Hybrid sensitivity-driven enhanced modified ant lion optimizer framework for multi- distributed generation allocation in radial distribution networks

Citation

P, Rajakumar and PM, Balasubramaniam and V, Ravi and Yumurtacı, Mehmet and Gulbarga, Mohammad Imtiyaz and Alam, Mohammad Mukhtar and Wee, Kuok Kwee and Keçebaş, Ali (2026) Hybrid sensitivity-driven enhanced modified ant lion optimizer framework for multi- distributed generation allocation in radial distribution networks. Energy Reports, 15. p. 109144. ISSN 2352-4847

[img] Text
main 2.pdf - Published Version
Restricted to Repository staff only

Download (3MB)

Abstract

Optimal siting and sizing of distributed generation (DG) units in radial power distribution networks (RPDNs) remain a critical challenge due to their nonlinear, multi-objective nature. Existing optimization approaches often struggle with computational inefficiencies, premature convergence, and limited adaptability across varying network scales. Addressing these limitations, this study proposes a novel hybrid framework that integrates Active Power Loss Sensitivity (APLS) and Voltage Sensitivity Index (VSI)-based bus preselection with an Enhanced Modified Ant Lion Optimizer (EMALO) for efficient multi-DG allocation. The proposed method leverages chaosbased initialization, L´evy-flight global search, and an elitist memory pool to enhance convergence reliability and solution diversity. A multi-objective fitness function is employed to minimize real power loss (RPL) and improve voltage profiles (VP), evaluated through Pareto-optimal approach. The methodology is rigorously tested on IEEE 69-bus and 118-bus systems and the practical Cairo-59-bus network using real-time load and PV generation profiles. Results reveal that EMALO achieves up to 69.12% and 96.52% RPL reductions for PV and WT scenarios respectively on the 69-bus system, surpassing conventional ALO, ABC, and BAT algorithms in both technical and computational performance. In the Cairo-59 case, EMALO reduced losses by 87%, demonstrating its practical viability. By addressing key research gaps in adaptive bus selection and robust multi-objective optimization, this study contributes a scalable, performance-driven solution for enhancing grid reliability and energy efficiency in modern RPDNs.

Item Type: Article
Uncontrolled Keywords: Radial distribution networks
Subjects: Q Science > QC Physics > QC501-766 Electricity and magnetism
Divisions: Faculty of Information Science and Technology (FIST)
Depositing User: Ms Rosnani Abd Wahab
Date Deposited: 02 Apr 2026 06:20
Last Modified: 06 Apr 2026 06:01
URII: http://shdl.mmu.edu.my/id/eprint/15660

Downloads

Downloads per month over past year

View ItemEdit (login required)