The use of artificial intelligence technologies in energy and climate security

Mammadov, Agil; Ibrahimli, Kanah; Guliev, Iglfal

Artykuł - szczegóły

Tytuł artykułu

The use of artificial intelligence technologies in energy and climate security

Autorzy

Mammadov Agil , Ibrahimli Kanah , Guliev Iglfal

Identyfikatory

Warianty tytułu

Języki publikacji

Abstrakty

This study provides a theoretical analysis of the use and application of artificial intelligence in the energy sector as it relates to climate security. The object of the study is energy and climate security as types of economic activity and social activity. The subject of the research is artificial intelligence in relation to the object area of research. The purpose of the study is to create a sound scientific basis for the use of artificial intelligence in the energy sector, as well as to identify emerging problems in the formation of a science-based approach to climate policy development. The authors' research includes three interrelated research methodologies: topic modeling, text mining as part of qualitative analysis and object modeling as part of the systematization of results that are adequate to the subject area of the study and correspond to their reality; in addition, the authors supplemented the quantitative results with a theoretical and heuristic analysis of the scientific results of other researchers. The concept of parametric optimization (PO) is used as an effective method for solving the applied problem of testing the hypothesis of managing energy costs and energy efficiency based on AI in order to achieve optimal performance of the technical system and compliance with the SDGs in the field of climate security. The study's findings suggest that AI is becoming fundamental to the development of a modern energy sector based on data and complex relationships and provides tools to improve technical system performance and efficiency in the face of sanctions restrictions. The truth of the hypothesis has been proven that the use of AI as a control feedback loop at a technical facility for purification and energy generation is a more cost-effective and technically optimal alternative to a “live” operator, which will eliminate the human error factor. In this regard, the energy industry, utilities, grid operators and independent power producers must pay special attention to the introduction of AI technologies into existing technical systems.

Słowa kluczowe

energy efficiency energy saving feedback loop intelligent algorithm optimization

Wydawca

KAPRINT

Czasopismo

Rynek Energii

Rocznik

2025

Tom

Nr 5

Strony

100--108

Opis fizyczny

Bibliogr. 36 poz., fig.

