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ETASR - Engineering, Technology & Applied Science Research Vol. 3, �o. 2, 2013, 391-395 391  
  

www.etasr.com �ayak and Dash: Performance Analysis of Different Control Strategies in a Z-source Inverter 
 

Performance Analysis of Different Control  

Strategies in a Z-source Inverter 

Byamakesh Nayak 

School of Electrical Engineering 

KIIT University, Bhubaneswar 

Orissa, India 

electricbkn11@gmail.com 

Saswati Swapna Dash 

Dpt of Electrical Engineering 

YMCA University of Science & Tech. 

Faridabad, Haryana, India 

reachtoswapna@gmail.com 

 
 

 

Abstract— This paper presents the analysis for different control 

techniques in Z-source inverters. The voltage gain versus 

modulation index from simulation result is compared with the 

mathematical calculated voltage gain. Further detailed analysis 

of %THD, %harmonics of output voltage at different modulation 

indexes for different boosting techniques of a Z-source inverter 

are also performed with respect to the traditional VSI by 

MATLAB based simulation. 

Keywords- Z-source inverter; shoot through; boost factor; 

voltage gain; voltage stress; total harmonic distortion (THD) 

I. INTRODUCTION 

Conventionally two types of three phase inverters are used, 
the voltage source inverter (VSI) and the current source 
inverter (CSI). In VSI, a capacitor is used in a DC link to 
obtain a constant voltage source and in CSI a large inductor is 
used to obtain a constant current source. These inverters have 
certain limitations. Commonly used Pulse Width Modulated 
(PWM) VSI is used for buck (step down) DC to AC power 
conversion. An additional DC-DC boost converter is needed to 
boost the AC voltage output. The CSI is used as a boost 
inverter in DC to AC conversion. For a change in voltage 
range, it also requires additional buck (or boost) DC-DC 
converters. Hence, no traditional inverter can be employed 
solely for buck and boost simultaneously, without additional 
DC link converters. 

To overcome the drawbacks of traditional inverters, the 
newly proposed impedance source or Z-source inverter [1] can 
be used, which is virtually the combination of VSI and CSI. It 
employs an impedance network as a DC link consisting of L 
and C to couple the converter bridge and the power source as 
shown in Figure 1. 

A traditional PWM 3-phase VSI operates in eight states, six 
active and two null states. In active states, power is transported 
from the DC link to the AC output, whereas in null states the 
DC link capacitor is charged from the DC source. The shoot-
through state is introduced within the null state of Z-source 
inverter. This cannot be applied in voltage source inverter. The 
shoot-through state in Z-source inverter enhances the voltage at 
the load end. It should be inserted in such a way that, equal null 
intervals are again maintained at the start and end of the 

switching cycle, to achieve the same optimal harmonic 
performance. 

This paper represents the comparison of voltage gain, 
%THD and %harmonics at different modulation indexes using 
different boosting techniques, in Z-source inverter. The 
boosting techniques for the Z-source inverter used in this paper 
are the simple boost control, the maximum boost control, the 
3
rd
 harmonic injected constant boost control and the 3

rd
 

harmonic injected maximum boost control method.  

 

 
Fig. 1.  Z-source inverter 

II. CONTROL TECHNIQUES 

A. Simple boost control 

In the sinusoidal PWM inverter, the gate pulses are 
obtained by comparing the 3-phase balanced sinusoidal carrier 
signals with triangular carrier signals. The drawback of the 
method is that it cannot be used for boosting of the output 
voltage because of the two null states in addition to the six 
active states in one cycle of operations. The shoot-through 
should be introduced in null states by various techniques as 
discussed in [1-2] to boost the output voltage. The shoot-
through techniques are objectionable in sinusoidal PWM 
voltage source inverter. The shoot-through can be inserted in 
null-state if Z-source is incorporated between the input DC 
voltage and the VSI inverter power circuit as shown in Figure 
1. In the VSI switching cycle, the zero state is produced when 
all sinusoidal waveforms are less or greater than the carrier 
signal. Therefore, to provide shoot–through in zero state the 



ETASR - Engineering, Technology & Applied Science Research Vol. 3, �o. 2, 2013, 391-395 392  
  

www.etasr.com �ayak and Dash: Performance Analysis of Different Control Strategies in a Z-source Inverter 
 

other two steady signals (Vp,Vn) whose amplitudes are equal to 
the amplitude of the sinusoidal waveform and the one is the 
negative of the other, are compared with triangular signal as 
shown in Figure 2. As discussed in [1-2] the shoot through 
states are obtained in all three legs at a time, maintaining shoot 
through time per switching cycle as constant.  The gate pulses 
for the simple boost method are shown in Figure 2. The voltage 
gain in simple constant boost ZSI is expressed as: 

ˆ
(1)

2
ac

o

V
G MB

V
= =  

where 
ac
V̂  is the output peak phase voltage, Vo is the input DC 

voltage, M is the modulation index and B is the boost factor.  

