Trends in Electrical Engineering (TEE)

Distributed generation (DG) must be positioned and sized at optimal levels for electrical power system networks to operate competently, affordably, and reliably. "Electrical power system networks" must function properly for optimal distributed generation to take place. Ensuring the secure operation of power system networks primarily aims to reduce active power losses and improve the overall voltage profile. The optimal distribution of distributed generation using JAYA, RAO, and optimization algorithms has been compared in this study. This makes use of type-1 distributed generation (DG), and 2.9443 MW and 2.404 MW, respectively, are the optimal losses for the IEEE-9 bus system when using the JAYA programme and the RAO methodology. The overall losses in the IEEE- 14 bus system for JAYA and RAO Algorithm are likewise practically comparable at 3.4783 MW and 3.4775 MW, respectively. The JAYA and RAO algorithms are used to distribute DG in the most likely manner using MATLAB Toolbox and Mat-Power 6.0.

RV Rao, HS Keesari. A self-adaptive population Rao algorithm for optimization of selected bio energy systems. Journal of Computational Design and Engineering. 2021; 8 (1): 69–96.

RV Rao, RB Pawar, S Khatir, TC Le. Weight Optimization of a Truss Structure Using Rao Algorithms and Their Variants, Structural Health Monitoring and Engineering Structures. 3–18. Lecture Notes in Civil Engineering, vol 148. Springer, Singapore. https://doi.org/10.1007/978–981–16–0945–9_1

RV Rao, RB Pawar, Quasi-oppositional- based Rao algorithms for multi-objective design optimization of selected heat sinks. Journal of Computational Design and Engineering. 2020; 7(6): 830–863.

RV Rao, RB Pawar, Constrained design optimization of selected mechanical system components using Rao algorithms, Applied Soft Computing. 89, 2020, 106141.

Yiying Zhang, Aining Chi, Seyedali Mirjalili, Enhanced Jaya algorithm: A simple but efficient optimization method for constrained engineering design problems‖, Knowledge- Based Systems Volume 233, 5 December 2021, 107555.

Ali M. Eltamaly, and M. S. Al-Saud, Nested multi-objective PSO for optimal allocation and sizing of renewable energy distributed generation‖, Journal of Renewable and Sustainable Energy. 10(3) 035302 (2018); doi: 10.1063/1.5028484.

Apparao, K. Bhashna. Optimal Allocation of DG Considering Loss Minimization and Voltage Profile Using PSO. International Journal of Science and Research. Volume 4 Issue 9, September 2015. 659– 663.

Ankita Mishra, Arti Bhandakkar. Selection of Optimal Location and Size of Distributed Generation in Distribution System Using Particle Swarm Optimization, International Journal of Engineering Research & Technology (IJERT). January – 2014; Vol. 3 Issue 1. 2008–2013.

Satish Kumar Injeti, Vinod Kumar Thunuguntla. Optimal integration of DGs into radial distribution network in the presence of plug-in electric vehicles to minimize daily active power losses and to improve the voltage profile of the system using bioinspired optimization algorithms. Protection and Control of Modern Power Systems (2020). 5(3) 2020. https://doi.org/10.1186/s41601–019–0149–x.

Singh, K. S. Verma, Pooja Mishra. FACTS Controllers Power System (PS); Performance Parameters of Systems. International Journal of Automation and Power Engineering. December 2012; Volume: 1, Issue: 9, 193–234.

B.Singh, K.S. Verma, Deependra Singh, C.N. Singh. Introduction to FACTS Controllers a Critical Review. International Journal of Reviews in Computing, Vol.8, Dec. 2011.17–34.

Malihe M. Farsangi, Hossien Nezamabadi- Pour and Kwang Y. Lee, Multi-objective VAr Planning with SVC for a Large Power System Using PSO and GA. 2006 IEEE PES Power Systems Conference and Exposition. 29 October 2006 - 01 November 2006; Atlanta, GA, USA. US: IEEE Press; 2007.

Chia-Nan Ko, Ying-Pin Chang, and Chia-Ju Wu. A PSO Method With Nonlinear Time- Varying Evolution for Optimal Design of Harmonic Filters. IEEE Transactions on Power Systems (Volume: 24, Issue: 1, February 2009). 437 - 444.

