Some Design and Simulation of Sliding Mode Variable Structure Control for Hopf Bifurcation in Power Systems

doi:10.4236/epe.2011.31004

Paper Menu >>

Journal Menu >>

Energy and Power Engineering, 2011, 3, 24-28

doi:10.4236/epe.2011.31004 Published Online February 2011 (http://www.SciRP.org/journal/epe)

Some Design and Simulation of Sliding Mode Variable

Structure Control for Hopf Bifurcation in Power Systems*

Qiwei Du1, Zhonghua Su2, Sheng Li2

1Zhejiang Electric Power Corporation, Hangzhou, China

2School of Electric Power Engineering, Nanjing Institute of Technology, Nanjing, China

E-mail: zjsddqw@163.com

Received September 11, 2010; revised November 12, 2010; accepted November 15, 2010

Abstract

In power systems, the Hopf bifurcation (HB) can occur before the saddle-node bifurcation (SNB) and be-

comes one of main reasons of voltage instability and collapse, so the bifurcation control for HB has impor-

tant significance in improving power system voltage stability. In this paper, the numerical bifurcation analy-

sis software MATCONT was used to study bifurcation behavior of a single-machine dynamic-load (SMDL)

system with SVC, and the simulation analysis results show that a unstable Hopf bifurcation (UHB) point oc-

curring before SNB point and engendering potential harm to voltage stability. To delay or eliminate the UHB

phenomenon and enhance voltage stability of the SMDL system with SVC, we designed a sliding mode

variable structure controller. The switching function and control variables of the controller are clearly de-

scribed and the derivations are directly provided in detail in this paper. The MATLAB simulation results

prove that the designed controller can eliminate the UHB point effectively and ensure safe and stable opera-

tion of the system.

Keywords: Voltage Stability, Hopf Bifurcation, SMVSC, Simulation

1. Introduction

With many voltage instability and collapse accidents

occurred in the last 30 years, voltage stability problem

has been drawn extensive attention and become a hot

spot in power system research. Power systems are com-

plex nonlinear dynamic systems in essence, therefore, the

bifurcation theory of nonlinear dynamics has been

widely used for studying power system voltage stability

problem. Now, saddle-node bifurcation (SNB), limit in-

duced bifurcation (LIB), Hopf bifurcation (HB) and sin-

gularity induced bifurcation (SIB) are generally consid-

ered to be the main bifurcation types that cause voltage

instability and collapse in power systems. HB is one of

the typical dynamic bifurcations, when it occurs, the

system will produce periodic oscillations which lead to

voltage collapse finally. The past researches show that

the HB can occur before the SNB and becomes one of

main reasons that lead to voltage instability and collapse

in power systems [1-5]. Obviously, the bifurcation con-

trol aiming at the HB has important significance in im-

proving voltage stability.

Sliding mode variable structure control (SMVSC) is a

kind of nonlinear variable structure control strategy, it

can act purposefully in the dynamic process according to

the current state of the system (such as state variable

deviation and its derivative, etc.), which forces the sys-

tem moving according to the state trajectory of the ex-

pected ‘sliding mode’. There is no need to design an ac-

curacy object model and online identification system for

SMVSC, and with the advantages of fast response and

being physically implemented easily, when the system

comes into sliding mode motion, it is almost unacted on

parameters change and external disturbances. Therefore,

SMVSC has a good adaptability and robustness [6,7].

In power system bifurcation analysis, when the HB

occurs, the power system has to take a short time to os-

cillate before the voltage collapse occurs, and at the same

time, SMVSC can make the trajectory of the system

reach the designed manifold quickly, and slid the stable

equilibrium point. Based on the above analysis, we can

realize the control aiming at the HB by using SMVSC

method in power systems.

*Jiangsu Province University Natural Science Research Project o

China (08KJD470008)

Q. W. DU ET AL.25

2. System Model and Bifurcation Analysis

2.1. Power System Model

A classical single-machine dynamic-load (SMDL) sys-

tem model was proposed to study voltage stability prob-

lem in [8,9]. To delay saddle-node bifurcation and im-

prove voltage stability, Reference [10,11] added a static

var compensator (SVC) to the load bus in the SMDL

system, as shown in Figure 1.

