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Dynamic Economic Dispatch of Power System Network Having Thermal Units and Electric Vehicles using IGWO | ||
| Majlesi Journal of Electrical Engineering | ||
| مقاله 4، دوره 15، شماره 4، اسفند 2021، صفحه 43-62 اصل مقاله (1.13 M) | ||
| نوع مقاله: Review Article | ||
| شناسه دیجیتال (DOI): 10.52547/mjee.15.4.43 | ||
| نویسندگان | ||
| Anjali Jain* 1؛ Ashish Mani1؛ Anwar Siddiqui2 | ||
| 1Amity University Uttar Pradesh, India. | ||
| 2Jamia Milia Islamia, New Delhi, India. | ||
| چکیده | ||
| Dynamic economic dispatch (DED) is a complex power system problem. The problem becomes more complex with inclusion of electric vehicles. In the presented paper, Improved Grey Wolf Optimizer (IGWO) is proposed to solve this complex problem. IGWO is having a better balance between exploitation and exploration for the complex problem such as Dynamic Economic Dispatch (DED) taking into account of valve- point effect, transmission losses and ramp-rate limits with and without electric vehicles (EVs). The efficiency of the algorithm is demonstrated on solving different DED problems for 5 generator and 15 generator test systems with and without losses along with different charging profile distribution of electric vehicles. The results showcased by IGWO is compared with the other algorithm. The results obtained by IGWO algorithm using repair method adopted in solving dynamic economic dispatch problem is giving competitive results as compared to the results given by other algorithm present in literature. | ||
| کلیدواژهها | ||
| Non-Linear Constrained Optimization؛ Non-Convex Optimization؛ Evolutionary Algorithm؛ ramp rate limits؛ Valve Point Effects؛ GWOLF؛ Levy Flight | ||
| مراجع | ||
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[1] C. Kumar, T. Alwarswamy, “Dynamic economic dispatch-a review of solution methodologies”, European Journal of Scientific Research, (2011), pp.517-537
[2] Bechert, E. Thomas, C. Nanming, “Area automatic generation control by multi-pass dynamic programming”, IEEE Transaction on Power System, (1977), pp. 1460-1469
[3] W. G. Wood, “Spinning reserve constraints and dynamic economic dispatch”, IEEE Transactions on Power Apparatus, (1982), pp. 338-1338
[4] D. L. Travers, R. J. Kaye, “Dynamic dispatch by constructive dynamic programming”, IEEE Transactions on Power System, (1998), pp. 72-78
[5] R. W. Ferrero, S. M. Shahidehpour, “Dynamic econmic dispatch in deregulated systems”, Electric Power Energy System, (1997), pp. 433-439
[6] Ross, Dale W., K. Sungkook, “Dynamic economic dispatch of generation”, IEEE Transactions on Power Apparatus and Systems, (1980), pp. 2060-2068
[7] L. G. Papageorgious, E. S. Fraga, “A mixed integer quadratic programming formulation for the economic dispatch of generators with prohibited operating zones”, Electrical Power System Research, (2007), pp. 1292-1296
[8] J. A. Momoh, M. E. El-Hawary, R. Adapa, “A review of selected optimal power flow literature to 1993. PartII. Newton, linear programming and interior point methods”, IEEE Transactions on Power System, (1999), pp. 105-111
[9] C. B. Somuah, N. Khunaizi, “Application of linear programming redispatch technique to dynamic generation allocation” IEEE Transactions on Power System, (1990), pp. 20-26
[10] S. P. Han, “A Globally Convergent Method for Nonlinear Programming”, Report No. 75-257, Department of Computer Science, Cornell University, 1975.
[11] G. P. Granelli, P. Marannino, M. Montagna, A. Silvestri, “Fast and efficient gradient projection algorithm for dynamic generation dispatching” IET Digital Library, (1989), pp. 295-302
[12] S. Hemamalini, Sishaj P. Simon, “Dynamic economic dispatch using Maclaurin series based Lagrangian method”, Energy Conversion and Management (2010), pp. 2212-2219
[13] C. K. Panigrahi, P. K. Chattopadhyay, R. N. Chakrabarti, M. Basu, “Simulated annealing technique for dynamic economic dispatch." Electric power components and systems, (2006), pp.577-586.
[14] J. K. Pattanaik, M. Basu, D. P. Dash, “Dynamic economic dispatch: a comparative study for differential evolution, particle swarm optimization, evolutionary programming, genetic algorithm, and simulated annealing” Journal of Electrical Systems and Information Technology (2019), pp. 1-18
[15] K. P. Wong, C. C. Fung, “Simulated annealing based economic dispatch algorithm”, IET Digital Library, (1993), pp. 509-515.
[16] W. M. Lin, Fu-Sheng Cheng, Ming-Tong Tsay, “An improved tabu search for economic dispatch with multiple minima”, IEEE Transactions on Power Systems (2002), pp. 108-112
[17] B. K. Panigrahi, V. Ravikumar Pandi, Sanjoy Das, “Adaptive particle swarm optimization approach for static and dynamic economic load dispatch”Energy Conversion and Management (2008), pp. 1407-1415
[18] X. Yuan, L. Wang, Y. Yuan, Y. Zhang, B. Cao, B. Yang, “A modified differential evolution approach for dynamic economic dispatch with valve-point effects”, Energy Conversion and Management (2008), pp. 3447-3453
[19] S. Hemamalini, S. P. Simon, “Dynamic economic dispatch using artificial bee colony algorithm for units with valve‐point effect”, European Transactions on Electrical Power (2011), pp.70-81
[20] Secui, Dinu Calin, “A method based on the ant colony optimization algorithm for dynamic economic dispatch with valve‐point effects." International Transactions on Electrical Energy Systems (2015), pp.262-287
[21] R. Arul, G. Ravi, S. Velusami, “Chaotic self-adaptive differential harmony search algorithm based dynamic economic dispatch”, International Journal of Electrical Power & Energy Systems (2013), pp. 85-96
[22] Z. Yang, K. Li, Q. Niu, Y. Xue, A. Foley, “ A self-learning TLBO based dynamic economic/environmental dispatch considering multiple plug-in electric vehicle loads” Journal of Modern Power Systems and Clean Energy (2014), pp.298-307
[23] Y. C. Ho, D. L. Pepyne, “Simple explanation of the no-free-lunch theorem and its implications”, Journal of Optimization Theory and Applications (2002), pp. 549-570
[24] A. Mani, A. Jain, “Towards realistic mimicking of grey wolves hunting process for bounded single objective optimization” IEEE Congress on Evolutionary Computation (CEC) (2020), pp. 1-8
[25] S. Mirjalili, S. M. Mirjalili, and A. Lewis, “Grey wolf optimizer”, Advances in Engineering Software (2014) pp. 46-61
[26] A. Jain, A. Mani, A. S. Siddiqui, “Solving Dynamic Economic Dispatch Problem with Plug-in Electric Vehicles using GWOLF”, IEEE International Conference on Computing, Power and Communication Technologies (GUCON) (2020), pp. 440-445
[27] A. A. Heidari, P. Pahlavani, “An efficient modified grey wolf optimizer with Levy flight for optimization tasks”, Applied Soft Computing (2017), pp. 115-134
[28] ZL. ,Ou TC, “Dynamic economic dispatch solution using fast evolutionary programming with swarm direction” IEEE conference on Industrial Electronics and Applications (ICIEA) (2009), pp. 1538–1544 | ||
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آمار تعداد مشاهده مقاله: 22 تعداد دریافت فایل اصل مقاله: 115 |
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