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Xiong, G., L. Li, A. W. Mohamed, X. Yuan, and J. Zhang, "A new method for parameter extraction of solar photovoltaic models using gaining–sharing​ knowledge based algorithm", Energy Reports, vol. 7: Elsevier, pp. 3286-3301, 2021. Abstract
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Xiong, G., L. Li, A. W. Mohamed, X. Yuan, and J. Zhang, "A new method for parameter extraction of solar photovoltaic models using gaining–sharing​ knowledge based algorithm", Energy Reports, vol. 7: Elsevier, pp. 3286-3301, 2021. Abstract
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Xiong, G., L. Li, A. W. Mohamed, X. Yuan, and J. Zhang, A new method for parameter extraction of solar photovoltaic models using gaining–sharing knowledge based algorithm, , vol. 7, pp. 3286 - 3301, 2021. AbstractWebsite

For the solar photovoltaic (PV) system to operate efficiently, it is necessary to effectively establish an equivalent model of PV cell and extract the relevant unknown model parameters accurately. This paper introduces a new metaheuristic algorithm, i.e., gaining-sharing knowledge based algorithm (GSK) to solve the solar PV model parameter extraction problem. This algorithm simulates the process of knowledge acquisition and sharing in the human life cycle and is with strong competitiveness in solving optimization problems. It includes two significant phases. The first phase is the beginner–intermediate or junior acquisition and sharing stage, and the second phase is the intermediate–expert or senior acquisition and sharing stage. In order to verify the effectiveness of GSK, it is applied to five PV models including the single diode model, double diode model, and three PV modules. The influence of population size on the algorithm performance is empirically investigated. Besides, it is further compared with some other excellent metaheuristic algorithms including basic algorithms and advanced algorithms. Among the five PV models, the root mean square error values between the measured data and the calculated data of GSK are 9.8602E−04 ± 2.18E−17, 9.8280E−04 ± 8.72E−07, 2.4251E−03 ± 1.04E−09, 1.7298E−03 ± 6.25E−18, and 1.6601E−02 ± 1.44E−16, respectively. The results show that GSK has overall better robustness, convergence, and accuracy.

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Sukheja, D., J. A. Shah, G. Madhu, S. K. Kautish, F. A. Alghamdi, I. S. Yahia, E. - S. M. El-kenawy, and A. W. Mohamed, "New decision-making technique based on hurwicz criteria for fuzzy ranking", Computers, Materials and Continua, pp. 4595-4609, 2022. Abstract
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Sharma, C., S. Sharma, S. Kautish, S. A. M. Alsallami, E. M. Khalil, and A. W. Mohamed, "A new median-average round Robin scheduling algorithm: An optimal approach for reducing turnaround and waiting time", Alexandria Engineering Journal, vol. 61, issue 12: Elsevier, pp. 10527-10538, 2022. Abstract
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Sallam, K. M., and A. W. Mohamed, "Neutrosophic MCDM methodology for evaluation onshore wind for electricity generation and sustainability ecological", Neutrosophic Systems with Applications, vol. 4, pp. 53-61, 2023. Abstract
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Nomer, H. A. A., K. A. Alnowibet, A. Elsayed, and A. W. Mohamed, "Neural Knapsack: A Neural Network Based Solver for the Knapsack Problem", IEEE Access, vol. 8, pp. 224200 - 224210, 2020. Abstract
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Nomer, H. A. A., K. A. Alnowibet, A. Elsayed, and A. W. Mohamed, "Neural knapsack: a neural network based solver for the knapsack problem", IEEE access, vol. 8: IEEE, pp. 224200-224210, 2020. Abstract
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Nabeeh, N. A., M. Mohamed, A. Abdel-Monem, M. Abdel-Basset, K. M. Sallam, M. El-Abd, and A. Wagdy, "A Neutrosophic Evaluation Model for Blockchain Technology in Supply Chain Management", 2022 IEEE International Conference on Fuzzy Systems (FUZZ-IEEE): IEEE, pp. 1-8, 2022. Abstract
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Mohamed, A. W., "A novel differential evolution algorithm for solving constrained engineering optimization problems", Journal of Intelligent Manufacturing, vol. 29: Springer US, pp. 659-692, 2018. Abstract
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Mohamed, A. W., A novel differential evolution algorithm for solving constrained engineering optimization problems, , vol. 29, issue 3, pp. 659 - 692, 2018. AbstractWebsite

This paper introduces a novel differential evolution (DE) algorithm for solving constrained engineering optimization problems called (NDE). The key idea of the proposed NDE is the use of new triangular mutation rule. It is based on the convex combination vector of the triplet defined by the three randomly chosen vectors and the difference vectors between the best, better and the worst individuals among the three randomly selected vectors. The main purpose of the new approach to triangular mutation operator is the search for better balance between the global exploration ability and the local exploitation tendency as well as enhancing the convergence rate of the algorithm through the optimization process. In order to evaluate and analyze the performance of NDE, numerical experiments on three sets of test problems with different features, including a comparison with thirty state-of-the-art evolutionary algorithms, are executed where 24 well-known benchmark test functions presented in CEC’2006, five widely used constrained engineering design problems and five constrained mechanical design problems from the literature are utilized. The results show that the proposed algorithm is competitive with, and in some cases superior to, the compared ones in terms of the quality, efficiency and robustness of the obtained final solutions.

