Calculation of Available Transfer Capability Using Hybrid Chaotic Selfish Herd Optimizer and 24 Hours RES-thermal Scheduling

doi:10.23919/CJEE.2023.000032

中国电气工程学报（英文） ›› 2023, Vol. 9 ›› Issue (4): 54-72.doi: 10.23919/CJEE.2023.000032

收稿日期:2023-01-14 修回日期:2023-06-13 接受日期:2023-08-23 发布日期:2024-01-08

Calculation of Available Transfer Capability Using Hybrid Chaotic Selfish Herd Optimizer and 24 Hours RES-thermal Scheduling

Kingsuk Majumdar^1,*, Provas Kumar Roy², Subrata Banerjee³

1. Department of Electrical Engineering, Dr. B C Roy Engineering College, Durgapur 713206, India;
2. Department of Electrical Engineering, Kalyani Government Engineering College, Kalyani 741235, India;
3. Department of Electrical Engineering, NIT Durgapur, Durgapur 713209, India

Received:2023-01-14 Revised:2023-06-13 Accepted:2023-08-23 Published:2024-01-08
Contact: *E-mail: kingsuk.majumdar5@gmail.com
About author:Kingsuk Majumdar received his Ph.D. degree and M.Tech. in Electrical Engineering from NIT Durgapur, 2023 and 2013, respectively. He is an Assistant Professor in the Department of Electrical Engineering, Dr. B C Roy Engineering College, Durgapur. His research interests include optimization, power system, power electronics, etc. He has guided several B.Tech. and three M.Tech. students. He is an associate member of The Institution of Engineers (India).
Provas Kumar Roy obtained Ph.D. degree in Electrical Engineering from National Institute of Technology Durgapur in 2011. He received his Master degree in Electrical Machine in 2001 from Jadavpur University. He finished his Engineering studies in Electrical Engineering from Regional Engineering College (Presently Known as National Institute of Technology) Durgapur. Presently, he is working as a Professor in lectrical Engineering Department at Kalyani Government Engineering College, West Bengal, India. He was the recipient of the Outstanding Reviewer Award for IJEPES (Elsevier, 2018), EAAI (Elsevier, 2017), Renewable Energy Focus (Elsevier, 2018), ASEJ (Elsevier, 2017). He has published more than 150 research papers in national/international journals and conference and more than 75 journals published in reputed SCI and Scopus indexed Journals, and more than 10 book chapters and two books of international standard. Six research scholars have obtained their Ph.D. degree under his guidance and 8 students are perusing their Ph.D. under his guidance. His research interests include economic load dispatch, optimal power flow, FACTS, automatic generation control, radial distribution network, power system stabilizer, image processing, machine learning, evolutionary techniques, etc.
Subrata Banerjee (M'04-SM'15) has received his Ph.D. degree from IIT Kharagpur, India in 2005. He is working as Professor with the Department of Electrical Engineering, NIT, Durgapur, India. His research interests include modeling & control of switch-mode converters and inverters, multilevel inverters & different modulation techniques, electromagnetic levitation & control system design, etc. He has successfully completed few research and consultancy projects. He has authored about 195 research papers in national/international journals and conference records & 7 book chapters. He has guided 10 Ph.D. and 22 M.Tech. students and many are pursuing their degree under his guidance. He has filed three Indian patents out of which one has been granted. Prof. Banerjee is the recipient of several academic awards, including 10 nos. Best Paper Awards and TATA RAO Prize etc. He is a Fellow of the IE (India), the IETE (India), and the IET (UK), Senior Member IEEE (USA). He is serving as Associate Editor in IEEE Access (USA), IET Power Electronics (UK), IEEE TEC eNewsletter (USA), Transportation Electrification IEEE (USA).

摘要/Abstract

Abstract: As fossil fuel stocks are being depleted, alternative sources of energy must be explored. Consequently, traditional thermal power plants must coexist with renewable resources, such as wind, solar, and hydro units, and all-day planning and operation techniques are necessary to safeguard nature while meeting the current demand. The fundamental components of contemporary power systems are the simultaneous decrease in generation costs and increase in the available transfer capacity (ATC) of current systems. Thermal units are linked to sources of renewable energy such as hydro, wind, and solar power, and are set up to run for 24 h. By contrast, new research reports that various chaotic maps are merged with various existing optimization methodologies to obtain better results than those without the inclusion of chaos. Chaos seems to increase the performance and convergence properties of existing optimization approaches. In this study, selfish animal tendencies, mathematically represented as selfish herd optimizers, were hybridized with chaotic phenomena and used to improve ATC and/or reduce generation costs, creating a multi-objective optimization problem. To evaluate the performance of the proposed hybridized optimization technique, an optimal power flow-based ATC was enforced under various hydro-thermal-solar-wind conditions, that is, the renewable energy source-thermal scheduling concept, on IEEE 9-bus, IEEE 39-bus, and Indian Northern Region Power Grid 246-bus test systems. The findings show that the proposed technique outperforms existing well-established optimization strategies.

Key words: Available transfer capability (ATC), biogeography-based optimization (BBO), chaotic map, chaotic selfish herd optimizer (CSHO), grey wolf optimizer (GWO), optimum power flow (OPF), power generation cost (PGC), renewable energy sources (RES), selfish herd optimizer (SHO)

. [J]. 中国电气工程学报（英文）, 2023, 9(4): 54-72.

Kingsuk Majumdar, Provas Kumar Roy, Subrata Banerjee. Calculation of Available Transfer Capability Using Hybrid Chaotic Selfish Herd Optimizer and 24 Hours RES-thermal Scheduling[J]. Chinese Journal of Electrical Engineering, 2023, 9(4): 54-72.

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Calculation of Available Transfer Capability Using Hybrid Chaotic Selfish Herd Optimizer and 24 Hours RES-thermal Scheduling

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