The boost factor is determined by following expression: 

0

1
(2)

2
1

B
T
T

=

−

 

where To is the shoot-through time interval over a switching 
period T. The duty ratio (T0/T) decreases with the increase of M 
in shoot-through state. 

Thus the voltage gain can be expressed as: 

ˆ
(3)

2 1
2

ac

o

V M
G MB

V M
= = =

−
 

Voltage stress [2] is given by: 

 

( )2 1 (4)s o oV BV G V= = −  

 

 
Fig. 2.  Gate pulse of  simple constant boost ZSI  

Voltage stress in switches increases as the voltage gain 
increases. So, this control method cannot be implemented to 
obtain higher gain because of the limitation of voltage ratings 
of switches. Therefore, other suitable control techniques can be 
adopted to operate the Z-source inverter at higher gains. 

B. Maximum boost control 

  Voltage stress is minimized on switches by maximizing To 
and B for a given modulation index. Considering the previous 
method, a simple modification is required. The shoot-through 
state is achieved when the triangular carrier wave is either 
greater than the maximum curve of three sinusoidal references 
or smaller than the minimum of the references [2]. Figure 3 
depicts the gate pulse for six switches.  

Averaging of the varying shoot-through times, the boost 
factor, voltage gain and voltage stress are given by the 
following equations: 

1
(5)

2 3 31

ˆ
(6)

3 3
2

3 3
(7)

o

ac

o

s o o

B
T M
T

V M
G MB

V M

G
V BV V

π

π

π

π

π

π

= =
−−

= = =
−

−
= =

 

The voltage stress is much lower in comparison to the 
simple boost control. Hence, the inverter can be operated at a 
higher voltage gain. 

C. Third harmonic injection control 

This method is opted to use the increased range of 
modulation indexes. Similarly to previous methods, the 
overshoot period can be maintained constant and variable. 

In third harmonic injection constant boost technique the 
sinusoidal reference signal is merged with third harmonic 
sinusoidal waveforms with one third amplitude of the 
fundamental, to generate non-sinusoidal waveforms. Constant 
shoot-through is introduced in zero states by comparing the 
triangular carrier wave with a positive, negative constant 
magnitude and generated non-sinusoidal sinusoidal reference 
waveforms as in simple boost control. The gate pulses are 
shown in Figure 4. 

Further, variable shoot-through times are provided 
considering the third harmonic injected sinusoidal reference 
waveforms and triangular carriers like maximum boost control. 
The gate pulses are shown in Figure 5. 

 



ETASR - Engineering, Technology & Applied Science Research Vol. 3, �o. 2, 2013, 391-395 393  
  

www.etasr.com �ayak and Dash: Performance Analysis of Different Control Strategies in a Z-source Inverter 
 

 

Fig. 3.  Gate pulse of  maximum boost ZSI  

 
Fig. 4.  Gate pulse for third harmonic injected constant boost ZSI  

 

 

Fig. 5.  Gate pulse of  third harmonic injected maximum boost ZSI  

The average boost factor and voltage gain in the above two 
cases [2] are given as follows: 

1
(8)

2 3 31

ˆ
(9)

3 3
2

3 3
(10)

o

ac

o

s o o

B
T M
T

V M
G MB

V M

G
V BV V

π

π

π

π

π

π

= =
−−

= = =
−

−
= =

 

The voltage gain remains the same as in the maximum 
boost control, so voltage stresses also remain the same. The 
only advantage in harmonic injected methods is the use of large 
range modulation indexes (M). 

III. PERFORMANCE ANALYSIS 

MATLAB simulations were performed to verify and 
compare different control methods. The SIMULINK model 
used is shown in Figure 6. The parameters used are: L1=L2=0.5 
mH, C1=C2=2 mF, V0=100 V (DC), Switching frequency=2 
kHz, Load: R/phase = 50 ohm, L/phase = 2 mH. The purpose 
of the system is to compare the performance of the different 
control techniques under different modulation indexes with 
constant DC voltage input. A comparative analysis of voltage 
gain at different M is performed based on the mathematical 
calculation and simulation result for various control techniques. 
Results are shown in Figures 7-10. The simulation results for 
voltage gain mostly matches the theoretical analysis, which 
verifies the above analysis and control concepts. 

The comparative bar graph in    Figure 11 for per unit 

output voltage at different modulation index shows the 

boosting of voltage with respect to VSI. Table I and the bar 

graph shown in Figure 12, compares the %THD of output 

voltage at selected modulation indexes for various control 

methods of ZSI with VSI. THD in different boosting methods 

is a little higher in comparison to VSI, but their ranges are 

within the permissible limit. The maximum boost control 

technique yields higher %THD in comparison to constant 

boost technique. 

 

TABLE I.  %THD COMPARISON OF OUTPUT VOLTAGE. 

Mod. 

