Implementation of a novel enhanced hybrid multi-objective osprey optimization algorithm for off-grid hybrid system sizing.
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| Title: | Implementation of a novel enhanced hybrid multi-objective osprey optimization algorithm for off-grid hybrid system sizing. |
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| Authors: | Bandopadhyay, Joy, Roy, Provas Kumar |
| Source: | Evolutionary Intelligence; Oct2025, Vol. 18 Issue 5, p1-39, 39p |
| Abstract: | A novel enhanced hybrid multi-objective osprey optimization algorithm (EHMOOOA) is proposed in this research work. It is used here for the optimum sizing of an off-grid composite renewable energy sources-based framework comprising a photovoltaic (PV) system, wind turbine generators (WTs), and battery energy storage system (BESS). The system is modelled to supply the administrative block of Kalyani Government Engineering College, Kalyani, India. The novelties include the integration of the quasi-oppositional-based learning mechanism, composite solution-oriented differential evolution algorithm (CSODEA), and Brownian motion concept into the osprey optimization algorithm (OOA). The contribution lies in the development of two novel mutation mechanisms, three new scaling coefficients and advanced extraction strategies for the core vector and the primary predecessor solutions of the difference vectors. The final stage of the exploitation process presents a novel scheme for the location upgrade of the solutions employing Brownian motion. A mathematical configuration has been built to minimize three primary fitness functions: loss of power supply probability (LPSP), levelized cost of electrical energy (LCOE), and net present cost (NPC). For validation purposes, the performances of the proposed hybrid meta-heuristic algorithm are compared with five other powerful optimization algorithms. Eight standard CEC benchmark functions and three CEC2020 actual scenario-constrained optimization problem functions are employed here for the evaluation of the proposed algorithm. The suggested composite methodology yielded the lowest and optimum values of LCOE (0.3029 $/kWh), NPC (0.9184e+05 $), and LPSP (0.000541). The optimum contributions made by PV, WT, and BESS are 80.9%, 10%, and 9.1%, respectively. Validation of the suggested technique has been further carried out by conducting statistical performance analysis through standard deviations. The proposed technique yielded the lowest standard deviation values: 7.4330e 04 (LCOE), 376.8249 (NPC), and 1.9901e 06 (LPSP), respectively. Further, to validate the outcomes, the Shapiro-Wilk test is conducted, followed by the Welch-like ANOVA and Games-Howell post-hoc tests. Moreover, a sensitivity test is performed to evaluate the robustness of EHMOOOA. [ABSTRACT FROM AUTHOR] |
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| Database: | Complementary Index |
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Nájsť tento článok vo Web of Science | Abstract: | A novel enhanced hybrid multi-objective osprey optimization algorithm (EHMOOOA) is proposed in this research work. It is used here for the optimum sizing of an off-grid composite renewable energy sources-based framework comprising a photovoltaic (PV) system, wind turbine generators (WTs), and battery energy storage system (BESS). The system is modelled to supply the administrative block of Kalyani Government Engineering College, Kalyani, India. The novelties include the integration of the quasi-oppositional-based learning mechanism, composite solution-oriented differential evolution algorithm (CSODEA), and Brownian motion concept into the osprey optimization algorithm (OOA). The contribution lies in the development of two novel mutation mechanisms, three new scaling coefficients and advanced extraction strategies for the core vector and the primary predecessor solutions of the difference vectors. The final stage of the exploitation process presents a novel scheme for the location upgrade of the solutions employing Brownian motion. A mathematical configuration has been built to minimize three primary fitness functions: loss of power supply probability (LPSP), levelized cost of electrical energy (LCOE), and net present cost (NPC). For validation purposes, the performances of the proposed hybrid meta-heuristic algorithm are compared with five other powerful optimization algorithms. Eight standard CEC benchmark functions and three CEC2020 actual scenario-constrained optimization problem functions are employed here for the evaluation of the proposed algorithm. The suggested composite methodology yielded the lowest and optimum values of LCOE (0.3029 $/kWh), NPC (0.9184e+05 $), and LPSP (0.000541). The optimum contributions made by PV, WT, and BESS are 80.9%, 10%, and 9.1%, respectively. Validation of the suggested technique has been further carried out by conducting statistical performance analysis through standard deviations. The proposed technique yielded the lowest standard deviation values: 7.4330e 04 (LCOE), 376.8249 (NPC), and 1.9901e 06 (LPSP), respectively. Further, to validate the outcomes, the Shapiro-Wilk test is conducted, followed by the Welch-like ANOVA and Games-Howell post-hoc tests. Moreover, a sensitivity test is performed to evaluate the robustness of EHMOOOA. [ABSTRACT FROM AUTHOR] |
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| ISSN: | 18645909 |
| DOI: | 10.1007/s12065-025-01083-1 |