Crowded plant height optimisation algorithm tuned maximum power point tracking for grid integrated solar power conditioning system

Solar energy is the base for both photovoltaic (PV) power generation and plant growth. Inspired by this biological phenomenon, a novel crowded plant height optimisation (CPHO) algorithm was developed for solar PV maximum power point tracking (MPPT). This CPHO-tuned MPPT algorithm was developed with...

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Bibliographic Details
Published in:IET renewable power generation 2019-09, Vol.13 (12), p.2137-2147
Main Authors: Pachaivannan, Nammalvar, Subburam, Ramkumar, Ramkumar, Umadevi, Kasinathan, Padmanathan
Format: Article
Language:English
Subjects:
algorithm‐based MPPT control
biological phenomenon
converter control strategy
CPHO algorithm
CPHO‐tuned MPPT algorithm
crowded plant height optimisation algorithm
DC output
DC–DC boost converter
dynamic weather conditions
d–q vector control‐based voltage source inverter
grid integrated solar power conditioning system
height convergence
invertors
maximum power point trackers
maximum solar power extraction
neighbouring plants
optimal duty cycle
optimal height
optimal numerical value
photovoltaic power generation
photovoltaic power systems
PI control
plant growth
power generation control
power grids
proportional–integral controller
PV panels
PV power integration
Research Article
solar energy
solar power
solar PV maximum power point tracking
stable height
stem height
voltage‐source convertors
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Summary:Solar energy is the base for both photovoltaic (PV) power generation and plant growth. Inspired by this biological phenomenon, a novel crowded plant height optimisation (CPHO) algorithm was developed for solar PV maximum power point tracking (MPPT). This CPHO-tuned MPPT algorithm was developed with the aim of obtaining the optimal duty cycle (d) for DC-DC boost converter for maximum solar power extraction from PV panels with the help of a proportional-integral controller. Crowded plants regulate the growth of their stem height in relation to neighbouring plants, also known as height convergence. Using this CPHO-algorithm, the stable height of the plant found in a numerical value is taken as the optimal height of the plant. This optimal numerical value was converted into (d) for the converter. Under dynamic weather conditions, the (d) was optimally adjusted by the proposed algorithm to regulate the DC output of the converter. On the utility side, d–q vector control-based voltage source inverter was used for PV power integration into the grid. The performance of the converter control strategy of the proposed CPHO algorithm was compared with perturb and observe algorithm-based MPPT control, which was analysed on MATLAB/Simulink platform.
ISSN:1752-1416
1752-1424
1752-1424
DOI:10.1049/iet-rpg.2018.5053