Index 

 

%THD in Different inverters 

 

 

VSI 
Simple 

Boost 

3 h 

Const. 

boost 

Max. 

boost 

3h 

max. 

boost 

0.65 0.32 1.38 0.62 2.2 1.95 

0.7 0.29 1.44 1.74 4.58 4.03 

0.9 0.23 0.92 0.78 4.37 4.48 

1.1 2.52 2.57 1.36 5.65 4.44 

 

 



ETASR - Engineering, Technology & Applied Science Research Vol. 3, �o. 2, 2013, 391-395 394  
  

www.etasr.com �ayak and Dash: Performance Analysis of Different Control Strategies in a Z-source Inverter 
 

 
Fig. 6.   Circuit diagram of ZSI 

 

 
Fig. 7.  Voltage gain vs modulation index comparison for simple boost 

control 

 

 
Fig. 8.  Voltage gain vs Modulation index comparison for maximum boost 

control 

 
Fig. 9.  Comparison of voltage gain vs modulation index for 1/6th third 

harmonic injected constand boost ZSI 

 

 
Fig. 10.  Comparison of voltage gain vs modulation index for 1/6th third 

harmonic injected Max. boost ZSI 

 

 

Fig. 11.  pu voltage comparison of ZSI with VSI 

 

V
o
lt
a
g
e
 g
a
in
 (
M
B
) 

V
o
lt
a
g
e
 g
a
in
 (
M
B
) 

V
o
lt
a
g
e
 g
a
in
 (
M
B
) 

V
o
lt
a
g
e
 g
a
in
 (
M
B
) 

Modulation index (M) 

Modulation index (M) 

Modulation index (M) 

Modulation index (M) 



ETASR - Engineering, Technology & Applied Science Research Vol. 3, �o. 2, 2013, 391-395 395  
  

www.etasr.com �ayak and Dash: Performance Analysis of Different Control Strategies in a Z-source Inverter 
 

 
Fig. 12.  Comparison of %THD for different ZSI with VSI at different 

modulation index 

       Table II represents the comparison of %age harmonics 
of output voltage for third, fifth and seventh order in different 
control methods at selected modulation index (M). The 
percentage harmonics of constant boost ZSI are at par with 
VSI. But the seventh harmonic in maximum boost control 
technique is slightly higher. The simulated output voltage and 
current waveforms at M=0.7 with passive R-L load in third 
harmonics injected maximum boost ZSI is shown in Figure 13 
for illustration. 

TABLE II.  % HARMONICS COMPARISON OF OUTPUT VOLTAGE. 

(a) 3
rd
 harmonics 

Mod. 

Index 

 

%  Harmonics 

 VSI Simple 

Boost 

3 h 

Const. 

boost 

Max. 

boost 

3h 

max. 

boost 

0.65 0.02 0.21 0.24 0.11 0.16 

0.7 0.01 0.21 0.09 0.07 0.05 

0.9 0.01 0.04 0.12 0.30 0.16 

1.1 0.01 0.33 0.28 0.14 0.07 

 

(b) 5
th
 harmonics 

Mod. 

Index 

 

%  Harmonics 

 VSI Simple 

Boost 

3 h 

Const. 

boost 

Max. 

boost 

3h 

max. 

boost 

0.65 0.02 0.92 0.39 1.41 1.10 

0.7 0.02 0.83 1.59 4.14 3.40 

0.9 0.03 0.42 0.47 2.68 3.07 

1.1 2.12 1.24 1.12 1.42 2.14 

 

(c) 7
th
 harmonics 

Mod. 

Index 

 

%  Harmonics 

 VSI Simple 

Boost 

3 h 

Const. 

boost 

Max. 

boost 

3h 

max. 

boost 

0.65 0.24 0.54 0.24 1.09 0.96 

0.7 0.21 0.29 0.49 1.18 1.91 

0.9 0.18 0.17 0.07 3.07 2.93 

1.1 1.33 1.62 0.31 5.07 3.56 

 

 

 

Fig. 13.  Simulated results of load line voltage and load current  

IV. CONCLUSION 

This paper compares the performances of the control 
methods of ZSI to achieve the maximum voltage output within 
the prescribed limit of harmonics and THD percentages. The 
method can achieve the minimum passive component 
requirement and maintain low voltage stress at the same time. 
This method can be suitable for controlling voltage sags and 
swells in drives. 

REFERENCES 

[1] F. Z. Peng, “Z-source inverter”, IEEE Transactions on Industry 
Applications, Vol. 39, No. 2, pp. 504-510, 2003 

[2] F. Z. Peng, M. Shen, Z. Qian, “Maximum boost control of the Z-source 
inverter”, IEEE Transactions on Power Electronics, Vol. 20, No. 4, pp. 
833-838, 2005 

[3] P. C. Loh, D. M. Vilathgamuwa, Y. S. Lai, G. T. Chua, Y. Li,  “Pulse-
width modulation of Z-source inverters”, IEEE Transactions on Power 
Electronics, Vol. 20, No. 6, pp. 1346-1355, 2005 

%
T
H
D
 

M