Recent Trends in Electronics and Communication Systems

The power crisis is a global concern for research and development engineers. These issues may be summarized manifold. These issues may be sudden outage/ failure of power system network, considerable power loss on the line, the voltage flickers, lack of proper equipment’s to monitor and protection, presence of significant harmonic level in the line that affects the performance of the equipment connected to line.  Some of these issues may persist for long and other some are of shorter duration. Though the various topologies of power electronic devices are available in order to mitigate these crisis, but they still need further improvement in terms of topologies, qualitative sensors/ transducers, coordinated control strategies (i.e., hybrid/ adaptive/ optimal) etc. The present literature recommends use of one of this same Facts controllers to analyze the impact on voltage flickers here on line, which are common events and are typically associated with network faults, transformer energization, or begin of huge motors. While they are limited in length, they can create serious difficulties with sensitive loads like power electronic devices. Thus, a quick three-phase power supply repair person (DVR) has indeed been developed and modeled using an adaptable control to determine its effectiveness, and the associated findings are reported.

W.E. Kazibwe, R.J.Ringlee and G.W, Woodzell, “Power quality: A review,” IEEE Computer Application in Power, pp. 39-42, Jan 1990.

P.Giroux, G.Sybille and H.Le-Huy, “Modelling and simulation of a distribution STATCOM using Simulink’s Power SysytemBlockset,” The 27th Annual Conference of IEEE Industrial Electronic Society, pp. 990-994. IECON’01.

J. Sun, D.Czarkowski and Z. Zabar, “Voltage mitigation using PWM-based Distribution STATCOM,” IEE Power Engineering Society Summer Meeting, vol. 1, pp. 616-621, Yr-2002.

H.Ding and et.al., “A novel dynamic voltage restorer and its unbalanced control strategy based on space vector pwm,” Elect Power Energy Syst., vol-24, no.9, pp. 693-699, Nov-2002.

D.M.Vilathgamuwa and et.al., “Voltage sag compensation with energy optimized dynamic voltage restorer,” IEEE Trans on Power Delivery, vol. 18, no. 3, pp. 928-936, July 2003.

C.Fitzer, M.Barnes and P.Green, “Voltage sag detection technique for a dynamic voltage restorer,” IEEE Trans on Industrial Application, vol. 40, no. 1, pp. 203-212, Jan/Feb 2004.

M.J.Newman and et.al., “A dynamic voltage restorer with selective harmonic compensation at medium voltage level,” IEEE Trans on Industrial Application, vol. 41, no. 6, pp. 1744-1753, Nov/Dec-2005.

S.S. Choi, J.D.Li and D.M. Vltahgamuwa, “A generalised voltage compensation strategy for mitigating the impacts of voltage sags/swells,” IEEE Trans on Power Delivery, vol. 20, no. 3, pp. 2289-2297, July 2005.

B. Delfino, F.Fornari and R. Procopio, “An effective SSC control scheme for voltage sag compensation,” IEEE Trans on Power Delivery, vol. 20, no. 3, pp. 2100-2107, July 2005.

H.Kim and S.K. Sul, “Compensation voltage control in dynamic voltage restorers by use of feedforward and state feedback scheme,” IEEE Trans on Power Electronics, vol. 20, issue-5, pp. 1169-1177, Sept-2005.

I.Riberio and E.R.Barbi, “Harmonic voltage reduction using a series active filter under different load conditions,” IEEE Trans on Power Electronics, vol. 21, issue-25, pp. 1394-1402, Yr-2006.

Y.Kolhatkar and S.P.Das, “ Experimental investigation of a single-phase UPQC with minimum VA loading,” IEEE Trans on Power Delivery, vol. 22, no. 1, pp. 373-380, Jan- 2007.

C.S.Lam, M.C.Wong and Y.D.Han, “Voltage swell and overvoltage compensation with undirectional power flow controlled dyanamic voltage restorer,” IEEE Trans on Power Delivery, vol. 23, no. 4, pp. 2513-2521, Oct-2008.