1. [1] Baker, A., Byrne, D., et al, World Energy Outlook. International Energy Agency, pp. 330-335, 2004. 2. [2] Guerrero, J.M., Vasquez, et al ‘Control strategy for flexible microgrid based on parallel line-interactive UPS systems’, IEEE Trans. Industrial Electronics, pp. 726–736, ., 2009. 3. [3] 4. [4] Ghasemi, A., Asrari, A., Zarif, M., Abdelwahed, S., “Techno-economic analysis of stand-alone hybrid PV–diesel–battery systems for rural electrification...” Renewable and Sustainable Energy Reviews, Vol. 28, pp. 456–462, 2013. 5. [5] Flick, T., and Morehouse, J., Securing the Smart Grid: Next Generation Power Grid Security, Syngress press, 2010. 6. [6] Tushar, M. H. K., Assi, C., and et al “Smart Microgrids: Optimal Joint Scheduling for Electric Vehicles and Home Appliances”, IEEE Trans. Smart Grid, Vol. 5, pp. 239 – 250, 2014. 7. [7] He, Y., Wang, L., and Wang, J., Handbook of CO2 in Power Systems. Springer Berlin Heidelberg, pp. 53-75, 2012. 8. [8] Bakhtyar, B., Fudholi, A., and et al, “Review of CO2 price in Europe using feed-in tariff rates” Renewable and Sustainable Energy Reviews, Vol. 69, pp 685-691, 2017. 9. [9] Zhang, P., Qian, K., et al,“A Methodology for Optimization of Power Systems Demand Due to Electric Vehicle Charging to Electric Vehicle Charging Load” IEEE Trans. Power Systems, Vol. 27, No.3, 2012. 10. [10] Richardson, P., Flynn, D., et al, “Local versus Centralized Charging Strategies for Electric Vehicles in Low Voltage Distribution Systems”, IEEE Trans. Smart Grid, Vol. 3, pp. 1020 – 1028, 2012. 11. [11] Stroehle, P., Becher, S., et al, “The Impact of Charging Strategies for Electric Vehicles on Power Distribution Networks”, IEE Proc. Int. Conf. on the European Energy Market (EEM), Zagreb, pp. 51 – 56, 2011. 12. [12] Bashash, S., and Fathy, H.K., “Cost-Optimal Charging of Plug-In Hybrid Electric Vehicles Under Time-Varying Electricity Price Signals”, IEEE Trans. Intelligent Transportation Systems, Vol.15, pp. 1958 – 1968, 2014. 13. [13] Zhang, P., Qian, K., et al, “A Methodology for Optimization of Power Systems Demand Due to Electric Vehicle Charging Load”, IEEE Trans. Power Systems, Vol. 27, pp. 1628 – 1636, 2012. 14. [14] Zhang, M., and J. Chen, “The Energy Management and Optimized Operation of Electric Vehicles Based on Microgrid”, IEEE Trans. Power Delivery, Vol.29, pp. 1427 – 1435, 2014. 15. [15] VDI-Guideline (2007) VDI 4602, Beuth Verlag, pp. 3-10. 16. [16] Zakariazadeh, A., Jadid, S., et al, “Integrated operation of electric vehicles and renewable generation in a smart distribution system”, Energy Conversion and Management, Vol.89, pp. 99–110, 2015. 17. [17] Chen, C., Duan, S., et al, “Smart energy management system for optimal microgrid economic operation” IET Renewable Power Generation, Vol. 5, pp. 258–267, 2011. 18. [18] Gast, N., Tomozei, D., et al, “Optimal Generation and Storage Scheduling in the Presence of Renewable Forecast Uncertainties”, IEEE Trans. Smart Grid, Vol. 5, pp. 1328 – 1339, 2014. 19. [19] Hytowitz, R.B., and Hedman, K.W., “Managing solar uncertainty in microgrid systems with stochastic unit commitment”, Electric Power Systems Research, Vol. 119, pp. 111–118, 2015. 20. [20] Dai, R., and Mesbahi, M., “Optimal power generation and load management for off-grid hybrid power systems with renewable sources via ... ”, Energy Conversion and Management,Vol. 73, pp. 234–244, 2013. 21. [21] Tiwari, N., and Srivastava, L., “Generation scheduling and micro-grid energy management using differential evolution algorithm”, ”, Int. Conf. on on Circuit, Power and Computing Technologies , Nagercoil, India, pp.1-7, 2016. 22. [22] Banvait, H., Lin, X., et al “Plug-in Hybrid Electric Vehicle Energy Management System using Particle Swarm Optimization”, World Electric Vehicle Journal, Vol. 3, pp. 1-11, 2009. 23. [23] Gast, N., Tomozei, D., et al “Optimal Generation and Storage Scheduling in the Presence of Renewable Forecast Uncertainties”, IEEE Trans. Smart Grid, Vol. 5, pp. 1328 – 1339, 2014. 24. [24] Ruoyang, L., Qiuwei, W., et al, “Distribution locational marginal pricing for optimal electric vehicle charging management”, ”, IEEE Trans. Power Systems, vol. 29, pp. 203 - 211, 2014. 25. [25] Atzeni, I., Ordonez, L.G., et al, “Demand-Side Management via Distributed Energy Generation and Storage Optimization”, IEEE Trans. Smart Grid, Vol. 4, pp. 866 – 876, 2013. 26. [26] Leterme, W., Ruelens, F., et al, “A Flexible Stochastic Optimization Method for Wind Power Balancing With PHEVs”, IEEE Trans. Smart Grid , Vol. 5, pp. 1238 – 1245, 2014. 27. [27] Setlhaolo, D., Xia, X., et al, “Optimal scheduling of household appliances for demand response”, Electric Power Systems Research, Vol. 116, pp. 24-28, 2014. 28. [28] Rastegar, M., Firuzabad, M. F., et al, “Load commitment in a smart home”, Applied Energy, Vol. 96, pp. 45–54, 2012. 29. [29] Taherpoor, H., Niknam, T., et al, “A novel stochastic framework for energy management in renewable micro-grids considering uncertainty ....”, Journal of Intelligent & Fuzzy Systems, Vol. 28, No. 3, pp. 999-1008, 2015. 30. [30] Saber, A.Y., and Venayagamoorthy, G.K., “Resource Scheduling Under Uncertainty in a Smart Grid with Renewables and Plug-in Vehicles”, IEEE Systems Journal, Vol. 6, pp. 103 – 109, 2012. 31. [31] Honarmand, M., Zakariazadeh, A., et al, “Integrated scheduling of renewable generation and electric vehicles parking lot in a smart microgrid”, Energy Conversion and Management, vol. 86, pp. 745–755, 2014. 32. [32] Honarmand, M., Zakariazadeh, A., et al, “Self-scheduling of electric vehicles in an intelligent parking lot using stochastic optimization”, Journal of the Franklin Institute, Vol. 352, pp. 449–467, 2015. 33. [33] King, A. J., and Wallace S. W., Modeling with Stochastic Programming, Springer New York, pp. 33-39, 2012. 34. [34] https://www.vw.com/models/e-golf/ 35. [35] Leou, C. Su, “Stochastic Analyses of Electric Vehicle Charging Impacts on Distribution Network”, Power Systems, ” IEEE Trans. Power Systems, vol. 29, pp. 1055 – 1063, 2014. 36. [36] NASA surface meteorology and solar energy. Available: 〈http://eosweb. larc.nasa.gov/sse/〉.
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