Input-output linearization and zero-dynamics control of three-phase AC/DC voltage-source converters

Nonlinear differential-geometric techniques are proposed for the design of a feedback controller for three-phase voltage-source pulsewidth modulation (PWM) AC/DC boost converters under a cascade control structure. The input-output linearizability of the system modeled in d-q synchronous reference frames is examined. The results lead to a decoupled d-q current control scheme. For the internal DC-bus voltage dynamics (zero dynamics), by considering the d-axis current command as control input and using a square transform on DC-bus voltage, it is shown that this remaining system contains an input memoryless nonlinearity of conic sector type and satisfies the conditions for a Lur'e plant. This suggests a new outer-loop control strategy to control the square of the DC output voltage, rather than DC output voltage itself, utilizing a simple proportional plus integral (PI) controller cascaded to the d-axis current loop. Since most results do not consider the control of zero dynamics, the strategy for the control of zero dynamics via cascade control structure may provide valuable insight for the design of input-output linearized systems in which zero dynamics contain some desired control variables. The absolute tracking concept for Lur'e plants is introduced to prove the global tracking capability with zero steady-state error of the voltage loop. The controlled PWM AC/DC converter has the features of global stability, fast (exponential) tracking of DC-bus voltage command with zero steady-state error, asymptotic rejection of load disturbance, robustness against parameter uncertainties and decoupled dynamical responses between d and q current loops. Also, measurement of load current is not required. All these features are confirmed via laboratory experiments on a 1.5 kVA PC-based controlled prototype.

[1]  D.-C. Lee Advanced nonlinear control of three-phase PWM rectifiers , 2000 .

[2]  Hasan Komurcugil,et al.  Lyapunov-based control for three-phase PWM AC/DC voltage-source converters , 1998 .

[3]  Darren M. Dawson,et al.  QMotor 3.0 and the QMotor robotic toolkit: a PC-based control platform , 2002 .

[4]  J. P. Louis,et al.  Non linear control of PWM rectifier by state feedback linearization and exact PWM control , 1994, Proceedings of 1994 Power Electronics Specialist Conference - PESC'94.

[5]  Song Chong,et al.  Design of a CLOS guidance law via feedback linearization , 1992 .

[6]  G. Zames On the input-output stability of time-varying nonlinear feedback systems Part one: Conditions derived using concepts of loop gain, conicity, and positivity , 1966 .

[7]  Dong-Choon Lee,et al.  DC-bus voltage control of three-phase AC/DC PWM converters using feedback linearization , 2000 .

[8]  H. Sira-Ramírez,et al.  Adaptive feedback stabilization in PWM-controlled DC-to-DC power supplies , 1993 .

[9]  Constantinos Mavroidis,et al.  PC-based control of robotic and mechatronic systems under MS-Windows NT workstation , 2001 .

[10]  Roland Siegwart,et al.  Application of digital signal processors for industrial magnetic bearings , 1994, IEEE Trans. Control. Syst. Technol..

[11]  V. Blasko,et al.  A new mathematical model and control of a three-phase AC-DC voltage source converter , 1997 .

[12]  Weiping Li,et al.  Applied Nonlinear Control , 1991 .

[13]  A. Draou,et al.  A new state feedback based transient control of PWM AC to DC voltage type converters , 1995 .

[14]  A. Isidori Nonlinear Control Systems , 1985 .

[15]  John Chiasson,et al.  DIFFERENTIAL-GEOMETRIC METHODS FOR CONTROL OF ELECTRIC MOTORS , 1998 .

[16]  Wen-Inne Tsai,et al.  Analysis and design of three-phase AC-to-DC converters with high power factor and near-optimum feedforward , 1999, IEEE Trans. Ind. Electron..

[17]  Ouassima Akhrif,et al.  Application of a multivariable feedback linearization scheme for rotor angle stability and voltage regulation of power systems , 1999 .

[18]  Geza Joos,et al.  State variable decoupling and power flow control in PWM current-source rectifiers , 1998, IEEE Trans. Ind. Electron..

[19]  R. Ambatipudi,et al.  Average current control of three-phase PWM boost rectifier , 1995, Proceedings of PESC '95 - Power Electronics Specialist Conference.

[20]  R. Wu,et al.  A PWM AC to DC converter with fixed switching frequency , 1988, Conference Record of the 1988 IEEE Industry Applications Society Annual Meeting.

[21]  Yan Guo,et al.  Pole-placement control of voltage-regulated PWM rectifiers through real-time multiprocessing , 1994, IEEE Trans. Ind. Electron..

[22]  D. M. Vilathgamuwa,et al.  Variable structure control of voltage sourced reversible rectifiers , 1996 .

[23]  Bimal K. Bose,et al.  Modern Power Electronics and AC Drives , 2001 .

[24]  G. D. Marques,et al.  DC voltage control and stability analysis of PWM-voltage-type reversible rectifiers , 1998, IEEE Trans. Ind. Electron..

[25]  Boon-Teck Ooi,et al.  Indirect current control of a unity power factor sinusoidal current boost type three-phase rectifier , 1988 .

[26]  S. Fukuda,et al.  Modelling and control of sinusoidal PWM rectifiers , 2002 .

[27]  Mark W. Spong,et al.  Robot dynamics and control , 1989 .