P. Naga Lakshmi,∗ R. Ashok Kumar,∗∗ and K. Hari Krishna∗∗∗


  1. [1] J. Kathiresan, S.K. Natarajan, and G. Jothimani, Energy management of distributed renewable energy sources for residential DC microgrid applications, International Transactions on Electrical Energy Systems, 30(3), 2020, e12258.
  2. [2] D. Kumar, F. Zare, and A. Ghosh, DC microgrid technology: system architectures, AC grid interfaces, grounding schemes, power quality, communication networks, applications, and standardizations aspects, IEEE Access 5 (2017): 12230–12256.
  3. [3] Shakweh, Yahya, and Eric A. Lewis. Assessment of medium voltage PWM VSI topologies for multi-megawatt variable speed drive applications, 30th Annual IEEE Power Electronics Specialists Conference. Record.(Cat. No. 99CH36321). Vol. 2. IEEE, 1999.
  4. [4] A. Iovine, et al., Power management for a DC MicroGrid integrating renewables and storages, Control Engineering Practice, 85, 2019, 59–79.
  5. [5] X. Li, et al., Robust and autonomous dc bus voltage control and stability analysis for a DC microgrid, 2016 IEEE 8th International Power Electronics and Motion Control Conference (IPEMC-ECCE Asia). IEEE, 2016.
  6. [6] S. Bhattacharjee and C. Nandi, Design of a voting based smart energy management system of the renewable energy based hybrid energy system for a small community, Energy, 214, 2021, 118977.
  7. [7] H. Lotfi and A. Khodaei, AC versus DC microgrid planning, IEEE Transactions on Smart Grid, 8(1), 2015, 296–304.
  8. [8] Y. Ito, Y. Zhongqing, and H. Akagi, DC microgrid based distribution power generation system, The 4th International Power Electronics and Motion Control Conference, IPEMC 2004. Vol. 3. IEEE, 2004.
  9. [9] S. Bhattacharjee, S. Chakraborty, and C. Nandi, An optimization case study of hybrid energy system in four different regions of India, Advances in Greener Energy Technologies. Springer, Singapore, 2020, 399–437.
  10. [10] A. Silani, et al. Output regulation for voltage control in DC networks with time-varying loads, IEEE Control Systems Letters 5(3), 2020, 797–802.
  11. [11] G.C. Kryonidis, et al., A coordinated droop control strategy for overvoltage mitigation in active distribution networks, IEEE Transactions on Smart Grid, 9(5), 2017, 5260–5270.
  12. [12] T. Morstyn, et al., Unified distributed control for DC microgrid operating modes, IEEE Transactions on Power Systems, 31(1), 2015, 802–812.
  13. [13] A. Khorsandi, et al., Automatic droop control for a low voltage DC microgrid, IET Generation, Transmission and Distribution, 10(1), 2016, 41–47.
  14. [14] N.L. Diaz, et al., Fuzzy-logic-based gain-scheduling control for state-of-charge balance of distributed energy storage systems for DC microgrids, 2014 IEEE Applied Power Electronics Conference and Exposition-APEC 2014. IEEE, 2014.
  15. [15] L. Gao, et al., A DC microgrid coordinated control strategy based on integrator current-sharing, Energies, 10(8), 2017, 1116.
  16. [16] F. Zhao, et al., Small-signal modeling and stability analysis of DC microgrid with multiple type of loads, 2014 International Conference on Power System Technology. IEEE, 2014.
  17. [17] L. Yang, et al., Second ripple current suppression by two bandpass filters and current sharing method for energy storage converters in DC microgrid, IEEE Journal of Emerging and Selected Topics in Power Electronics, 5(3), 2016, 1031–1044.
  18. [18] H. Kakigano, et al., DC micro-grid for super high quality distribution—System configuration and control of distributed generations and energy storage devices, 2006 37th IEEE Power Electronics Specialists Conference. IEEE, 2006.
  19. [19] S. Bhattacharjee and C. Nandi, Design of an industrial internet of things-enabled energy management system of a gridconnected solar wind hybrid system-based battery swapping charging station for electric vehicle, Applications of Internet of Things. Springer, Singapore, 2021. 1–14.
  20. [20] J. Mohammadi and F.B. Ajaei, Adaptive voltage-based load shedding scheme for the DC microgrid, IEEE Access, 7, 2019, 106002–106010.
  21. [21] T. Yang, et al., Electric springs with coordinated battery management for reducing voltage and frequency fluctuations in microgrids, IEEE Transactions on Smart Grid, 9(3), 2016, 1943–1952.
  22. [22] N. Vafamand, et al., Robust non-fragile fuzzy control of uncertain DC microgrids feeding constant power loads, IEEE Transactions on Power Electronics, 34(11), 2019, 11300–11308.
  23. [23] Q. Wang, M. Cheng, and Y. Jiang, Harmonics suppression for critical loads using electric springs with current-source inverters, IEEE Journal of Emerging and Selected Topics in Power Electronics, 4(4), 2016, 1362–1369.
  24. [24] Y. Chen, et al., An adaptive voltage regulation control strategy of an electric spring based on output current feedback, IEEJ Transactions on Electrical and Electronic Engineering, 14(3), 2019, 394–402.
  25. [25] J. Liao, et al., Decoupling control for DC electric spring-based unbalanced voltage suppression in a bipolar DC distribution system, IEEE Transactions on Industrial Electronics, 68(4), 2020, 3239–3250.
  26. [26] A.G. Anu, R. Hari Kumar, and S. Ushakumari, Power quality enhancement of DC micro-grid using DC electric spring, Advances in Smart Grid Technology. Springer, Singapore, 2020, 137–148.
  27. [27] C.K. Lee, S.C. Tan, F.F. Wu, S.Y.R. Hui and B. Chaudhuri, Use of Hooke’s law for stabilizing future smart grid – The electric spring concept, 2013 IEEE Energy Conversion Congress and Exposition, 2013, 5253–5257, doi: 10.1109/ECCE.2013.6647412.
  28. [28] S.Y. Hui, C.K. Lee, and F.F. Wu, Electric springs—a new smart grid technology, IEEE Transactions on Smart Grid, 3(3), 2012, 1552–1561, doi: 10.1109/TSG.2012.2200701.
  29. [29] M. Yin, et al., Modeling of the wind turbine with a permanent magnet synchronous generator for integration, 2007 IEEE Power Engineering Society General Meeting. IEEE, 2007.
  30. [30] Z. Jin, et al., Admittance-type RC-mode droop control to introduce virtual inertia in DC microgrids, 2017 IEEE Energy Conversion Congress and Exposition (ECCE). IEEE, 2017.
  31. [31] S. Moon, S. Jou, and K. Lee, State-space average modeling of bidirectional DC-DC converter for battery charger using LCLC filter, 2014 International Power Electronics Conference (IPEC-Hiroshima 2014 – ECCE ASIA), 2014, 224–229, doi: 10.1109/IPEC.2014.6869584.

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