Work place: LRP & LEA Labs. Electronics department, Faculty of Technology, Batna University, Batna, Algeria
E-mail: mkhireddine@yahoo.fr
Website:
Research Interests: Computer Vision, Process Control System, Logic Calculi, Logic Circuit Theory
Biography
Mohamed Salah Khireddine was born at Tolga (Algeria) in 1956. He obtained the Informatics Engineer Degree from the University of Algiers in 1980. He received his Doctorate (Ph.D) in Automation and computer science from the University of Aix-Marseille (France) in July 1990. In 2010 he received a postdoctoral degree in “Habilitation of conducting research in Control Engineering” from the Batna University where he is currently Associate professor in Automation and Industrial Computing and research member in the Advanced Electronics Laboratory (LEA) and head of artificial intelligence team in Productics Research Laboratory (LRP).
He is currently supervising many doctor’s and master’s thesis in different areas of power electronics and robotics. He has published ten papers in the real-time control of mobile robots, fault diagnosis and fault tolerant control of robot arms, and solar photovoltaic energy control.
His research interests include Faults Diagnosis, Fault Tolerant Control, Artificial Intelligence, Control Systems and Robotics.
By M.T. Makhloufi M.S. Khireddine Y. Abdessemed A. Boutarfa
DOI: https://doi.org/10.5815/ijisa.2014.12.03, Pub. Date: 8 Nov. 2014
Photovoltaic generation is the technique which uses photovoltaic cell to convert solar energy to electric energy. Nowadays, PV generation is developing increasingly fast as a renewable energy source. However, the disadvantage is that PV generation is intermittent because it depends considerably on weather conditions.
This paper proposes an intelligent control method for the maximum power point tracking (MPPT) of a photovoltaic system under variable temperature and solar irradiation conditions. In this paper, a simulation study of the maximum power point tracking (MPPT) for a photovoltaic system using an artificial neural network is presented. The system simulation is elaborated by combining the models established of solar PV module and a DC/DC Boost converter. Finally performance comparison between artificial neural network controller and Perturb and Observe method has been carried out which has shown the effectiveness of artificial neural networks controller to draw much energy and fast response against change in working conditions.
Subscribe to receive issue release notifications and newsletters from MECS Press journals