M.S. Rahman Tito, Tek T. Lie, and Timothy Anderson
[1] B.S. Borowy and Z.M. Salameh, Optimum photovoltaic array size for a hybrid wind/PV system, IEEE Transactions on Energy Conversion, 9(3), 1994, 482–488. [2] B.S. Borowy and Z.M. Salameh, Methodology for optimally sizing the combination of a battery bank and PV array in wind/PV hybrid system, IEEE Transactions on Energy Conversion, 11(2), 1996, 367–375. [3] T. Markvart, Sizing of hybrid photovoltaic-wind energy systems, Solar Energy, 54(4), 1996, 277–281. [4] R. Chedid and S. Rahman, Unit sizing and control of hybrid wind–solar power systems, IEEE Transaction on Energy Conversion, 12(1), 1997, 79–85. [5] H.X. Yang, L. Lu, and W. Zhou, A novel optimization sizing model for hybrid solar–wind power generation system, Solar Energy, 81(1), 2007, 76–84. [6] D. Xu, L. Kang, L. Chang, and B. Cao, Optimal sizing of standalone hybrid wind/PV power systems using genetic algorithm, Proc. Canadian Conf. on Electrical and Computer Engineering, Saskatoon, 2005, 1722–1725. [7] E. Kourtroulis, D. Kolokotsa, A. Potirakis, and K. Kalaitzakis, Methodology for optimal sizing of stand-alone photovoltaic/wind-generator systems using genetic algorithm, Solar Energy, 80(9), 2006, 1072–1188. [8] The US Department of Energy, http://apps1.eere.energy.gov/buildings/energyplus/weatherdata.about (cited Jan. 30, 2013). [9] M.R. Patel, Wind and Solar Power System, 2nd ed. (UK: CRC Press, 1999). [10] R. Chedid, H. Akiki, and S. Rahman, A decision support technique for the design of hybrid solar–wind power system, IEEE Transactions on Energy Conversion, 13(1), 1998, 76–83. [11] H. Yang, W. Zhou, L. Lu, and Z. Fang, Optimal sizing method for stand-alone solar system with LPSP technology by genetic algorithm, Solar Energy, 82(4), 2008, 354–367. [12] A. Kashefi Kaviani, G.H. Riahy, and S.H. Kouhsari, Optimal design of a reliable hydrogen-based stand-alone wind/PV generating system, considering component outages, Renewable Energy, 34(11), 2009, 2380–2390.
Important Links:
Go Back
