Distribution System Performance Improvement using Meta-heuristic Optimization Algorithms

Apon, Hasan Jamil; Morshed, Khandaker Adil; Abid, Md. Shadman

IUT Repository Home
→
Electrical and Electronics Engineering (EEE)
→
Thesis
→
Undergraduate
→
2022
→
View Item

dc.contributor.author	Apon, Hasan Jamil
dc.contributor.author	Morshed, Khandaker Adil
dc.contributor.author	Abid, Md. Shadman
dc.date.accessioned	2023-05-05T04:37:34Z
dc.date.available	2023-05-05T04:37:34Z
dc.date.issued	2022-05-30
dc.identifier.citation	[1] H. Bevrani, A. G. Tikdari, T. Hiyama., 2010. Power system load shedding: Key issues and new perspectives. World Academy of Science, Engineering and Technology; vol. 65, pp. 199-204, May 2010 [2] Larik, R., Mustafa, M. and Aman, M., 2019. A critical review of the state-of-art schemes for under voltage load shedding. International Transactions on Electrical Energy Systems, 29(5), p.e2828. [3] Hsu, C., Kang, M. and Chen, C., 2005. Design of adaptive load shedding by artificial neural networks. IEE Proceedings - Generation, Transmission and Distribution, 152(3), p.415. [4] J. Zhang, C. Lu, C. Fang, X. Ling and Y. Zhang, ”Load Shedding Scheme with Deep Reinforcement Learning to Improve Short-term Voltage Stability,” 2018 IEEE Innovative Smart Grid Technologies - Asia (ISGT Asia), 2018, pp. 13-18, doi: 10.1109/ISGT-Asia.2018.8467877. [5] Ma lkowski, R. and Niezna´nski, J., 2020. Underfrequency Load Shedding: An Innovative Algorithm Based on Fuzzy Logic. Energies, 13(6), p.1456. [6] J. Sasikala, M. Ramaswamy, Fuzzy based load shedding strategies for avoiding voltage collapse, Applied Soft Computing, Volume 11, Issue 3, 2011, Pages 3179-3185, ISSN 1568-4946, https://doi.org/10.1016/j.asoc.2010.12.020. [7] Olabambo Ifeoluwa Oluwasuji, Obaid Malik, Jie Zhang, and Sarvapali Dyanand Ramchurn. 2018. Algorithms for fair load shedding in developing countries. In Proceedings of the 27th International Joint Conference on Artificial Intelligence (IJCAI’18). AAAI Press, 1590–1596. [8] Alqunun, K., Guesmi, T. Farah, A. Load shedding optimization for economic operation cost in a microgrid. Electr Eng 102, 779–791 (2020). https://doi.org/10.1007/s00202-019-00909-3 [9] G. S. Grewal, J. W. Konowalec and M. M. Hakim, ”Optimization of load-shedding scheme in an integrated process plant,” in IEEE Transactions on Industry Applications, vol. 35, no. 4, pp. 959-967, July-Aug. 1999, doi: 10.1109/28.777206. [10] V. Tamilselvan, T. Jayabarathi, A hybrid method for optimal load shedding and improving voltage stability, Ain Shams Engineering Journal, Volume 7, Issue 1, 2016, Pages 223-232, ISSN 2090-4479, https://doi.org/10.1016/j.asej.2015.11.003. 64 [11] Malekpour, A. and Seifi, A., 2009. An Optimal Load Shedding Approach for Distribution Networks with DGs Considering Capacity Deficiency Modelling of Bulked Power Supply. Modern Applied Science, 3(5). [12] Ketabi, A. and Hajiakbari Fini, M., 2017. Adaptive underfrequency load shedding using particle swarm optimization algorithm. Journal of Applied Research and Technology, 15(1), pp.54-60. [13] Talaat, M., Hatata, A., Alsayyari, A. and Alblawi, A., 2020. A smart load management system based on the grasshopper optimization algorithm using the under-frequency load shedding approach. Energy, 190, p.116423. [14] Wan Afandie, W., 2016. Comparative Analysis of Bacterial Foraging Optimization Algorithm and Evolutionary Programming for Load Shedding in Power System. International Journal of Simulation: Systems, Science Technology,. [15] Arya, L., Singh, P. and Titare, L., 2012. Differential evolution applied for anticipatory load shedding with voltage stability considerations. International Journal of Electrical Power Energy Systems, 42(1), pp.644-652. [16] V. G. Calderaro, V.;Lattarrulo,V.;Siano,P.;, ”A new algorithm