This system in Figure 1 can be described by the fol-

lowing differential state equations [10]:



1sin

cos

ref

VkPVB

BVV













 











 



















(1)

Where δ is the generator power angle; ω is the gen-

erator rotor angle speed; X is the line reactance; E is the

generator potential; D is the generator damping coeffi-

cient; M is the generator moment of inertia; τ is the time

constant of PQ dynamic load; P is the system active

power demand; V is the load bus voltage; k is a scalar

representing constant power factor of the PQ dynamic

load; B is the compensation susceptance of SVC; T is the

control time constant of SVC; Vref is the reference volt-

age value of load bus. The SVC controller is modeled as

a first order pure integrator.

The research results of [10] show that the SVC control

can delay SNB point effectively, but also induces a new

bifurcation phenomenon — HB in the system.

2.2. Bi furc at ion An alys is

We can use MATCONT, a MATLAB package for nu-

merical bifurcation analysis of ordinary differential

equations (ODEs), to analyze bifurcation phenomena of

the simple system shown in Figure 1.

The system parameters appearing in (1) are:

D = 0.1 p.u., M = 0.1 s, X = 0.5 p.u., E = 1 p.u., k = 0.5,

τ = 0.001 s, T = 0.01 s, Vref = 1 p.u.

The MATCONT bifurcation analysis result for the

SMDL system with SVC is depicted in Figure 2. Ac-

cording to Figure 2, a HB point (H) occurs before SNB

point (LP) in the system.

Bifurcation parameter of the HB point (H) is:

(δ, ω, V, B, P) = (0.785469, 0, 1, 1.293043, 1.414314).

First Lyapunov coefficient is 6.406133e + 002 (> 0),

Figure 1. The SMDL system with SVC.

Figure 2. P-δ curve (based on MATCONT).

so the HB point is a subcritical Hopf bifurcation (namely

unstable Hopf bifurcation, UHB), it is harmful to the

system voltage stability.

Figure 3 shows the time domain simulation result for

a change in P from 1.414314 p.u. to 1.42 p.u. (a small

disturbance) at the UHB point. From figure 3 we can

know when the UHB occurs, the load bus voltage will

lose its stability with the increasing oscillation phe-

nomenon and lead to collapse finally, which can be a

mechanism to explain voltage oscillation and instability.

Hence, SNB point couldn’t be the reference standard of

voltage instability, and UHB point can be seen the start-

ing point of voltage instability in power systems.

3. Design of SMVSC

It’s undoubtedly of great significance to delay or elimi-

nate UHB phenomena in power systems which can im-

prove load limits and enhance voltage stability. Refer-

ences [12,13] designed some new types of SVC control-

lers based on SMVSC so that the load bus voltage turns

more stable. In this section, we will use the SMVSC

method to design a SVC controller in the SMDL system,

with the purpose of regulating reactive power output of

SVC and eliminating or delaying UHB phenomenon.

Q. W. DU ET AL.

Figure 3. t-V curve (based on MATCONT).

The differential equations describing the system with

SMVSC are:



1sin

cos

ref

VkPVB

BVVu













 











 



















(2)

Where u is the control input to the SVC.

Set









1234

,,, ,,,

xx xxVB







, take



 as the output. Change the nonlinear sys-

tem to the linear system directly:



fff

zLhhx

zLhLLhf





 



 



 







 



(3)

Namely

1sin

1cos sin

sin sin

sinsin cos

zP D

EVDP DEV

zMX MMX

DkPE EVB

MX X

EVE V































 

 







 







 





 









 (4)

Suppose









zxx





u, and make a nonlinear

transformation as























. After deriva-

tion calculus to (4), the original system can be translated

into the following standard system:

0100 0

0010 0

0001 0

0000 1

 





 





 







 







 









 





(5)

In the new coordinates, suppose the switching function

of the new system:





11223 34

SZCzCzCzz



 (6)

where





1234

,,,

zzzz.