Mohamed, A. W., "A Novel Discrete Binary Differential Evolution Algorithm", Aloy Journal of Soft Computing and Applications, vol. 2, no. 1: Aloy Publisher, 2014. Abstract
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Mohamed, A. W., "A novel differential evolution algorithm for solving constrained engineering optimization problems", Journal of Intelligent Manufacturing, vol. 29: Springer US, pp. 659-692, 2018. Abstract
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Mohamed, A. W., "A New Modified Binary Differential Evolution Algorithm and its Applications", Applied Mathematics & Information Sciences, vol. 10, issue 5: Natural Sciences Publishing, pp. 1965-1969, 2016. Abstract
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Mohamed, A. W., A. A. Hadi, and K. M. Jambi, Novel mutation strategy for enhancing SHADE and LSHADE algorithms for global numerical optimization, , vol. 50, pp. 100455, 2019. AbstractWebsite

Proposing new mutation strategies to improve the optimization performance of differential evolution (DE) is an important research study. Therefore, the main contribution of this paper goes in three directions: The first direction is introducing a less greedy mutation strategy with enhanced exploration capability, named DE/current-to-ord_best/1 (ord stands for ordered) or ord_best for short. In the second direction, we introduce a more greedy mutation strategy with enhanced exploitation capability, named DE/current-to-ord_pbest/1 (ord_pbest for short). Both of the proposed mutation strategies are based on ordering three selected vectors from the current generation to perturb the target vector, where the directed differences are used to mimic the gradient decent behavior to direct the search toward better solutions. In ord_best, the three vectors are selected randomly to enhance the exploration capability of the algorithm. On the other hand, ord_pbest is designed to enhance the exploitation capability where two vectors are selected randomly and the third is selected from the global p best vectors. Based on the proposed mutation strategies, ord_best and ord_pbest, two DE variants are introduced as EDE and EBDE, respectively. The third direction of our work is a hybridization framework. The proposed mutations can be combined with DE family algorithms to enhance their search capabilities on difficult and complicated optimization problems. Thus, the proposed mutations are incorporated into SHADE and LSHADE to enhance their performance. Finally, in order to verify and analyze the performance of the proposed mutation strategies, numerical experiments were conducted using CEC2013 and CEC2017 benchmarks. The performance was also evaluated using CEC2010 designed for Large-Scale Global Optimization. Experimental results indicate that in terms of robustness, stability, and quality of the solution obtained, both mutation strategies are highly competitive, especially as the dimension increases.

Madhu, G., S. Kautish, K. A. Alnowibet, H. M. Zawbaa, and A. W. Mohamed, "Nipuna: A novel optimizer activation function for deep neural networks", Axioms, vol. 12, issue 3: MDPI, pp. 246, 2023. Abstract
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Hassan, S. A., P. Agrawal, T. Ganesh, and A. W. Mohamed, "A Novel Multi-Objective Nonlinear Discrete Binary Gaining-Sharing Knowledge-Based Optimization Algorithm: Optimum Scheduling of Flights for Residual Stranded Citizens Due to COVID-19", International Journal of Applied Metaheuristic Computing (IJAMC), vol. 13, issue 1: IGI Global, pp. 1-25, 2022. Abstract
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Hassan, S. A., P. Agrawal, T. Ganesh, and A. W. Mohamed, "A Novel Discrete Binary Gaining-Sharing Knowledge-Based Optimization Algorithm for the Travelling Counselling Problem for Utilization of Solar Energy", International Journal of Swarm Intelligence Research (IJSIR), vol. 13, issue 1: IGI Global, pp. 1-24, 2022. Abstract
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El-Quliti, S. A., A. H. M. Ragab, R. Abdelaal, A. W. Mohamed, A. S. Mashat, A. Y. Noaman, and A. H. Altalhi, "A nonlinear goal programming model for university admission capacity planning with modified differential evolution algorithm", Mathematical Problems in Engineering, vol. 2015: https://doi.org/10.1155/2015/892937, pp. 13, 2015. Abstract
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Ali W. Mohamed, Anas A. Hadi, K. J. M., "Novel mutation strategy for enhancing SHADE and LSHADE algorithms for global numerical optimization", Swarm and Evolutionary Computation, vol. 50, issue 100455: https://doi.org/10.1016/j.swevo.2018.10.006., 2019. Abstract
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Ali W. Mohamed, Anas A. Hadi, K. J. M., "Novel mutation strategy for enhancing SHADE and LSHADE algorithms for global numerical optimization", Swarm and Evolutionary Computation, vol. 50, issue 100455: https://doi.org/10.1016/j.swevo.2018.10.006., 2019. Abstract
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Agrawal, P., T. Ganesh, and A. W. Mohamed, "A novel binary gaining–sharing knowledge-based optimization algorithm for feature selection", Neural Computing and Applications, vol. 33, issue 11: Springer London, pp. 5989-6008, 2021. Abstract
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Agrawal, P., T. Ganesh, and A. W. Mohamed, "A novel binary gaining–sharing knowledge-based optimization algorithm for feature selection", Neural Computing and Applications, vol. 33, issue 11: Springer London, pp. 5989-6008, 2021. Abstract
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