for steady state load-shedding strategy,” in 2010, 12th International Conference on Optimization of Electrical and Electronic Equipment (OPTIM) Basov, 2010, p. 48. [17] Usman, M., Amin, A., Azam, M.M., Mokhlis, H., 2018. Optimal under voltage load shedding scheme for a distribution network using EPSO algorithm, in: 2018 1st International Conference on Power, Energy and Smart Grid (ICPESG). Presented at the 2018 1st International Conference on Power, Energy and Smart Grid (ICPESG), IEEE. [18] Khamis, A., Shareef, H., Mohamed, A., amp; Dong, Z. Y. (2018). A load shedding scheme for DG integrated islanded power system utilizing backtracking search algorithm. Ain Shams Engineering Journal, 9(1), 161–172. https://doi.org/10.1016/j.asej.2015.10.001 [19] Civicioglu, P., 2013. Backtracking Search Optimization Algorithm for numerical optimization problems. Applied Mathematics and Computation, 219(15), pp.8121-8144. [20] Acharya, N., Mahat, P. and Mithulananthan, N., 2006. An analytical approach for DG allocation in primary distribution network. International Journal of Electrical Power Energy Systems, 28(10), pp.669-678. 65 [21] Walling, R., Saint, R., Dugan, R., Burke, J. and Kojovic, L., 2008. Summary of Distributed Resources Impact on Power Delivery Systems. IEEE Transactions on Power Delivery, 23(3), pp.1636-1644. [22] Xu, Y., Shi, Z., Wang, J. and Hou, P., 2013. Discussion on the Factors Affecting the Stability of Microgrid Based on Distributed Power Supply. Energy and Power Engineering, 05(04), pp.1344-1346. [23] H. Bevrani, A. G. Tikdari, T. Hiyama., 2010. Power system load shedding: Key issues and new perspectives. World Academy of Science, Engineering and Technology; vol. 65, pp. 199-204, May 2010 [24] Larik, R., Mustafa, M. and Aman, M., 2019. A critical review of the state-of-art schemes for under voltage load shedding. International Transactions on Electrical Energy Systems, 29(5), p.e2828. [25] P. S. Georgilakis and N. D. Hatziargyriou, ”Optimal Distributed Generation Placement in Power Distribution Networks: Models, Methods, and Future Research,” in IEEE Transactions on Power Systems, vol. 28, no. 3, pp. 3420-3428, Aug. 2013, doi: 10.1109/TPWRS.2012.2237043. [26] Kansal, Satish Kumar, Vishal. (2013). Optimal placement of different type of DG sources in distribution networks. International Journal of Electrical Power Energy Systems. 53. 752–760. 10.1016/j.ijepes.2013.05.040. [27] R. Sanjay, T. Jayabarathi, T. Raghunathan, V. Ramesh and N. Mithulananthan, ”Optimal Allocation of Distributed Generation Using Hybrid Grey Wolf Optimizer,” in IEEE Access, vol. 5, pp. 14807-14818, 2017, doi: 10.1109/ACCESS.2017.2726586. [28] Samala, R.K., Kotapuri, M.R. Optimal allocation of distributed generations using hybrid technique with fuzzy logic controller radial distribution system. SN Appl. Sci. 2, 191 (2020). https://doi.org/10.1007/s42452-020-1957-3 [29] Kumar, S., Mandal, K. and Chakraborty, N., 2019. Optimal DG placement by multi-objective opposition based chaotic differential evolution for techno-economic analysis. Applied Soft Computing, 78, pp.70-83. [30] Elattar, E. and Elsayed, S., 2020. Optimal Location and Sizing of Distributed Generators Based on Renewable Energy Sources Using Modified Moth Flame Optimization Technique. IEEE Access, 8, pp.109625-109638. 66 [31] Vita, V., 2017. Development of a Decision-Making Algorithm for the Optimum Size and Placement of Distributed Generation Units in Distribution Networks. Energies, 10(9), p.1433. [32] Rani, B. and Reddy, A., 2019. Optimal Allocation and Sizing of Multiple DG in Radial Distribution System Using Binary Particle Swarm Optimization. International Journal of Intelligent Engineering and Systems, 12(1), pp.290-299. [33] Memarzadeh G, Keynia F. A new index-based method for optimal DG placement in distribution networks. Engineering Reports. 