Your search keyword '"Averbukh Moshe"' showing total 4 results

1. Opposition-Based Tunicate Swarm Algorithm for Parameter Optimization of Solar Cells

Author

Sharma, Abhishek, Sharma, Abhinav, Dasgotra Ankit, Jately, Vibhu, Ram, Mangey, Rajput, Shailendra, Averbukh, Moshe, and Azzopardi, Brian

Subjects

General Computer Science, Mean squared error, Building-integrated photovoltaic systems, photovoltaic cells, 02 engineering and technology, Metaheuristics, Households -- Energy consumption, 7. Clean energy, Renewable energy sources, Electric power systems, Robustness (computer science), Convergence (routing), Machine learning, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, opposition-based learning, Mathematics, parameter extraction, metaheuristics, Estimation theory, Photovoltaic cells, 020208 electrical & electronic engineering, Photovoltaic system, General Engineering, Swarm behaviour, Particle swarm optimization, 020206 networking & telecommunications, Function (mathematics), TK1-9971, Electrical engineering. Electronics. Nuclear engineering, tunicate swarm algorithm, Algorithm

Abstract

Parameter estimation of photovoltaic modules is an essential step to observe, analyze, and optimize the performance of solar power systems. An efficient optimization approach is needed to obtain the finest value of unknown parameters. Herewith, this article proposes a novel opposition-based tunicate swarm algorithm for parameter estimation. The proposed algorithm is developed based on the exploration and exploitation components of the tunicate swarm algorithm. The opposition-based learning mechanism is employed to improve the diversification of the search space to provide a precise solution. The parameters of three types of photovoltaic modules (two polycrystalline and one monocrystalline) are estimated using the proposed algorithm. The estimated parameters show good agreement with the measured data for three modules at different irradiance levels. Performance of the developed opposition-based tunicate swarm algorithm is compared with other predefined algorithms in terms of robustness, statistical, and convergence analysis. The root mean square error values are minimum ( 6.83×10−4 , 2.06×10−4 , and 4.48×10−6 ) compared to the tunicate swarm algorithm and other predefined algorithms. Proposed algorithm decreases the function cost by 30.11%, 97.65%, and 99.80% for the SS2018 module, SolarexMSX-60 module, and Leibold solar module, respectively, as compared to the basic tunicate swarm algorithm. The statistical results and convergence speed depicts the outstanding performance of the anticipated approach. Furthermore, the Friedman ranking tests confirm the competence and reliability of the developed approach., This work was supported in part by the European Commission H2020 TWINNING Joint Universal activities for Mediterranean PV integration Excellence (JUMP2Excel) Project under Grant 810809., peer-reviewed

Published

2021

2. Improved Moth Flame Optimization Approach for Parameter Estimation of Induction Motor.

Author

Danin, Zekharya, Sharma, Abhishek, Averbukh, Moshe, and Meher, Arabinda

Subjects

PARAMETER estimation, INDUCTION motors, FLAME, COST functions, PARTICLE swarm optimization, MOTHS

Abstract

The effective deployment of electrical energy has received attention because of its environmental implications. On the other hand, induction motors are the primary equipment used in many industries. Industrial facilities demand the maximum percentage of energy. This energy demand is determined by the operating circumstances imposed by the internal characteristics of the induction motor. Because internal parameters of an induction motor are not immediately measurable, they must be obtained through an identification process. This paper proposed an improved version of moth flame optimization (IMFO) for the efficient parameter estimation of induction motors. A steady-state equivalent circuit of the induction motor is employed for the simulation. The proposed technique handles the parameter estimation problem better than moth flame optimization (MFO), particle swarm optimization (PSO), the flower pollination algorithm (FPA), the tunicate swarm algorithm (TSA), and the sine cosine algorithm (SCA). The anticipated IMFO reduces the cost function by 49.38% as compared with the basic version of MFO. [ABSTRACT FROM AUTHOR]

Published

2022

3. A Novel TSA-PSO Based Hybrid Algorithm for GMPP Tracking under Partial Shading Conditions.

Author

Sharma, Abhishek, Sharma, Abhinav, Jately, Vibhu, Averbukh, Moshe, Rajput, Shailendra, and Azzopardi, Brian

Subjects

TRACKING algorithms, HYBRID systems, PARTICLE swarm optimization, EXTRACTION techniques

Abstract

In this paper, a new hybrid TSA-PSO algorithm is proposed that combines tunicate swarm algorithm (TSA) with the particle swarm optimization (PSO) technique for efficient maximum power extraction from a photovoltaic (PV) system subjected to partial shading conditions (PSCs). The performance of the proposed algorithm was enhanced by incorporating the PSO algorithm, which improves the exploitation capability of TSA. The response of the proposed TSA-PSO-based MPPT was investigated by performing a detailed comparative study with other recently published MPPT algorithms, such as tunicate swarm algorithm (TSA), particle swarm optimization (PSO), grey wolf optimization (GWO), flower pollination algorithm (FPA), and perturb and observe (P&O). A quantitative and qualitative analysis was carried out based on three distinct partial shading conditions. It was observed that the proposed TSA-PSO technique had remarkable success in locating the maximum power point and had quick convergence at the global maximum power point. The presented TSA-PSO MPPT algorithm achieved a PV tracking efficiency of 97.64%. Furthermore, two nonparametric tests, Friedman ranking and Wilcoxon rank-sum, were also employed to validate the effectiveness of the proposed TSA-PSO MPPT method. [ABSTRACT FROM AUTHOR]

Published

2022

4. An Effective Method for Parameter Estimation of a Solar Cell.

Author

Sharma, Abhishek, Sharma, Abhinav, Averbukh, Moshe, Jately, Vibhu, Azzopardi, Brian, and Ustun, Taha Selim

Subjects

PARTICLE swarm optimization, SOLAR cells, STANDARD deviations, PARAMETER estimation, SILICON solar cells, MATHEMATICAL optimization, MAXIMUM power point trackers, PHOTOVOLTAIC cells

Abstract

Parameter extraction of the photovoltaic cell is a highly nonlinear complex optimization problem. This article proposes a new hybrid version of whale optimization and particle swarm optimization algorithm to optimize the photovoltaic cell parameters. The exploitation ability of particle swarm optimization with adaptive weight function is implemented in the pipeline mode with a whale optimization algorithm to improve its exploitation capability and convergence speed. The performance of the proposed hybrid algorithm is compared with six different optimization algorithms in terms of root mean square error and rate of convergence. The simulation result shows that the proposed hybrid algorithm produces not only optimized parameters at different irradiation levels (i.e., 1000 W/m2, 870 W/m2, 720 W/m2, and 630 W/m2) but also estimates minimum root mean square error even at a low level of irradiations. Furthermore, the statistical analysis validates that the average accuracy and robustness of the proposed algorithm are better than other algorithms. The best values of root mean square error generated by the proposed algorithm are 7.1700 × 10 − 4 and 9.8412 × 10 − 4 for single-diode and double-diode models. It is observed that the estimated parameters based on the optimization process are highly consistent with the experimental data. [ABSTRACT FROM AUTHOR]

Published

2021