Abstract
The global maximum power point tracking of a PV array under partial shading represents a global optimization problem. Conventional maximum power point tracking algorithms fail to track the global maximum power point, and global optimization algorithms do not provide global maximum power point in real-time mode due to a slow convergence process. This paper presents an intelligent reconfigurable photovoltaic system on the basis of a modified fuzzy neural net that includes a convolutional block, recurrent networks, and fuzzy units. We tune the modified fuzzy neural net based on modified multi-dimension particle swarm optimization. Based on the processing of the sensors’ signals and the photovoltaic array’s image, the tuned modified fuzzy neural net generates an electrical interconnection matrix of a photovoltaic total-cross-tied array, which reaches the global maximum power point under non-homogeneous insolation. Thus, the intelligent reconfigurable photovoltaic system represents an effective machine learning application in a photovoltaic system. We demonstrate the advantages of the created intelligent reconfigurable photovoltaic system by simulations. The simulation results reveal robustness against photovoltaic system uncertainties and better performance and control speed of the proposed intelligent reconfigurable photovoltaic system under non-homogeneous insolation as compared to a GA-based reconfiguration total-cross-tied photovoltaic system.
Highlights
The power generated by a photovoltaic (PV) array depends on temperature, insolation, and partial shading (PS) [1]
We tuned the modified fuzzy neural net (MFNN) based on algorithm 2 “The modified particle swarm optimization (PSO)
We developed and verified an intelligent reconfigurable PV system on the basis of an MFFN, which includes a convolutional block, recurrent neural net (RNN), and fuzzy units
Summary
The power generated by a photovoltaic (PV) array depends on temperature, insolation, and partial shading (PS) [1]. The generated PV array power significantly decreases due to PS, which is difficult to track and forecast. The power loss can vary from 10% to 70% due to PS [2]. The power–voltage (P–V) characteristic of a PV array under PS has several peaks. Tracking of a PV array under PS represents a global optimization problem. Conventional maximum power point tracking (MPPT) algorithms, such as Perturb and Observe, fail to track the GMPP [1]
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