Fossil fuels is the main energy resource now a day with the advantage of generating gigantic electricity at a given location. Fossil resources, however, are subject to exhaustion rendering energy resources risks. The process of electricity generation from fossils fuels may be less costly compared to other schemes however this advantage comes at the expense of increased pollution, greenhouse gases emission contributing to overall global warming. Sustainable energy production requires reusable energy resources. Each renewable energy resource is characterized by a unique characteristic set and advantages, making it suitable for application of specific nature and location. In a hybrid system, the cummulative sum of the powers generated by the constituent systems should match the load demand rendering its implementation complex mainly due to the non linear behavior of the renewable energy resources and the non linearity of the fuel consumption curve. The dissimilar load demand pattern and the limit on the operation of the battery also poses a constraint. Controlling the process of any compound power source system in an optimal manner is essential and challenging to achieve low overall system cost.
Muhammad Waseem Dr. Abdul Basit and Imran Khan Control of Optimal Operation with Hybrid Energy System International Journal of Engineering Works Vol. 5 Issue 11 PP. 224-231 November 2018
Ardakani, Fatemeh Jahanbani, Gholamhossein Riahy, and Mehrdad Abedi. ”Design of an optimum hybrid renewable energy system consider-ing reliability indices.” Electrical Engineering (ICEE), 2010 18th Iranian Conference on. IEEE, 2010.
Ardakani, Fatemeh Jahanbani, Gholamhossein Riahy, and Mehrdad Abedi. ”Optimal sizing of a grid-connected hybrid system for north-west of Iran-case study.” Environment and Electrical Engineering (EEEIC), 2010 9th International Conference on. IEEE, 2010.
Ashari, Mochamad, and C. V. Nayar. ”An optimum dispatch strategy using set points for a photovoltaic (PV)CdieselCbattery hybrid power system.” Solar Energy 66.1 (1999): 1-9.
Bajpai, Prabodh, and Vaishalee Dash. ”Hybrid renewable energy systems for power generation in stand-alone applications: a review.” Renewable and Sustainable Energy Reviews 16.5 (2012): 2926-2939.
Bakare, G. A., et al. ”Differential evolution approach for reactive power optimization of Nigerian grid system.” Power Engineering Society Gen-eral Meeting, 2007. IEEE. IEEE, 2007.
Banos, Raul, et al. ”Optimization methods applied to renewable and sus-tainable energy: A review.” Renewable and Sustainable Energy Reviews 15.4 (2011): 1753-1766.
Barley, C. Dennis, et al. Optimal control of remote hybrid power systems. Part 1: Simplified model. No. NREL/TP-441-7806; CONF-950309-3. National Renewable Energy Lab., Golden, CO (United States), 1995.
Bashir, Mohsen, and Javad Sadeh. ”Optimal sizing of hybrid wind/photovoltaic/battery considering the uncertainty of wind and photo-voltaic power using Monte Carlo.” Environment and Electrical Engineer-ing (EEEIC), 2012 11th International Conference on. IEEE, 2012.
Bashir, Mohsen, and Javad Sadeh. ”Size optimization of new hybrid stand-alone renewable energy system considering a reliability index.” Environment and Electrical Engineering (EEEIC), 2012 11th International Conference on. IEEE, 2012.
Bernal-Agustłn, Jos L., and Rodolfo Dufo-Lopez. ”Simulation and optimization of stand-alone hybrid renewable energy systems.” Renewable and Sustainable Energy Reviews 13.8 (2009): 2111-2118.
Borowy, Bogdan S., and Ziyad M. Salameh. ”Methodology for optimally sizing the combination of a battery bank and PV array in a wind/PV hybrid system.” IEEE Transactions on energy conversion 11.2 (1996): 367-375.
Chen, Fengzhen, et al. ”RenewislandsłRenewable energy solutions for islands.” Renewable and Sustainable Energy Reviews 11.8 (2007): 1888-1902.
Connolly, David, et al. ”A review of computer tools for analysing the integration of renewable energy into various energy systems.” Applied energy 87.4 (2010): 1059-1082.
Dagdougui, Hanane, et al. ”A dynamic decision model for the real-time control of hybrid renewable energy production systems.” IEEE Systems Journal 4.3 (2010): 323-333.
Maniaci, David C., and Ye Li. Investigating the influence of the added mass effect to marine hydrokinetic horizontal-axis turbines using a General Dynamic Wake wind turbine code. IEEE, 2011.
Dagdougui, Hanane, et al. ”Modelling and control of a hybrid renewable energy system to supply demand of a green-building.” 5th Biennial Conference of the International Environmental Modelling and Software Society: Modelling for Environment’s Sake, iEMSs 2010. Vol. 2. iEMSs Secretariat c/-IDSIA, Galleria 2, Manno, 6928, Switzerland, 2010.
Dehghan, S., et al. ”Optimal sizing of a hybrid wind/PV plant consid-ering reliability indices.” World Academy of Science, Engineering and Technology 56.32 (2009): 527-535.
Afzal, Anis, Mohibullah Mohibullah, and Virendra Kumar Sharma. ”Op-timal hybrid renewable energy systems for energy security: a comparative study.” International Journal of Sustainable Energy 29.1 (2010): 48-58.
Diaf, Said, et al. ”A methodology for optimal sizing of autonomous hybrid PV/wind system.” Energy Policy 35.11 (2007): 5708-5718.