2020;e12243. https://doi.org/10.1002/eng2.12243 [34] M.C.V. Suresh, J. Belwin Edward,A hybrid algorithm based optimal placement of DG units for loss reduction in the distribution system, Applied Soft Computing,Volume 91,2020,106191,ISSN 1568-4946, https://doi.org/10.1016/j.asoc.2020.106191. [35] Hassan, A., Sun, Y. and Wang, Z., 2020. Multi-objective for optimal placement and sizing DG units in reducing loss of power and enhancing voltage profile using BPSO-SLFA. Energy Reports, 6, pp.1581-1589. [36] A. Selim, S. Kamel, A. S. Alghamdi and F. Jurado, ”Optimal Placement of DGs in Distribution System Using an Improved Harris Hawks Optimizer Based on Singleand Multi-Objective Approaches,” in IEEE Access, vol. 8, pp. 52815-52829, 2020, doi: 10.1109/ACCESS.2020.2980245. [37] Talaat, M., Hatata, A., Alsayyari, A. and Alblawi, A., 2020. A smart load management system based on the grasshopper optimization algorithm using the under-frequency load shedding approach. Energy, 190, p.116423. [38] Khamis, A., Shareef, H., Mohamed, A., amp; Dong, Z. Y. (2018). A load shedding scheme for DG integrated islanded power system utilizing backtracking search algorithm. Ain Shams Engineering Journal, 9(1), 161–172. https://doi.org/10.1016/j.asej.2015.10.001 [39] Arya, L., Singh, P. and Titare, L., 2012. Differential evolution applied for anticipatory load shedding with voltage stability considerations. International Journal of Electrical Power Energy Systems, 42(1), pp.644-652. [40] Wan Afandie, W., 2016. Comparative Analysis of Bacterial Foraging Optimization Algorithm and Evolutionary Programming for Load Shedding in Power System. International Journal of Simulation: Systems, Science Technology,. 67 [41] V. G. Calderaro, V.;Lattarrulo,V.;Siano,P.;, ”A new algorithm for steady state load-shedding strategy,” in 2010, 12th International Conference on Optimization of Electrical and Electronic Equipment (OPTIM) Basov, 2010, p. 48. [42] Usman, M., Amin, A., Azam, M.M., Mokhlis, H., 2018. Optimal under voltage load shedding scheme for a distribution network using EPSO algorithm, in: 2018 1st International Conference on Power, Energy and Smart Grid (ICPESG). Presented at the 2018 1st International Conference on Power, Energy and Smart Grid (ICPESG), IEEE. [43] Mohanty, B. and Tripathy, S., 2016. A teaching learning based optimization technique for optimal location and size of DG in distribution network. Journal of Electrical Systems and Information Technology, 3(1), pp.33-44. [44] Khamis, A., Shareef, H. and Mohamed, A., 2015. Islanding detection and load shedding scheme for radial distribution systems integrated with dispersed generations. IET Generation, Transmission Distribution, 9(15), pp.2261-2275. [45] VK Mehta & Rohit Mehta (2005). Principles of Power System: Including Generation, Transmission, Distribution, Switchgear and Protection: for BE/B. Tech., AMIE and Other Engineering Examinations. S. Chand Publishing. [46] Lopes, Jo˜ao Abel Pe¸cas et al. “Integrating distributed generation into electric power systems: A review of drivers, challenges and opportunities.” Electric Power Systems Research, 77 (2007): 1189-1203. [47] Omar Ellabban, Haitham Abu-Rub and Frede Blaabjerg. ”Renewable Energy Resources: Current status, future prospects and their enabling technology.” Renewable and Sustainable Energy Reviews, 39 (2014), 748–764. [48] Stefan Weitemeyer, David Kleinhans et al. ”Integration of renewable energy sources in future power systems: The role of Storage.” Renewable Energy, 75 (2015), 14–20. [49] M. Liserre, T. Sauter and J. Y. Hung. ”Future Energy Systems: Integrating Renewable Energy Sources into the Smart Power Grid Through Industrial Electronics”, in IEEE Industrial Electronics Magazine, vol. 4, no. 1, pp. 18-37, March 2010. [50] Falkoni, Anamarija Krajacic, Goran Puksec, Tomislav Duic, Neven (2015). The integration of renewable energy sources and electric vehicles into the power system of the Dubrovnik region. Energy, Sustainability and Society, 5(1). 