A non-revisiting artificial bee colony algorithm for phased array synthesis

Zhang, Xin

doi:10.1186/s13638-016-0802-2

Cited by 3 publications

(4 citation statements)

References 36 publications

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“…In equation (13) s and u k i;j are two different random numbers uniformly distributed on (0,1), i.e. s; k$Uð0;1Þ.…”

Section: The Random Drift Particle Swarm Optimizationmentioning

confidence: 99%

“…Most importantly, when the same optimal value reappears again in the search history, it can warn that the search may fall into local optimum. Non-revisiting strategy is integrated with intelligent algorithms12–18 to avoid the re-evaluation of the evaluated solution candidates by using binary space partitioning (BSP). The non-revisiting genetic algorithm (NrGA) is proposed to prevent solution re-evaluation14,15 in the genetic algorithm by using search history and cNrGA16 is another version designed for continuous variables.…”

Section: Introductionmentioning

confidence: 99%

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An improved dynamic cooperative random drift particle swarm optimization algorithm based on search history decision

Zhao

Martino

2020

Journal of Algorithms & Computational Technology

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A novel dynamic cooperative random drift particle swarm optimization algorithm based on entire search history decision (CRDPSO) is reported. At each iteration, the positions and the fitness values of the evaluated solutions in the algorithm are stored by a binary space partitioning tree structure archive, which leads to a fast fitness function approximation. The mutation is adaptive and parameter-less because of the fitness function approximation enhancing the mutation strategy. The dynamic cooperation between the particles by using the context vector increases the population diversity helps to improve the search ability of the swarm and cooperatively searches for the global optimum. The performance of CRDPSO is tested on standard benchmark problems including multimodal and unimodal functions. The empirical results show that CRDPSO outperforms other well-known stochastic optimization methods.

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“…In equation (13) s and u k i;j are two different random numbers uniformly distributed on (0,1), i.e. s; k$Uð0;1Þ.…”

Section: The Random Drift Particle Swarm Optimizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An improved dynamic cooperative random drift particle swarm optimization algorithm based on search history decision

Zhao

Martino

2020

Journal of Algorithms & Computational Technology

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“…Stochastic algorithms are popularly used because traditional optimization methods are not suitable due to the unavailable of gradient information [11][12][13]. Stochastic algorithms also show good performance for such design problems [14,15].…”

Section: Introductionmentioning

confidence: 99%

“…Although EAs and SI are created based on different nature, their positive combinations are able to result effective algorithms [22]. In the past, GA, PSO, and ABC have been used in antenna designs [15,23,24]. Recently, covariance matrix adaptation evolutionary strategy [25] and differential evolution [26] are applied to synthesize antenna array patterns.…”

Section: Introductionmentioning

confidence: 99%

Thinning of antenna array via adaptive memetic particle swarm optimization

Zhang

2017

J Wireless Com Network

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Massive multiple input multiple output antenna array is crucial for the fifth generation wireless communication.Proper antenna array design can reduce interference among different signals and generate desirable beamforming. Sparse antenna array is able to form narrower beam with lower sidelobe than equally spaced antenna array given the same number of array elements. However, determining the position of elements is non-deterministic polynomial-time hard. To effectively solve such problem, this paper proposes adaptive memetic particle swarm optimization (AMPSO) algorithm. The algorithm adaptively tunes algorithmic parameters of particle swarm optimization (PSO). Moreover, crossover operator is added to enhance local exploiting search information of PSO. Sparse antenna array design is modeled as a minimization by thinning method. It is then tackled by the proposed algorithm. In terms of peak sidelobe level, the AMPSO algorithm shows good performance compared with PSO and genetic algorithm.

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