Twórcy

autor

Mammadov Agil

Science Department, British Lyceum, Moscow

autor

Ibrahimli Kanah

Science Department, European Azerbaijan School

autor

Guliev Iglfal

MGIMO—University

Bibliografia

[1] Abdalla A. N. et al.: Integration of energy storage system and renewable energy sources based on artificial intelligence: An overview. Journal https://doi.org/10.1016/j.est.2021.102811 of Energy Storage. T. 40. P. 102811.
[2] Ahmad T. et al.: Artificial intelligence in sustainable energy industry: Status Quo, challenges and ibpportunities. Journal of Cleaner https://doi.org/10.1016/j.jclepro.2021. 125834 Production. T. 289. P. 125834.
[3] Ahmad T., Zhang H., Yan B. A review on renewable energy and electricity requirement forecasting models for smart grid and buildings. https://doi.org/10.1016/j.scs.2020.102052
[4] Ajagekar A, You F. 2022. Quantum computing and quantum artiﬁcial intelligence for renewable and sustainable energy: A emerging prospect towards climate neutrality. Renewable and Sustainable Energy Reviews. T. 165. P. 112493. https: //doi. org/10. 1016/j.rser.2022. 112493
[5] Ali A.,Majhi S: Integral criteria for optimal tuning of PI/PID controllers for integrating processes. Asian Journal of Control. 2011. 13. No. 2. pp. 328-337. https://doi.org/10.1002/asjc.278
[6] Balachandran G. B. et al.: Comparative investigation of imaging techniques, preprocessing and visual fault diagnosis using artiﬁcial intelligence models for solar photovoltaic system - A comprehensive review. Measurement. T. 232. P. 114683. https://doi.org/10%.1016/J' .measurement.2024.114683
[7] Certiﬁcate of state registration of a computer program No. 2017614254 Russian Federation. Program for parametric generation of a model of a high-performance computing complex and optimization of the model according to a given criterion: No. 2017611315: application. 02/16/2017: publ. 04/10/2017 / G. I. Evtushenko, A. B. Novikov, A. G. Vorontsov, S. A. Petunin; applicant Federal State Unitary Enterprise "All- Russian Scientiﬁc Research Institute of Automation named after N.L. Dukhov" (FSUE "VNIIA"). - EDN CPYKXK.
[8] Certiﬁcate of state registration of a computer program No. 2018663352 Russian Federation. Program for implementing a universal algorithm for solving parametric optimization problems: No. 2018617155: application. 07/06/2018: publ. 10.25.2018 / V. A. Koveshnikov. - EDN LNYIJL.
[9] Chen C. et al.: Artiﬁcial intelligence on economic evaluation of energy efﬁciency and renewable Energy technologies. Sustainable Energy Technologies and Assessments. T. 47. P. 101358. https://doi.org/10.1016/j.seta.2021.101358
[10 Fan Z., Yan Z., Wen S.: Deep learning and artiﬁcial intelligence in sustainability: a review of SDGs, renewable energy, and environmental health. Sustainability. T. 15. 2023. No. 18. P. 13493. https://doi.org/ 10.3390/su151813493
[11] Francisco M.” Artiﬁcial intelligence for environmental security: national, international, human and environmental perspectives. Current Opinion in Environmental Sustainability. T. 61. 2023. P. 101250. https://doi.org/10.1016/j.cosust.2022.101250
[12] Franki V., Majnarić D., Viśković A. A.: Comprehensive review of artificial intelligence (AI) companies in the power sector. Energies. 2023. T. 16. No. 3. P. 1077. https://doi.org/10.3390/en16031077
[13] Grabchak, E. P.: Introduction of digital platforms with elements of artiﬁcial intelligence to support decision—making in complex technological situations in the Russian energy sector. Mechatronics, automation and robotics. 2022 No. 9. Pp. 93-96. - DOI 10.26160/2541-8637-2022-9-93-96. - EDN EYNAUC.
[14] Han Z. et al.: Stakeholder engagement in natural resources for energy transitions governance. Environmental ImpactAssessment Review. T. 102. Pp. 107206. https://doi.org/10.1016/j.eiar.2023.107206
[15] Hramov, A. E., Maksimenko V. A., Pisarchik A. N.: Physical principles of brain-computer interfaces and their applications for rehabilitation, robotics and control of human brain states. Physics Reports. T. 918. Pp. 1- 133. https. //doi.org/10.1016/j p.h.ysrep 2021.03.002
[16] Leonelli S, Williamson H. F.: Artificial Intelligence in Plant and Agricultural Research. Artiﬁcial Intelligence for Science. A Deep Learning Revolution. 2023. Pp. 3 19-333. https://doi.org/10.1142/9789811265679_0018
[17] Li J., Liu P., Li Z.: Optimal design and techno-economic analysis of a solar-wind-biomass off-grid hybrid power system for remote rural electriﬁcation: A case study of west China. Energy. 2020. T. 208. P. 118387. https://doi.org/10.1016/j.energy.2020.118387
[18] Li X. et al.: Interpretable deep learning: Interpretation, interpretability, trustworthiness, and beyond. Knowledge and Information Systems. 2022. 64. No. 12. pp. 3197-3234. https://doi.org/10.1007/s10115-022-01756-8
