Integrating genetic algorithms and tabu search for unit commitment problem

Sudhakaran, M.; Raj, P. Ajay-D-Vimal

doi:10.4314/ijest.v2i1.59085

Cited by 25 publications

(12 citation statements)

References 24 publications

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“…For numerical experimentation, a set of six instances of the UCP are considered from the literature, in which the numbers of units are 10, 20, 40, 60, 80 and 100 over a 24-h time horizon. The reason for considering these particular instances is that these are the most widely studied instances for illustrating the performances of different solution techniques proposed for the UCP [1][2][3][4][5]7,16,[19][20][21]26,29,31,32,36,[38][39][40][41][42]44,45]. The unit related known data for the 10-unit power system are given in Table 2 with notations as per Eqs.…”

Section: Numerical Experiments and Discussionmentioning

confidence: 99%

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A binary-real-coded differential evolution for unit commitment problem

Datta

Dutta²

2012

International Journal of Electrical Power & Energy Systems

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Section: Numerical Experiments and Discussionmentioning

confidence: 99%

“…Apart from these, some hybrid methods combining metaheuristics with deterministic methods or other metaheuristics are also investigated in order to reduce the search space in large-scale UCP. Such hybrid methods include LR and GA [5], LR and MA [42], LR and PSO [3], GA and SA [30], and GA and TS [36].…”

Section: Introductionmentioning

confidence: 99%

A binary-real-coded differential evolution for unit commitment problem

Datta

Dutta²

2012

International Journal of Electrical Power & Energy Systems

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“…The performance of HABFGA algorithm without considering the ramp rate constraint is compared with genetic algorithms and tabu search [40], Lagrangian relaxation and genetic algorithms [41], differential evolution [42], ant colony [43], shuffled frog-leaping algorithm [44] and binary real-coded genetic algorithm (BRGA) [3]. Table IV shows the results of this comparison that shows that the HABFGA algorithm yields enhanced results over other published methods.…”

Section: Case 1: Using Standard Test Systemsmentioning

confidence: 99%

Adaptive bacterial foraging and genetic algorithm for unit commitment problem with ramp rate constraint

Elattar

2015

Int. Trans. Electr. Energ. Syst.

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SUMMARYSolving unit commitment (UC) problem is one of the most critical tasks in electric power system operations. Therefore, proposing an accurate method to solve this problem is of great interest. The original bacterial foraging (BF) algorithm suffers from poor convergence characteristics for larger constrained optimization problems. In addition, the stopping criterion used in the original BF algorithm increases the computation burden of the original algorithm in many cases. To overcome these drawbacks, a hybridized adaptive BF and genetic algorithm (HABFGA) algorithm is proposed in this paper to solve the UC problem with ramp rate constraint. The HABFGA algorithm can be derived by combining adaptive stopping criterion, BF algorithm and genetic algorithm; therefore, the drawbacks of the original BF algorithm can be treated before employing it to solve the complex UC problem. To illustrate the effectiveness of the HABFGA algorithm, several standard and real test systems with different numbers of generating units are used. The results of HABFGA algorithm are compared with the results obtained using other published methods employing same test systems. This comparison shows the effectiveness and the superiority of the proposed method over other published methods.

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“…A genetic algorithm is an algorithm that simulates the evolution of living organisms in a manner to contribute to the enhancement of computerized systems (Sudhakaran & Raj, 2010). Therefore, genetic algorithms are considered to be "Bio-Inspired" applications (Stein et al, 2004).…”

Section: Genetic Algorithmsmentioning

confidence: 99%

Genetic Algorithm Solution of the Knapsack Problem Used in Finding Full Issues in the Holy Quran Based on the Number (19)

Najadat¹,

Kanaan²,

Kanaan³

et al. 2013

CIS

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The Holy Quran is the biggest Miracle of Muslims everywhere and at every time; therefore, it is valid for every time and place. Actually, researches and studies into the Holy Quran that aim to uncover new miracles within are considered as a kind of worship for Muslims researchers since it facilitates the Islamic mission and clarifies the vague picture of Islam throughout the world. From this perspective, the researchers have selected the vague miracle of the number 19 in the Holy Quran to examine through this study.In this study, the researchers describe a special algorithm that facilitates the retrieval process of the full-issues according to the conditions of number 19 miracle in the Holy Quran. This algorithm is derived from the genetic algorithm that is used to solve the knapsack problem, since it is so similar to the case of this study. However, in the results of this study many full-issues have appeared that insure the truth of the number 19 miracle in the Holy Quran and thus support the miracle of the whole Holy Quran.

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Integrating genetic algorithms and tabu search for unit commitment problem

Cited by 25 publications

References 24 publications

A binary-real-coded differential evolution for unit commitment problem

A binary-real-coded differential evolution for unit commitment problem

Adaptive bacterial foraging and genetic algorithm for unit commitment problem with ramp rate constraint

Genetic Algorithm Solution of the Knapsack Problem Used in Finding Full Issues in the Holy Quran Based on the Number (19)

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