68 [51] Dudiak, Jozef and Michal Kolcun. “Integration of renewable energy sources to the power system.” 2014 14th International Conference on Environment and Electrical Engineering (2014): 148-151. [52] Paliwal, Priyanka Patidar, N.P. & Nema, R.K., 2014. ”Planning of grid integrated distributed generators: A review of technology, objectives and techniques,” Renewable and Sustainable Energy Reviews, Elsevier, vol. 40(C), pages 557-570. [53] Ndamulelo Mararakanye, Bernard Bekker (2019). ”Renewable energy integration impacts within the context of generator type, penetration level and grid characteristics.” Renewable and Sustainable Energy Reviews, 108, 441–451. [54] Grant Allan, Igor Eromenko, Michelle Gilmartin, Ivana Kockar, Peter McGregor (2015). ”The economics of Distributed Energy Generation: A Literature Review.” Renewable and Sustainable Energy Reviews, 42, 543–556. [55] Mudathir Funsho Akorede, Hashim Hizam, Edris Pouresmaeil (2010). ”Distributed Energy Resources and benefits to the environment.” Renewable and Sustainable Energy Reviews, 14(2), 724–734. [56] Zubo, R. H. A., Mokryani, G., Rajamani, H.-S., Aghaei, J., Niknam, T., amp; Pillai, P. (2017). ”Operation and planning of distribution networks with integration of renewable distributed generators considering uncertainties: A Review.” Renewable and Sustainable Energy Reviews, 72, 1177–1198. [57] Esmaeili, S.; Anvari-Moghaddam, A.; Jadid, S. Optimal Operational Scheduling of Reconfigurable Multi-Microgrids Considering Energy Storage Systems. Energies 2019, 12, 1766. [58] Najafi, J., Peiravi, A., Anvari-Moghaddam, A., Guerrero, J. M. (2019). ”Resilience Improvement Planning of power-water distribution systems with multiple microgrids against hurricanes using clean strategies.” Journal of Cleaner Production, 223, 109–126. [59] Hassan, A. S., Othman, E. S. A., Bendary, F. M., amp; Ebrahim, M. A. (2020). ”Optimal integration of distributed generation resources in active distribution networks for techno-economic benefits.” Energy Reports, 6, 3462–3471. [60] Jordehi, A. R. (2018). ”How to deal with uncertainties in Electric Power Systems? A Review.” Renewable and Sustainable Energy Reviews, 96, 145–155. 69 [61] Soroudi, A., Aien, M., amp; Ehsan, M. (2012).” A probabilistic modeling of photo voltaic modules and wind power generation impact on distribution networks.” IEEE Systems Journal, 6(2), 254–259. [62] Maleki, A., Khajeh, M. G., Ameri, M. (2016). ”Optimal sizing of a grid independent hybrid renewable energy system incorporating resource uncertainty, and load uncertainty.” International Journal of Electrical Power and Energy Systems, 83, 514–524. [63] Elkadeem, M. R., Abd Elaziz, M., Ullah, Z., Wang, S., Sharshir, S. W. (2019). ”Optimal planning of renewable energy-integrated distribution system considering uncertainties.” IEEE Access, 7, 164887–164907. [64] Radosavljevic, J., Arsic, N., Milovanovic, M., amp; Ktena, A. (2020). ”Optimal placement and sizing of renewable distributed generation using hybrid metaheuristic algorithm.” Journal of Modern Power Systems and Clean Energy, 8(3), 499–510. [65] Ali, E. S., Abd Elazim, S. M., amp; Abdelaziz, A. Y. (2016). ”Optimal allocation and sizing of renewable distributed generation using Ant Lion Optimization algorithm.” Electrical Engineering, 100(1), 99–109. [66] El-Fergany, A. (2015). ”Optimal allocation of multi-type distributed generators using backtracking search optimization algorithm.” International Journal of Electrical Power and Energy Systems, 64, 1197–1205. [67] Abu-Mouti, F. S., amp; El-Hawary, M. E. (2009). ”Modified artificial bee colony algorithm for optimal distributed generation sizing and allocation in distribution systems.” 