[19] Lin G. et al.: Implementation and test of an automated control hunting fault correction algorithm in a fault detection and diagnostics tool. Energy and Buildings. 2023. T. 283. P. 112796. https.//doi.org/10. 1016/J'. enbuild.2023.112796
[20] MachlevnR. et al.. Eplainable Artificial Intelligence (XAI) techniques for energy and power systems: Review, challenges and opportunities. Energy and A1 2022. T. 9. P. 100169. https: //doi.org/10.1016/j.egyai.2022.100169
[21] Mashio K., Kasamatsu M., Noda E.: Development d..-Emergency Information System to Support Nuclear Power Plant Management in Severe Accident. Nuclear Technology. 2023. T. 209. No. 3. pp. 346-353. https://doi.org/10.1080/00295450.2022.2087837
[22] Massel, L. V.: The current stage of development of artificial intelligence (AI) and the application of AI methods and systems in the energy sector. Information and mathematical technologies in science and management. No. 4(24). P. 5-20. DOI 10.38028/ESI.2021.24.4.001. - EDN WGRJMS.
[23] Mayer M. J., Szilagyi A., Gróf G.: Environmental and economic multi-obj ective optimization of a household level hybrid renewable energy system by genetic .; algorithm. Applied Energy. T. 269. P. 115058. https://doi.org/10.1016/j.apenergy.2020.115058\
[24] Nagy Z. et al.: Ten questions concerning reinforcement learning for building energy management. Building and Environment. 2023. T. 241. P. 110435. https://doi.org/10.1016/j.buildenv.2023.110435
[25] Ohalete N. C. et al. AI-driven solutions in renewable energy: A review of data science applications in solar and wind energy optimization. World Journal of Advanced Research and Reviews. 2023. T. 20. No. 3. pp. 401-417. https://doi.org/10.30574/wjarr.202320.3.2433
[26] Raihan A. A.: Comprehensive review of artiﬁcial intelligence and machine learning applications in the energy sector. Journal of Technology Innovations and Energy. 2023. 2. No. 4. ' Pp. 1-26. https://doi.org/1 0.5 65 5 6/jtie.v2i4.608
[27] Raihan A. A.: Concise review of technologies for converting forest biomass to bioenergy. Journal of Technology Innovations and Energy. 2023. T. 2. No. 3.pp. 10-36. https://doi.org/10.5 65 56/jtie.v2i3.592
[28] Shang Y. et al.: Employing artiﬁcial intelligence and enhancing resource efﬁciency to achieve carbon neutrality. Resources Policy. T. 88. P. 104510. https://doi.org/10.1016/j.resourpol.2023.104510
[29] Slama S. B., Mahmoud M.: A deep learning model for intelligent home energy management system using renewable energy. Engineering Applications of Artificial Intelligence. 2024. T. 123. P. 106388. https://doi.org/10.1016/j.engappai.2023.106388
[30] Sweeney C. et al.: The future of forecasting for renewable energy. Wiley Interdisciplinary Reviews: Energy and Environment. 2020. T. 9. No. 2. Pp. e365. https://doi.org/10.1002/wene.365
[31] Utility model patent No. 120525 U1 Russian Federation, IPC H02K 7/18, F 03B 13/10. Device for receiving and converting mechanical energy of a ﬂuid ﬂow into electricity: No. 2012113352/07: application. .. 04/06/2012: publ. 09.20.2012 / P. G. Kolpakhchyan, L. I. Lavronova, R. B. Lobov, I. N. Sysoeva; applicant Limited Liability Company Scientiﬁc and Production Enterprise "Don Technologies". - EDN MDDJPD.
[32] Utility model patent No. 158767 U1 Russian Federation, IPC F03B 13/00. device for generating electricity from wastewater: No. 2015106532/06: application. 02/25/2015: publ. 01/20/2016 / A. V. Shaikhislamov, V. N. Zentsov, V. F. Shaikhislamov, V. A. Khairullin; applicant Federal State Budgetary Educational Institution of Higher Professional Education "Ufa State Petroleum Technical University". - EDN QFSDUW.
[33] Wang, B. et al.: How does artiﬁcial intelligence affect high-quality energy development? Achieving a clean energy transition society. Energy Policy? 2024. T. 186. Pp. 1 14010. https://doi.org/10.1016/j.enpol.2024.114010 '
[34] Yang, C. et al.: Optimal power ﬂow in distribution network: A review on problem formulation and optimization methods. Energies. 2023. 16. No. 16. Pp. 5974. https://doi.org/10.3390/en16165974
[35] Zentsov, V. N., Astashina, M. V., Kuznetsova, E. V., Khairullin V. A.: Solutions for energy saving when changing the design solutions of water supply and sanitation facilities. Internet Journal of Science. 2016. T., No. 3(34). P. 28. - EDN WIRITZ.
[36] Zoidov, K. Kh.: Digital authenticity of reality: expanding the boundariesof reliability in management in the Russian energy sector based on the use of elements of artiﬁcial intelligence. Education. The science. Scientific personnel. 2019. No. 4. Pp. 127-130. DOI 10.24411/2073-3305-2019-10201.- EDN DYWPVY.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-f78e42e1-43a4-437a-92ac-32c8e5c51609