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

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  1. [1] J. Kathiresan, S.K. Natarajan, and G. Jothimani, Energymanagement of distributed renewable energy sources for resi-dential DC microgrid applications, International Transactionson Electrical Energy Systems, 30(3), 2020, e12258.10
  2. [2] D. Kumar, F. Zare, and A. Ghosh, DC microgrid technology:system architectures, AC grid interfaces, grounding schemes,power quality, communication networks, applications, andstandardizations aspects, IEEE Access 5 (2017): 12230–12256.
  3. [3] Shakweh, Yahya, and Eric A. Lewis. Assessment of mediumvoltage PWM VSI topologies for multi-megawatt variablespeed drive applications, 30th Annual IEEE Power ElectronicsSpecialists Conference. Record.(Cat. No. 99CH36321). Vol. 2.IEEE, 1999.
  4. [4] A. Iovine, et al., Power management for a DC MicroGrid inte-grating renewables and storages, Control Engineering Practice,85, 2019, 59–79.
  5. [5] X. Li, et al., Robust and autonomous dc bus voltage controland stability analysis for a DC microgrid, 2016 IEEE 8th In-ternational Power Electronics and Motion Control Conference(IPEMC-ECCE Asia). IEEE, 2016.
  6. [6] S. Bhattacharjee and C. Nandi, Design of a voting based smartenergy management system of the renewable energy basedhybrid 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 baseddistribution power generation system, The 4th InternationalPower Electronics and Motion Control Conference, IPEMC2004. Vol. 3. IEEE, 2004.
  9. [9] S. Bhattacharjee, S. Chakraborty, and C. Nandi, An optimiza-tion case study of hybrid energy system in four different regionsof India, Advances in Greener Energy Technologies. Springer,Singapore, 2020, 399–437.
  10. [10] A. Silani, et al. Output regulation for voltage control inDC networks with time-varying loads, IEEE Control SystemsLetters 5(3), 2020, 797–802.
  11. [11] G.C. Kryonidis, et al., A coordinated droop control strategy forovervoltage mitigation in active distribution networks, IEEETransactions on Smart Grid, 9(5), 2017, 5260–5270.
  12. [12] T. Morstyn, et al., Unified distributed control for DC microgridoperating modes, IEEE Transactions on Power Systems, 31(1),2015, 802–812.
  13. [13] A. Khorsandi, et al., Automatic droop control for a lowvoltage DC microgrid, IET Generation, Transmission andDistribution, 10(1), 2016, 41–47.
  14. [14] N.L. Diaz, et al., Fuzzy-logic-based gain-scheduling control forstate-of-charge balance of distributed energy storage systemsfor DC microgrids, 2014 IEEE Applied Power ElectronicsConference and Exposition-APEC 2014. IEEE, 2014.
  15. [15] L. Gao, et al., A DC microgrid coordinated control strategybased on integrator current-sharing, Energies, 10(8), 2017,1116.
  16. [16] F. Zhao, et al., Small-signal modeling and stability analysis ofDC microgrid with multiple type of loads, 2014 InternationalConference on Power System Technology. IEEE, 2014.
  17. [17] L. Yang, et al., Second ripple current suppression by twobandpass filters and current sharing method for energy storageconverters in DC microgrid, IEEE Journal of Emerging andSelected Topics in Power Electronics, 5(3), 2016, 1031–1044.
  18. [18] H. Kakigano, et al., DC micro-grid for super high qualitydistribution—System configuration and control of distributedgenerations and energy storage devices, 2006 37th IEEE PowerElectronics Specialists Conference. IEEE, 2006.
  19. [19] S. Bhattacharjee and C. Nandi, Design of an industrial inter-net of things-enabled energy management system of a grid-connected solar wind hybrid system-based battery swappingcharging station for electric vehicle, Applications of Internetof Things. Springer, Singapore, 2021. 1–14.
  20. [20] J. Mohammadi and F.B. Ajaei, Adaptive voltage-based loadshedding scheme for the DC microgrid, IEEE Access, 7, 2019,106002–106010.
  21. [21] T. Yang, et al., Electric springs with coordinated batterymanagement for reducing voltage and frequency fluctuationsin microgrids, IEEE Transactions on Smart Grid, 9(3), 2016,1943–1952.
  22. [22] N. Vafamand, et al., Robust non-fragile fuzzy control of uncer-tain DC microgrids feeding constant power loads, IEEE Trans-actions on Power Electronics, 34(11), 2019, 11300–11308.
  23. [23] Q. Wang, M. Cheng, and Y. Jiang, Harmonics suppressionfor critical loads using electric springs with current-sourceinverters, IEEE Journal of Emerging and Selected Topics inPower Electronics, 4(4), 2016, 1362–1369.
  24. [24] Y. Chen, et al., An adaptive voltage regulation control strategyof an electric spring based on output current feedback, IEEJTransactions on Electrical and Electronic Engineering, 14(3),2019, 394–402.
  25. [25] J. Liao, et al., Decoupling control for DC electric spring-basedunbalanced voltage suppression in a bipolar DC distributionsystem, IEEE Transactions on Industrial Electronics, 68(4),2020, 3239–3250.
  26. [26] A.G. Anu, R. Hari Kumar, and S. Ushakumari, Power qualityenhancement of DC micro-grid using DC electric spring, Ad-vances 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. Chaud-huri, Use of Hooke’s law for stabilizing future smart grid– The electric spring concept, 2013 IEEE Energy Con-version 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 newsmart 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 permanentmagnet synchronous generator for integration, 2007 IEEEPower Engineering Society General Meeting. IEEE, 2007.
  30. [30] Z. Jin, et al., Admittance-type RC-mode droop control tointroduce virtual inertia in DC microgrids, 2017 IEEE En-ergy Conversion Congress and Exposition (ECCE). IEEE,2017.
  31. [31] S. Moon, S. Jou, and K. Lee, State-space average modelingof bidirectional DC-DC converter for battery charger usingLCLC filter, 2014 International Power Electronics Conference(IPEC-Hiroshima 2014 – ECCE ASIA), 2014, 224–229, doi:10.1109/IPEC.2014.6869584.

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