE Access (2023)
47.
Unterluggauer, T.; Rich, J.; Andersen, P.B.; Hashemi, S.: Electric vehicle charging infrastructure planning for integrated transportation and power distribution networks: A review. ETransportation 12, 100163 (2022)CrossRef
48.
Ahmed, I.; Rehan, M.; Basit, A.; Tufail, M.; Hong, K.-S.: A dynamic optimal scheduling strategy for multi-charging scenarios of plug-in-electric vehicles over a smart grid. IEEE Access 11, 28992–29008 (2023)CrossRef
49.
Brady, J.; O’Mahony, M.: Modelling charging profiles of electric vehicles based on real-world electric vehicle charging data. Sustain. Cities Soc. 26, 203–216 (2016)CrossRef
50.
Askarzadeh, A.: A novel metaheuristic method for solving constrained engineering optimization problems: crow search algorithm. Comput. Struct. 169, 1–12 (2016)CrossRef
51.
Ahmed, I.; Rehan, M.; Basit, A.; Tufail, M.; Hong, K.-S.: Neuro-fuzzy and networks-based data driven model for multi-charging scenarios of plug-in-electric vehicles. IEEE Access 11, 87150–87165 (2023)CrossRef
52.
Li, J.; Yan, G.; Abbud, L.H.; Alkhalifah, T.; Alturise, F.; Khadimallah, M.A.; Marzouki, R.: Predicting the shear strength of concrete beam through anfis-ga-pso hybrid modeling. Adv. Eng. Softw. 181, 103475 (2023)CrossRef
53.
Gaing, Z.-L.; Ou, T.-C.: Dynamic economic dispatch solution using fast evolutionary programming with swarm direction. In: 2009 4th IEEE Conference on Industrial Electronics and Applications, pp. 1538–1544 (2009). IEEE
54.
Hoover, Z.; Nägele, F.; Polymeneas, E.; Sahdev, S.: How charging in buildings can power up the electric-vehicle industry. McKinsey 9, 1–8 (2021)
55.
Aziz, S.; Ahmed, I.; Khan, K.; Khalid, M.: Emerging trends and approaches for designing net-zero low-carbon integrated energy networks: A review of current practices. Arabian Journal for Science and Engineering, 1–23 (2023)
Metadata
Title
Adaptive Neuro-fuzzy Inference System-Based Data-Driven Model for Optimal Recharging of Electric Vehicles and Cost Prediction in Energy Hubs
Author
Muhammad Khalid
Publication date
30-04-2024
Publisher
Springer Berlin Heidelberg
Published in
Arabian Journal for Science and Engineering
Print ISSN: 2193-567X
Electronic ISSN: 2191-4281
DOI
https://doi.org/10.1007/s13369-024-09050-1

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