Optimizing PV Sources and Shunt Capacitors for Energy Efficiency Improvement in Distribution Systems Using Subtraction-Average Algorithm

Smaili, Idris H.; Almalawi, Dhaifallah R.; Shaheen, Abdullah M.; Mansour, Hany S. E.

doi:10.3390/math12050625

Cited by 7 publications

(2 citation statements)

References 39 publications

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“…Studying PV systems is crucial due to their pivotal role as ideal companions for both renewable and traditional energy sources in hybrid energy systems. These systems are widely adopted globally because of their reliability and stability in energy production from individual sources; such systems include PV/Grid [20], PV energy forecasting [21], PV/STATCOM [22], PV/Voltage regulators [23], and microgrid management [24]. Additionally, a variety of maximum power point tracking (MPPT) methodologies have been developed to optimize the operation of solar PV arrays for maximum power output [25].…”

Section: Introductionmentioning

confidence: 99%

Modified Rime-Ice Growth Optimizer with Polynomial Differential Learning Operator for Single- and Double-Diode PV Parameter Estimation Problem

Hakmi,

Alnami,

Moustafa

et al. 2024

Electronics

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A recent optimization algorithm, the Rime Optimization Algorithm (RIME), was developed to efficiently utilize the physical phenomenon of rime-ice growth. It simulates the hard-rime and soft-rime processes, constructing the mechanisms of hard-rime puncture and soft-rime search. In this study, an enhanced version, termed Modified RIME (MRIME), is introduced, integrating a Polynomial Differential Learning Operator (PDLO). The incorporation of PDLO introduces non-linearities to the RIME algorithm, enhancing its adaptability, convergence speed, and global search capability compared to the conventional RIME approach. The proposed MRIME algorithm is designed to identify photovoltaic (PV) module characteristics by considering diverse equivalent circuits, including the One-Diode Model (ONE-DM) and Two-Diode Model TWO-DM, to determine the unspecified parameters of the PV. The MRIME approach is compared to the conventional RIME method using two commercial PV modules, namely the STM6-40/36 module and R.T.C. France cell. The simulation results are juxtaposed with those from contemporary algorithms based on published research. The outcomes related to recent algorithms are also compared with those of the MRIME algorithm in relation to various existing studies. The simulation results indicate that the MRIME algorithm demonstrates substantial improvement rates for the STM6-40/36 module and R.T.C. France cell, achieving 1.16% and 18.45% improvement for the ONE-DM, respectively. For the TWO-DM, it shows significant improvement rates for the two modules, reaching 1.14% and 50.42%, respectively. The MRIME algorithm, in comparison to previously published results, establishes substantial superiority and robustness.

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Section: Introductionmentioning

confidence: 99%

Modified Rime-Ice Growth Optimizer with Polynomial Differential Learning Operator for Single- and Double-Diode PV Parameter Estimation Problem

Hakmi,

Alnami,

Moustafa

et al. 2024

Electronics

Self Cite

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“…Moreover, particle swarm optimization has been developed for designing an optimum wind farm layout with active control of turbine yaws [19], and wind power intermittency was demonstrated in [20] via genetic algorithm optimization. Further successful applications in this field include optimizing energy conversion [21], refining operational scheduling, demand side management [22], renewable energies integration [23], and power system optimization [24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Enhanced Kepler Optimization Method for Nonlinear Multi-Dimensional Optimal Power Flow

Alqahtani,

Almutairi,

Shaheen

et al. 2024

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Multi-Dimensional Optimal Power Flow (MDOPF) is a fundamental task in power systems engineering aimed at optimizing the operation of electrical networks while considering various constraints such as power generation, transmission, and distribution. The mathematical model of MDOPF involves formulating it as a non-linear, non-convex optimization problem aimed at minimizing specific objective functions while adhering to equality and inequality constraints. The objective function typically includes terms representing the Fuel Cost (FC), Entire Network Losses (ENL), and Entire Emissions (EE), while the constraints encompass power balance equations, generator operating limits, and network constraints, such as line flow limits and voltage limits. This paper presents an innovative Improved Kepler Optimization Technique (IKOT) for solving MDOPF problems. The IKOT builds upon the traditional KOT and incorporates enhanced local escaping mechanisms to overcome local optima traps and improve convergence speed. The mathematical model of the IKOT algorithm involves defining a population of candidate solutions (individuals) represented as vectors in a high-dimensional search space. Each individual corresponds to a potential solution to the MDOPF problem, and the algorithm iteratively refines these solutions to converge towards the optimal solution. The key innovation of the IKOT lies in its enhanced local escaping mechanisms, which enable it to explore the search space more effectively and avoid premature convergence to suboptimal solutions. Experimental results on standard IEEE test systems demonstrate the effectiveness of the proposed IKOT in solving MDOPF problems. The proposed IKOT obtained the FC, EE, and ENL of USD 41,666.963/h, 1.039 Ton/h, and 9.087 MW, respectively, in comparison with the KOT, which achieved USD 41,677.349/h, 1.048 Ton/h, 11.277 MW, respectively. In comparison to the base scenario, the IKOT achieved a reduction percentage of 18.85%, 58.89%, and 64.13%, respectively, for the three scenarios. The IKOT consistently outperformed the original KOT and other state-of-the-art metaheuristic optimization algorithms in terms of solution quality, convergence speed, and robustness.

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A Review of Distributed Generation Optimization with Shunt Capacitors in Reconfigured Distribution Networks

Fadel

2024

Wireless Pers Commun

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Optimizing PV Sources and Shunt Capacitors for Energy Efficiency Improvement in Distribution Systems Using Subtraction-Average Algorithm

Cited by 7 publications

References 39 publications

Modified Rime-Ice Growth Optimizer with Polynomial Differential Learning Operator for Single- and Double-Diode PV Parameter Estimation Problem

Modified Rime-Ice Growth Optimizer with Polynomial Differential Learning Operator for Single- and Double-Diode PV Parameter Estimation Problem

Enhanced Kepler Optimization Method for Nonlinear Multi-Dimensional Optimal Power Flow

A Review of Distributed Generation Optimization with Shunt Capacitors in Reconfigured Distribution Networks

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