Akash Talwariya and Pushpendra Singh


  1. [1] P. Singh, D.P. Kothari, and M. Singh, Smart grid model, International Journal on Electrical and Electronic Engineering Research, 1(1), 2011, 129–148.
  2. [2] R.A. Abri, E.E. Saadany, and Y. Atwa, Optimal placement and sizing method to improve the voltage stability margin in a distribution system using distributed generation, IEEE Transactions on Power Systems, 28(1), 2013, 326–334.
  3. [3] A. Mahari, and E. Babaei, Optimal DG placement and sizing in distribution systems using imperialistic competition algorithm, IEEE 5th India International Conference on Power Electronics, Delhi, India, 2012, 1–6.
  4. [4] A. Ameli, S. Bahrami, F. Khazaeli, and M.R. Haghifam, A multiobjective particle swarm optimization for sizing and placement of DGs from DG owner’s and distribution company’s viewpoints, IEEE Transactions on Power Delivery, 29(4), 2014, 1831–1840.
  5. [5] P. Singh, D.P. Kothari, and M. Singh, Interconnected distribution network for the integration of distributed energy resources, Research Journal of Applied Sciences, Engineering and Technology, 7(2), 2014, 240–250.
  6. [6] A. Talwariya, D. Sharma, A.K. Pandey, and P. Singh, An execution of smart grid with game theory, International Conference on Recent Advances and Innovations in Engineering, Jaipur, India, 2016, 1–4.
  7. [7] D.P. Kothari, P. Singh, and M. Singh, Concept of energy highways for industrial growth and national prosperity, International Journal of Electronic and Electrical Engineering, 9(3), 2010, 9–15.
  8. [8] P. Singh, D.P. Kothari, and M. Singh, Voltage control in distribution networks having DGs by using UPFC, International Journal on Electronic & Electrical Engineering Systems, 2(1), 2010, 31–38.
  9. [9] J.A.X. Prabhu, S. Sharma, M. Nataraj, and D.P. Tripathi, Design of electrical system based on load flow analysis using ETAP for IEC projects, IEEE 6th International Conference on Power System, Delhi, India, 2016, 1–6.
  10. [10] J.M. Rupa, and S. Ganesh, Power flow analysis for radial distribution system using backward/forward sweep method, International Journal of Electrical, Computer, Electronics and Communication Engineering, 8(10), 2014, 1540–1544.
  11. [11] W. Wei, F. Liu, and S. Mei, Energy pricing and dispatch for smart grid retailers under demand response and market price uncertainty, IEEE Transactions on Smart Grid, 6(3), 2015, 1364–1374.
  12. [12] A. Talwariya, S. K. Sharma, P. Singh, and M. Kolhe, Smart grid development in India with challenges and opportunities: Execution with game theory, International Journal of Technical Research & Science, 3(4), 2018, 122–128.
  13. [13] A. Talwariya, S. K. Sharma, P. Singh, and M. Kolhe, Game theory: Demand side management with DG’s and storage units, International Journal of Technical Research & Science, 3(4), 2018, 129–133.
  14. [14] S. Mei, W. Wei, and F. Liu, On engineering game theory with its application in power systems, Control Theory and Technology, 15(1), 2017, 1–12.
  15. [15] A. Talwariya, S.K. Sharma, P. Singh, and M. Kolhe, A game theory approach for energy tariff and demand side management, International Conference on Recent Advancement and Innovations in Engineering, Jaipur, India, 2018, 1–5.
  16. [16] M. Marzband, M. Javadi, S.A. Pourmousavi, and G. Lightbody, An advanced retail electricity market for active distribution systems and home microgrid interoperability based on game theory, Electric Power Systems Research, 157, 2018, 187–199.
  17. [17] A. Talwariya, P. Singh, and M. Kolhe, A stepwise power tariff model with game theory based on Monte-Carlo simulation and its applications for household, agricultural, commercial and industrial consumers, International Journal of Electrical Power & Energy Systems, 111, 2019, 14–24.

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