2009 IEEE Electrical Power and Energy Conference (EPEC). [68] Sanjay, R., Jayabarathi, T., Raghunathan, T., Ramesh, V., Mithulananthan, N. (2017). ”Optimal allocation of distributed generation using Hybrid Grey Wolf optimizer.” IEEE Access, 5, 14807–14818. [69] Mohamed Imran A, amp; Kowsalya M. (2014). ”Optimal size and siting of multiple distributed generators in distribution system using bacterial foraging optimization.” Swarm and Evolutionary Computation, 15, 58–65. [70] Rama Prabha, D., Jayabarathi, T., Umamageswari, R., Saranya, S. (2015). ”Optimal allocation and sizing of distributed generation unit using Intelligent Water Drop algorithm.” Sustainable Energy Technologies and Assessments, 11, 106–113. 70 [71] ChithraDevi, S. A., Lakshminarasimman, L., amp; Balamurugan, R. (2017). ”Stud krill herd algorithm for multiple DG placement and sizing in a radial distribution system.” Engineering Science and Technology, an International Journal, 20(2), 748–759. [72] Moradi, M. H., amp; Abedini, M. (2012). ”A combination of genetic algorithm and particle swarm optimization for optimal distributed generation location and sizing in distribution systems with fuzzy optimal theory.” International Journal of Green Energy, 9(7), 641–660. [73] Kaur, S., Kumbhar, G., Sharma, J. (2014). ”A MINLP technique for optimal placement of multiple DG units in Distribution Systems.” International Journal of Electrical Power and Energy Systems, 63, 609–617. [74] Kumar, S., Mandal, K. K., Chakraborty, N. (2019). ”Optimal DG placement by multi-objective opposition based chaotic differential evolution for techno-economic analysis.” Applied Soft Computing, 78, 70–83. [75] Khatod, D. K., Pant, V., Sharma, J. (2013). ”Evolutionary programming based optimal placement of renewable distributed generators.” IEEE Transactions on Power Systems, 28(2), 683–695. [76] Abdelaziz, A. Y., Hegazy, Y. G., El-Khattam, W., Othman, M. M. (2015). ”Optimal allocation of stochastically dependent renewable energy based distributed generators in unbalanced distribution networks.” Electric Power Systems Research, 119, 34–44. [77] Kayal, P., Chanda, C. K. (2015). ”Optimal mix of solar and wind distributed generations considering performance improvement of Electrical Distribution Network.” Renewable Energy, 75, 173–186. [78] Ali, Abdelfatah Mahmoud, Karar Lehtonen, Matti. (2021). ”Optimal planning of inverter-based renewable energy sources towards autonomous microgrids accommodating electric vehicle charging stations.” IET Generation, Transmission and Distribution. 16. [79] A. Ali, K. Mahmoud and M. Lehtonen. ”Optimization of Photovoltaic and Wind Generation Systems for Autonomous Microgrids With PEV-Parking Lots.” IEEE Systems Journal. [80] Biswal, S. R., Shankar, G., Elavarasan, R. M., Mihet-Popa, L. (2021). ”Optimal allocation/sizing of dgs/capacitors in reconfigured radial distribution system using quasi-reflected slime mould algorithm.” IEEE Access, 9, 125658–125677. [81] Zellagui, M., Belbachir, N., Ziad El-Bayeh, C. (2021). ”Optimal allocation of RDG in distribution system considering the seasonal uncertainties of load demand and solar-wind 71 generation systems.” IEEE EUROCON 2021 - 19th International Conference on Smart Technologies. [82] Lekvan, A. A., Habibifar, R., Moradi, M., Khoshjahan, M., Nojavan, S., & Jermsittiparsert, K. (2021). ”Robust optimization of renewable-based multi-energy micro-grid integrated with flexible energy conversion and storage devices.” Sustainable Cities and Society, 64, 102532. [83] Galvani, S., Bagheri, A., Farhadi-Kangarlu, M., & Nikdel, N. (2022). ”A multi-objective probabilistic