An adaptive TS‐fuzzy model based RBF neural network learning for grid integrated photovoltaic applications

Neeraj Priyadarshi; P. Sanjeevikumar; MS Bhaskar; Farooque Azam; Ibrahim B. M. Taha; Mohamed G. Hussien

doi:10.1049/rpg2.12505

IET Renewable Power Generation (Oct 2022)

An adaptive TS‐fuzzy model based RBF neural network learning for grid integrated photovoltaic applications

Neeraj Priyadarshi,
P. Sanjeevikumar,
MS Bhaskar,
Farooque Azam,
Ibrahim B. M. Taha,
Mohamed G. Hussien

Affiliations

Neeraj Priyadarshi: Department of Electrical Engineering JIS College of Engineering Kolkata India
P. Sanjeevikumar: Center for Research and Development KPR Institute of Engineering and Technology Tamilnadu India
MS Bhaskar: Renewable Energy Lab College of Engineering Prince Sultan University Riyadh Saudi Arabia
Farooque Azam: School of Computer Science and Engineering REVA University Bangalore India
Ibrahim B. M. Taha: Electrical Engineering Department College of Engineering Taif University Taif Saudi Arabia
Mohamed G. Hussien: Electrical Power and Machines Engineering Department Faculty of Engineering Tanta University Tanta Egypt

DOI: https://doi.org/10.1049/rpg2.12505
Journal volume & issue: Vol. 16, no. 14
pp. 3149 – 3160

Abstract

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Abstract In this research work, an adaptive TS‐fuzzy based RBF neural network (ATSFRBFNN) algorithm based maximum power point tracker (MPPT) is employed for grid integrated photovoltaic (PV) system. The novel learning algorithm provides accurate and rapid PV power tracking under fluctuating solar insolation. However, an improved damping circulating current limiting inverter controller is employed to generate gating signal of voltage source inverter and to deliver reduced harmonic constant, less power loss, mitigation of power quality issues regulation of Dc‐link voltage utilization for grid integrated PV system under steady, and transient weather conditions. The experimental results justify the improved system performance under varying operating conditions. The behaviour of novel hybrid PV MPPT structure is compared with TS‐fuzzy, RBFNN, and GA‐RBF for higher tracking efficacy, least tracking deviation, accurate responses, and zero steady‐state power oscillation around MPP region.

Published in IET Renewable Power Generation

ISSN: 1752-1416 (Print); 1752-1424 (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Technology: Mechanical engineering and machinery: Renewable energy sources
Website: https://ietresearch.onlinelibrary.wiley.com/journal/17521424

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