When the system goes into the sliding mode, S = 0, i.e.,





411223

zCzCzCz 3

. Therefore, the sliding mode

equations can be given as follows:

3123

010

001

zCCCz



 



 





 



 





 



(7)

The eigenvalue equation of (7) is:

321

0CCC





 (8)

Supply the poles





123

,,kkk, which enable the sliding

mode Equations (7) to be stable in advance, then





123

,,CC C are derived:



1123

212231

3123

Ckkk

Ckkkkkk

Ckkk











(9)

Substitute the nonlinear transfer equations Z = T(x)

(namely (4)) for the switching function S(Z), then the

switching function of the system in the original coordi-

nates can be derived.

Let equal the exponential reaching law:



sgn







 (10)

Where ε > 0 and l > 0, then

12 23 34

sgn SlS CzCzCzv





   (11)





sgnvCZ SlS



 ,





123

0, ,,CCCC, and

now u can be derived as follows:









 

  



sgn

uxvx

CZS lSx

xCTx STx

lS Txx





























 









(12)

Now we have finished designing the switching function

and the law of the SMVSC. In the next section, the simu-

Q. W. DU ET AL.

lation analyses about control effect of the designed con-

troller will be introduced.

SMVSC is very complex and it keeps regulating the load

bus voltage. However, the swing amplitudes are very

small, and the voltage can remain in the qualified area.

4. Time Domain Simulation 5. Conclusions

To observe and study control effect of the designed

variable structure controller, a MATLAB-procedure was

written and executed for the time domain simulation

analyses. The flow chart of extracting the control vari-

able u is depicted in Figure 4.

In this paper, a simple but meaningful and representative

power system model, the single-machine dynamic-load

system with SVC, was used to analyze Hopf bifurcation

and voltage stability. We also used the SMVSC method

to design a controller to stabilize the load bus voltage

and control UHB phenomenon of the simple system by

controlling the reactive power output of the SVC. Simu-

According to the previous analyses based on MAT-

CONT, we can know that in the SMDL system with SVC,

the UHB occurs when bifurcation parameter is: (δ, ω, V,

B, P) = (0.785469, 0, 1, 1.293043, 1.414314).

Make the UHB point be the initial state of the SMDL

system with SVC, when the system is subjected to a

small disturbance (P is from 1.414314p.u. to 1.42p.u.),

the time domain simulation results without SMVSC and

with SMVSC are depicted in Figure 5 and Figure 6 re-

spectively. According to Figures 5-6, conclusions below

can be got:

Linearization for

system model

Determining the

switching function

Choosing the

exponential

reaching law

Determining the

sliding mode

equations

Extracting the

variable v

Extracting the

variable u

1) When the system without SMVSC operates at the

HB point, after the small disturbance occurs, the load bus

voltage will have a sudden drop at about 0.57s after the

increasing oscillation, and at the same time, the generator

power angle also loses its stability.

2) When the system with SMVSC operates at the HB

point, after the small disturbance occurs, the load bus

voltage won’t have an oscillation and keeps stable, and at

the same time, the generator power angle also keeps its

stability.

3) The load bus voltage after variable structure control

has a little erratic swing at all time, this is because the Figure 4. Flow chart of extracting the variable u.

Figure 5. Time domain simulation results without SMVSC.

Figure 6. Time domain simulation results with SMVSC.

Q. W. DU ET AL.

lation results show that the UHB of the original system

can be eliminated effectively and the voltage stability

margin is improved.

The SMVSC method can eliminate the UHB, but also

bring some new problems. For example, we can derive

the voltage stability index and the voltage stability mar-

gin of the original system by the methods that have been

found in [14,15], but there is no method for the system

with SMVSC at present. In addition, the structure of the

SMVSC is very complex, and it’s very difficult to

change the controller into a practical product now. These

problems will take a long time to be studied. Therefore,

the SMVSC method in many areas including power sys-

tems is still in the stage of theoretical research. There is

an urgent need to solve above problems depending on a

variety of advanced automatic control technologies.