approach for smart voltage control in wind-energy integrated networks considering correlated parameters.” Sustainable Cities and Society, 78, 103651. [84] Geng, J., Zheng, T., Cao, J., Yang, Y., Jin, Y., Fu, J. (2022). ”Research on multi-objective Operation Optimization of Multi Energy Integrated Service stations based on Autonomous Collaborative Control.” Energy Reports, 8, 278–284. [85] Dinakara P et al (2018).” Optimal renewable resources placement in distribution networks by Combined Power Loss Index and whale optimization algorithms.” Journal of Electrical Systems and Information Technology, 5(2), 175–191. [86] Tolba, M., Rezk, H., Tulsky, V., Diab, A., Abdelaziz, A., Vanin, A. (2018). ”Impact of optimum allocation of renewable distributed generations on distribution networks based on different optimization algorithms.” Energies, 11(1), 245. [87] Nawaz, S., Bansal, D. A. K., Sharma, D. M. (2017). ”A novel approach for multiple DG allocation in real distribution system.” International Journal of Engineering and Technology, 9(2), 963–968. [88] El-Fergany, A. (2015). ”Multi-objective allocation of multi-type distributed generators along distribution networks using backtracking search algorithm and Fuzzy Expert Rules.” Electric Power Components and Systems, 44(3), 252–267. [89] Biswas, P. P., Suganthan, P. N., Mallipeddi, R., Amaratunga, G. A. J. (2019). ”Optimal reactive power dispatch with uncertainties in load demand and renewable energy sources adopting scenario-based approach.” Applied Soft Computing, 75, 616–632. [90] Li, S., Chen, H., Wang, M., Heidari, A. and Mirjalili, S., 2020. Slime mould algorithm: A new method for stochastic optimization. Future Generation Computer Systems, 111, pp.300-323. [91] A. Faramarzi, M. Heidarinejad, B. Stephens et al., Equilibrium optimizer:A novel optimization algorithm, Knowledge-Based Systems (2019), doi:https://doi.org/10.1016/j.knosys.2019.105190 72 [92] Zhao, W., Wang, L., amp; Mirjalili, S. (2022). ”Artificial Hummingbird Algorithm: A new bio-inspired optimizer with its engineering applications.” Computer Methods in Applied Mechanics and Engineering, 388, 114194. [93] M. H. Hauqe, ”A linear static voltage stability margin for radial distribution systems,” 2006 IEEE Power Engineering Society General Meeting, 2006, pp. 6 pp.-, doi: 10.1109/PES.2006.1708954. [94] Open data sets. ”IEEE PES Intelligent Systems Subcommittee”. Available: https://site. ieee.org/pes-iss/data-sets/ (accessed Feb. 3, 2022). [95] Power Systems Test Case Archive. ”Reliability test system”. Available :http://labs.ece. uw.edu/pstca/rts/pg_tcarts.htm (accessed Feb. 3, 2022).	en_US
dc.identifier.uri	http://hdl.handle.net/123456789/1879
dc.description	Supervised by Prof. Dr. Ashik Ahmed, Department of Electrical and Electronic Engineering (EEE), Islamic University of Technology (IUT), Board Bazar, Gazipur-1704, Bangladesh. This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Electrical and Electronic Engineering, 2022.	en_US
dc.description.abstract	The critical challenge for an efficient islanding operation of a distribution system having Distributed Generation (DG) is preserving the frequency and voltage stability. Contemporary load shedding schemes are inefficient and do not adequately assess the optimum amount of load to shed which results in either excessive or inadequate load shedding. Appropriate installation of renewable energy-based distributed generation units (RDGs) is one of the most important challenges and current topics of interest in the optimal functioning of modern power networks. Due to the intermittent nature of renewable energy sources, optimal allocation and sizing of RDGs, particularly photovoltaic (PV) and wind turbine (WT), remains a critical task. Additionally, maintaining frequency and voltage