S. Auchariyamet, S. Sirisumrannukul. Optimal Reactive Power Planning with Facts Devices by Particle Swarm Technique. 8th International Conference on Advances in Power System Control, Operation and Management (APSCOM 2009). 08-11 November 2009; Hong Kong, China. US: IEEE Press; 2010.

Hirotaka Yoshida, Kenichi Kawata, Yoshikazu Fukuyama, S. Takayama; Y. Nakanishi. A Particle Swarm Optimization for Reactive Power and Voltage Control Considering Voltage Security Assessment. Vol. 15, No. 4, Nov. 2006.

K Sundareswaran, Hariharan B, Fawas Palasseri Parasseri, Daniel Sanju Antony,and Binyamin Subair Optimal Placement of Static VAr Compensators (SVC’s) Using Particle Swarm Optimization. 2010 International Conference on Power, Control and Embedded Systems. 29 November 2010 - 01 December 2010; Allahabad, India. US: IEEE Press; 2011. IEEE 2010.

R. Benabid, M. Boudour. Optimal Placement of FACTS devices for Multiobjectiv Voltage Stability Problem. 2009 IEEE/PES Power Systems Conference and Exposition. 15–18 March 2009; Seattle, WA, USA. US: IEEE Press; 2009.

S. Sakthivel, R. Vetrivel Dr. D. Mary. Optimal Location of SVC for Voltage Stability Enhancement under Contingency Condition through PSO Algorithm. International Journal of Computer Applications. Volume 20– No.1, April 2011; 30–36.

Tridib K. Das, Sandhya R. Jetti, and Ganesh K. Venayagamoorthy. Optimal Design of SVC Damping Controllers with Wide Area Measurements Using Small Population based PSO The 2006 IEEE International Joint Conference on Neural Network Proceedings. 16–21 July 2006; Vancouver, BC, Canada. US: IEEE Press; 2006.

K. Dhananjaya Babu and M.Damodar Reddy Mehdi Eghbal, E.E.El–Araby2,Naoto Yorino1,Yoshifumi Zoka. Application of Metaheuristic Methods to Reactive Power Planning: A Comparative Study for GA, PSO and EPSO. 2007 IEEE International Conference on Systems, Man and Cybernetics. 07-10 October 2007; Montreal, QC, Canada. US: IEEE Press; 2008.

Mehdi Eghbal, Naoto Yorino and Yoshifumi Zoka. Comparative Study on the Application of Modern Heuristic Techniques to SVC Placement Problem. Journal of Computers. Volume 4: 6; June 2009.535–540.

Malihe M. Farsangi, Hossein Nezamabadi-pour, Kwang Y. Lee. Multi-objective VAr Planning with SVC Using Immune Algorithm and Guaranteed Convergence Particle Swarm Optimization. IFAC Proceedings Volumes. Volume 41, Issue 2, 2008, Pages 5599–5604

Malihe M. Farsangi, Hossein Nezamabadi– pour and Kwang Y. Lee, Implementation of GCPSO for Multi-objective VAr Planning with SVC and Its Comparison with GA and PSO. 2007 International Conference on Intelligent Systems Applications to Power Systems. 05–08 November 2007; Kaohsiung, Taiwan. US: IEEE Press; 2008.

S. Nagalakshmi, N. Kamaraj. Loadability enhancement for pool model with FACTS devices in transmission system using Differential Evolution and Particle Swarm Optimization. India International Conference on Power Electronics 2010 (IICPE2010). 28-30 January 2011; New Delhi, India. US: IEEE Press; 2011.

Vivek Kumar Jain, Himmat Singh, and Laxmi Srivastava, Minimization of Reactive Power Using Particle Swarm Optimization. IJCER, May-June 2012, Vol.2, Issue No.3, PP 686–691.

Alisha Banga and S.S. Kaushik. Modeling and Simulation of SVC Controller for Enhancement of Power System Stability. IJAET Journal. Volume 1, Issue: 3, 2020.

Hingorani, N G and Laszlo Gyugyi, "Understanding FACTS- Concepts and Technology of Flexible AC Transmission Systems. 1st ed. IEEE Preess, New York 2000.