6. References

[1] Y. Wang, H. Chen, R. Zou, “A Nonlinear Controller De-

sign for SVC to Improve Power System Voltage Stabil-

ity,” Electrical Power and Energy Systems, Vol. 22, No.

7, October 2000, pp. 463-70. doi:10.1016/S0142-0615

(00)00023-5

[2] Z. J. Jing, D. S. Xu, Y. Chang, and L. L. Chen, “Bifurca-

tions, Chaos, and System Collapse in a Three Node

Power System,” Electrical Power and Energy Systems,

Vol. 25, No. 6, July 2003, pp. 443-61. doi:10.1016/S014

2-0615(02)00130-8

[3] S. S. Mohamed, A. H. Munther, H. A. Eyad and E. Ab-

del-Aty, “Delaying Instability and Voltage Collapse in

Power System Using SVCs with Washout Filter-Aided

Feedback,” Proceedings of 2005 American Control Con-

ference, Portland, 2005, pp. 4357-4362.

[4] S. F. Liu, J. F. Gao and P. Li, “Multi-Parameter Bifurca-

tion Analysis of a Typical Power System with the Walve

Aggregated Load Model,” Relay, Vol. 32, No. 19, 2004,

pp. 13-17.

[5] Z. W. Peng, G. G. Hu and Z. X. Han, “Power System Volt-

age Stability Analysis Based on Bifurcation Theory,”

China Electric Power Press, Beijing, 2005.

[6] Y. M. Hu, “Variable Structure Control Theory and Ap-

plication,” Science Press, Beijing, 2003.

[7] W. B. Gao, “Variable Structure Control Theory and De-

sign Methods,” Science Press, Beijing, 1996.

[8] C. A. Caňizares, “On Bifurcation, Voltage Collapse and

Load Modeling,” IEEE Transactions on Power Systems,

Vol. 10, No. 1, 1995, pp. 512-522. doi:10.1109/59.37397

[9] C. A. Caňizares, “Calculating Optimal System Parame-

ters to Maximize the Distance to Saddle-Node Bifurca-

tions,” IEEE Transactions on Circuits and Systems-I, Vol.

45, No. 3, 1998, pp. 225-237. doi:10.1109/81.662696

[10] W. Gu, F. Milano, P. Jiang and G. Q. Tang, “Hopf Bifur-

cations Induced by SVC Controllers: A Didactic Exam-

ple,” Electric Power Systems Research, Vol. 77, No. 3-4,

pp. 234-240, 2007. doi:10.1016/j.epsr.2006.03.001

[11] S. Li and Z. H. Su, “Static State Feedback Control for

Saddle-Node Bifurcation in a Simple Power System,”

Proceedings of the 2nd Conference on Power Electronics

and Intelligent Transportation System, Shenzhen, Vol. 1,

2009, pp. 158-160.

[12] J. W. Du, B. Wang and W. Cai, “Study on Nonlinear

Grey Sliding Mode Controller for Static Var Compensa-

tor,” Electrotechnical Application, Vol. 26, No. 7, pp. 50-

53, 2007.

[13] Z. J. Kang and F. Y. Meng, “Nonlinear Variable Struc-

ture SVC Control Based on Extended States Observer,”

Relay, Vol. 35, No. 22, 2007, pp. 10-13.

[14] Y. Li, Y. J. Zhang and W. Liu, “Fast Determination of

Voltage Stability Critical Point and Its Sensitivity Algo-

rithm,” Power System Technology, Vol. 32, No. 18, 2008,

pp. 47-51.

[15] B. Dai, J. H. Zhang, and J. Liu, “Influence of Load In-

crease Pattern on the Oscillatory Instability Margin of

Power Systems,” Proceedings of the CSEE, Vol. 28, No.

25, 2008, pp. 44-49.