stability is crucial for optimal functioning of an islanded network connected to DGs. Conventional load shedding schemes do not effectively identify the optimal amount of load to shed, culminating in either excessive or insufficient load shedding. Hence, the first part of this work presents an optimal load shedding technique using Chaotic Slime Mould Algorithm (CSMA) with sinusoidal map in order to achieve greater efficiency. A constrained function with static voltage stability margin (VSM) index and total remaining load after load shedding was applied to accomplish the evaluation. A total of three islanding scenarios of IEEE 33 bus and IEEE 69 bus radial distribution systems were used as test systems to assess the efficacy of the proposed load shedding approach using MATLAB software. To identify performance enhancements, the developed method was compared to Backtrack Search Algorithm (BSA) and the original SMA. According to the results, CSMA outperforms both BSA and SMA in terms of remaining load and voltage stability margin index values in all the test systems. Moreover, the second part of this work proposes Chaotic Equilibrium Optimizer (CEO) with iterative map to achieve an optimal solution for multiple DG sizing and placement in distribution networks, as well as an optimal load shedding approach. Regarding DG placement, the objective function was to minimize total active power loss and voltage deviation of the network nodes. The proposed method was compared with Modified moth flame optimization (MMFO), Teaching learning based optimization (TLBO) and the original Equilibrium optimizer (EO). Moreover, to assess the optimal load shedding technique, a constrained function with total remaining load and static voltage stability margin (VSM) index was used. In addition, the proposed CEO algorithm is compared with some of the recent metaheuristics algorithms applied in this domain such as Grasshopper optimization algorithm (GOA), Backtrack search algorithm (BSA) and the original Equilibrium optimizer (EO). In the last part of the work, based on a new metaheuristic known as the Artificial hummingbird algorithm (AHA), this work provides a novel approach for addressing the problem of RDG planning optimization. Considering various operational constraints, the optimization problem is developed with multiple objectives including power loss reduction, voltage stability margin (VSM) enhancement, voltage deviation minimization, and yearly economic savings. Furthermore, using relevant probability distribution functions, the ambiguities related with the stochastic nature of PV and WT output powers are evaluated. The proposed algorithm was compared to two of the recent metaheuristics applied in this domain known as improved harris hawks and particle swarm optimization algorithm (HHO-PSO) and hybrid of phasor particle swarm and gravitational search algorithm (PPSOGSA). The IEEE 33-bus and 69-bus systems are assessed as the test systems in this study. According to the findings, AHA delivers superior solutions and enhances the techno-economic benefits of distribution systems in all the scenarios evaluated.	en_US
dc.language.iso	en	en_US
dc.publisher	Department of Electrical and Electronic Engineering, Islamic University of Technology (IUT) The Organization of Islamic Cooperation (OIC) Board Bazar, Gazipur-1704, Bangladesh	en_US
dc.subject	Slime mould algorithm, Steady state load shedding; Optimization; Voltage stability; Chaotic slime mould algorithm; VSM, Distributed generation, Optimal DG placement, Equilibrium optimizer, Iterative map, Artificial hummingbird algorithm, Renewable energy, Wind turbine, Photovoltaic generation.	en_US
dc.title	Distribution System Performance Improvement using Meta-heuristic Optimization Algorithms	en_US
dc.type	Thesis	en_US