Wind farm layout optimization by using Definite Point selection and genetic algorithm

Shakoor, Rabia; Hassan, Mohammad Yusri; Raheem, Abdur; Rasheed, Nadia; Nasir, Mohamad Na'im Mohd

doi:10.1109/pecon.2014.7062439

Cited by 20 publications

(11 citation statements)

References 11 publications

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“…On the other hand, Chowdhury et al opted for particle swarm optimization to resolve the non-linear optimization problem that affects the wind turbine layout and employs turbines of varying diameters [6]. Shakoor et al (2014) studied a combination of generic and definite point selection algorithms to approach the optimal wind turbine layout design problem [7]. Christopher Elkinton et al [8] focused on minimizing the production costs of the wind turbine farm and maximizing the power output by reducing wake effects.…”

Section: Literature Reviewmentioning

confidence: 99%

Wind Farm Layout: Modeling and Optimization Using Genetic Algorithm

Brahimi

El-Amin

2022

IOP Conf. Ser.: Earth Environ. Sci.

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Wind Farm Layout Optimization (WFLO) is a complex multidisciplinary topic that requires a lot of expertise and is becoming an essential part of today’s wind farm planning. Yet, selecting optimum wind farm locations is complex, time-consuming, and influenced by environmental factors and upstream turbines inflow wind. The present study attempts to develop an optimization approach based on the Genetic Approach (GA) to determine the most suitable wind turbine locations that maximize the net energy production while minimizing the Cost of Energy (COE) ($/kWh). The WFLO for the optimized objective function was performed for 500, 1000, and 1500 iterations. The best output was obtained for 1500 iterations with the lowest value for the objective function.

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Section: Literature Reviewmentioning

confidence: 99%

Wind Farm Layout: Modeling and Optimization Using Genetic Algorithm

Brahimi

El-Amin

2022

IOP Conf. Ser.: Earth Environ. Sci.

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“…Shakoor [14] Genetic algorithm The linear Jensen's wake model was employed with definite selection criteria.…”

Section: Year Optimizer Remarksmentioning

confidence: 99%

“…Many previous works have sought to identify the optimal distribution of WTs within a WF [8][9][10][11][12][13][14][15][16][17][18][19][20][21]. The summary of these related works is presented in Table 1.…”

Section: Introductionmentioning

confidence: 99%

The Application of Water Cycle Optimization Algorithm for Optimal Placement of Wind Turbines in Wind Farms

et al. 2019

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Wind farms (WFs) include an enormous number of wind turbines (WTs) in order to achieve high capacity. The interaction among WTs reduces the extracted amount of wind energy because wind speed decreases in the wake region. The optimal placement of WTs within a WF is therefore vital for achieving high performance. This permits as many WTs as possible to be installed inside a narrow region. In this work, the water cycle algorithm (WCA), a recently developed optimizer, was employed to identify the optimal distribution of WTs. Minimization of the total cost per kilowatt was the objective of the optimization process. Two different cases were considered: the first assumed constant wind speed with variable wind direction, while the second applied variable wind speed with variable wind direction. The results obtained through the WCA optimizer were compared with other algorithms, namely, salp swarm algorithm (SSA), satin bowerbird optimization (SBO), grey wolf optimizer (GWO), and differential evolution (DE), as well as other reported works. WCA gave the best solution compared to other reported and programmed algorithms, thus confirming the reliability and validity of WCA in optimally configuring turbines in a wind farm for both the studied cases.

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“…Rabia Shakoor, Mohammad Yusri Hassan, Abdur Raheem, Nadia Rasheed and Mohamad Na'im Mohd Nasir used Definite Point Selection (DPS) and Genetic Algorithm to optimally arrange wind turbines in a wind farm by minimizing the cost per unit power and minimizing the wake effects [14]. The cost per unit power was minimized by changing the dimensions of the wind farm while keeping the area of the wind farm constant by which the area is the same as the area used in [5,13].…”

Section: Optimization Algorithmsmentioning

confidence: 99%

“…The cost per unit power was minimized by changing the dimensions of the wind farm while keeping the area of the wind farm constant by which the area is the same as the area used in [5,13]. By comparing the results in [14] to the results in [8] and [13] that the power output of the wind farm increased by using the same area with different dimensions when the total number of wind turbines in a wind farm were the same.…”

Section: Optimization Algorithmsmentioning

confidence: 99%

Investigation into the Optimal Wind Turbine Layout Patterns for a Wind Farm in Walvis Bay, Namibia

Wanjekeche¹

2018

EPES

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Due to the unpredictable nature of wind speed and direction, there is a need to optimize the wind turbines placement to extract maximum available wind power at a low cost. Through optimization, best positions of the wind turbines that lead to maximum output are determined. This paper presents an into an optimal Wind Turbine (WT) layout pattern for three Wind Farm (WF) configurations (aligned, Genetic Algorithm (GA) and Particle Swarm Optimization (PSO). A Hypothetical WF (2km X 2km) is analyzed based on 2016 Wind data. Result shows that the total power generated from the customized is 863.098 kW, from Genetic Algorithm (GA) layout, the total power generated is 1296.286 kW while from Particle Swarm Optimization (PSO) the total power generated is 1300.668 kW. In comparison to the customized layout, optimization algorithms layouts resulted in a good improvement of the total power generated, GA improved the total power generated by 50.2% while PSO improved the total power generated by 50.7%. Optimization Algorithms layout proved to be efficient as compared to the customized layout because they have fewer power losses. GA and PSO layout have losses of 13.5% and 13.3% respectively, while the customized layout resulted in the most losses which are at 43%. The results from GA and PSO slightly differ, with a small difference in power of 4.4 kW.

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Wind farm layout optimization by using Definite Point selection and genetic algorithm

Cited by 20 publications

References 11 publications

Wind Farm Layout: Modeling and Optimization Using Genetic Algorithm

Wind Farm Layout: Modeling and Optimization Using Genetic Algorithm

The Application of Water Cycle Optimization Algorithm for Optimal Placement of Wind Turbines in Wind Farms

Investigation into the Optimal Wind Turbine Layout Patterns for a Wind Farm in Walvis Bay, Namibia

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