Page 249 - Modern Control of DC-Based Power Systems
P. 249
Control Approaches for Parallel Source Converter Systems 213
[12] A. Kolesnikov, et al., Modern Applied Control Theory: Synergetic Approach in
Control Theory, vol. 2, TSURE Press, 2000.
[13] I. Kondratiev, R. Dougal, Synergetic Control Strategies for Shipboard DC Power
Distribution Systems, in: American Control Conference, 2007. ACC ‘07, pp. 4744,
4749, 9 13 July 2007.
[14] I. Kondratiev, E. Santi, R. Dougal, G. Veselov, Synergetic control for DC-DC buck
converters with constant power load, in: 2004 IEEE 35th Annual Power Electronics
Specialists Conference, 2004. PESC 04., vol. 5, no., pp. 3758, 3764 Vol. 5, 20 25
June 2004.
[15] I. Kondratiev, A Synergetic Control for Parallel-connected DC-DC Buck
Converters, PhD Dissertation, University of South Carolina, College of Engineering
and Information Technology, 2005.
[16] M. Cupelli, M. Moghimi, A. Riccobono, A. Monti, A comparison between syner-
getic control and feedback linearization for stabilizing MVDC microgrids with con-
stant power load, in: 2014 IEEE PES Innovative Smart Grid Technologies
Conference Europe (ISGT-Europe), pp. 1, 6, 12 15 Oct. 2014.
[17] E. Santi, A. Monti, D. Li, K. Proddutur, R.A. Dougal, Synergetic control for power
electronics applications: a comparison with the sliding mode approach, J. Circuits
Systems Computers 13 (04) (Aug. 2004) 737 760.
˚
[18] K.J. Astro ¨m, B. Wittenmark, Computer-controlled Systems: Theory and Design,
third ed., Dover Publications, Mineola, NY, 2011.
[19] A. Nusawardhana, S.H. Zak, W.A. Crossley, Nonlinear synergetic optimal control-
lers, J. Guidance Control Dynamics 30 (4) (2007) 1134 1147.
[20] E. Santi, D. Li, A. Monti, A.M. Stankovic, A Geometric Approach to Large-signal
Stability of Switching Converters under Sliding Mode Control and Synergetic
Control, IEEE 36th Power Electronics Specialists Conference, 2005. PESC ‘05,pp.
1389, 1395, 16-16 June 2005.
[21] E. Santi, A. Monti, D. Li, K. Proddutur, R.A. Dougal, Synergetic control for DC-
DC boost converter: implementation options, IEEE Trans. Ind. Appl. 39 (6) (Nov.-
Dec. 2003) 1803 1813.
[22] C. Edwards, S. Spurgeon, Sliding Mode Control: Theory and Applications, Taylor &
Francis, London, 1998.
[23] J. Slotine, W. Li, Applied Nonlinear Control, Prentice-Hall, Englewood Cliffs, NJ,
1991.
[24] C. Tse, Complex Behavior of Switching Power Converters, CRC Press, London, 2000.
[25] I. Kondratiev, R. Dougal, General synergetic control strategies for arbitrary number
of paralleled buck converters feeding constant power load: implementation of
dynamic current sharing, in: 2006 IEEE International Symposium on Industrial
Electronics, vol. 1, no., pp. 257, 261, 9 13 July 2006.
[26] A. Astolfi, D. Karagiannis, R. Ortega, Nonlinear and Adaptive Control With
Applications, Springer Science & Business Media, 2007.
[27] K.D. Young, V.I. Utkin, U. Ozguner, A control engineer’s guide to sliding mode
control, in: IEEE Transactions on Control Systems Technology, vol. 7, no. 3, pp.
328 342, May 1999.
[28] A. Astolfi, R. Ortega, Immersion and invariance: a new tool for stabilization and
adaptive control of nonlinear systems, in: IEEE Transactions on Automatic Control,
vol. 48, no. 4, pp. 590 606, April 2003.
[29] A. Kwasinski, C.N. Onwuchekwa, Dynamic behavior and stabilization of DC
microgrids with instantaneous constant-power loads, in: IEEE Transactions on Power
Electronics, vol. 26, no. 3, pp. 822 834, 2011.
[30] J.M. Guerrero, et al., Hierarchical control of droop-controlled AC and DC micro-
grids—A general approach toward standardization, IEEE Trans. Ind. Electr. 58.1
(2011) 158 172.
