Cover
Vol. 12 No. 2 (2017)

Published: January 31, 2017

Pages: 123-136

Original Article

Design and Implementation of Neuro-Fuzzy Controller Using FPGA for Sun Tracking System

Ammar A. Aldair 1 Adel A. Obed 2 Ali F. Halihal 3
1Electrical Eng. University of Basrah Basra/ Iraq.
2Electrical Power Eng. Middle Technical University Baghdad/ Iraq.
3Electrical Eng. University of Basrah Basrah/ Iraq.
History
  • Received: November 30, 2016
  • Available Online: January 31, 2017
DOI

https://doi.org/10.37917/ijeee.12.2.2

Abstract

Nowadays, renewable energy is being used increasingly because of the global warming and destruction of the environment. Therefore, the studies are concentrating on gain of maximum power from this energy such as the solar energy. A sun tracker is device which rotates a photovoltaic (PV) panel to the sun to get the maximum power. Disturbances which are originated by passing the clouds are one of great challenges in design of the controller in addition to the losses power due to energy consumption in the motors and lifetime limitation of the sun tracker. In this paper, the neuro-fuzzy controller has been designed and implemented using Field Programmable Gate Array (FPGA) board for dual axis sun tracker based on optical sensors to orient the PV panel by two linear actuators. The experimental results reveal that proposed controller is more robust than fuzzy logic controller and proportional- integral (PI) controller since it has been trained offline using Matlab tool box to overcome those disturbances. The proposed controller can track the sun trajectory effectively, where the experimental results reveal that dual axis sun tracker power can collect 50.6% more daily power than fixed angle panel. Whilst one axis sun tracker power can collect 39.4 % more daily power than fixed angle panel. Hence, dual axis sun tracker can collect 8 % more daily power than one axis sun tracker .

Keywords

References

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