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The Journal of Engineering Research (TJER), Vol. 13, No. 2 (2016) 149-159 

Realization of a Photovoltaic Fed Sparse Alternating Current 
(AC)-Link Inverter 

 
R. Ramaprabha*, G. Ramya, U. Ashwini and A.H. Fathima Humaira 

Department of Electrical and Electronics Engineering, SSN College of Engineering, Rajiv Gandhi Sala,  
Kalavakkam-603110, Tamilnadu, India 

 
Received 9 September 2015; Accepted 4 January 2016 

 
Abstract: In this paper, a soft-switched alternating current (AC)-link buck-boost inverter with a 
reduced number of switches, referred to as a sparse AC-link buck-boost inverter, was designed and 
implemented for a photovoltaic (PV) interface. Important features of the sparse configuration 
included a lower number of switches, lower failure rates, compactness, and cost-effectiveness. The 
link was composed of a low reactive rating series inductor/capacitor pair. Significant merits of the 
AC-link buck-boost inverter are a zero voltage turn on and a soft turn off of the switches, resulting in 
minimum voltage stress on the switches and negligible switching losses. In this paper, 10 switches 
were used instead of 20 switches as are used in existing buck-boost inverter topology. The reduction 
in the number of switches did not change the principle of operation of the sparse configuration; 
hence, it remains the same as that of the original configuration. The pulse width modulation (PWM) 
technique was used for gating the switches. The inverter operation was validated and implemented 
for PV interface using a microcontroller. 

Keywords: Sparse inverter, Photovoltaic systems, Zero voltage switching, MATLAB, Microcontroller. 

 

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* Corresponding author’s e-mail:  ramaprabhar@ssn.edu.in



R. Ramaprabha, G. Ramya, U. Ashwini and A.H. Fathima Humaira 

 

150 

1.  Introduction 
 
Renewable energy is defined as energy from a 
source that is not depleted when used (Carlson, 
1989), and photovoltaic (PV) energy is the most 
important renewable energy source available. 
(Shen 2008). PV systems are the fastest growing 
energy source worldwide because of an increase 
in energy demand, and the fact that fossil 
energy sources are finite and expensive. PV 
energy is renewable, inexhaustible, and non-
polluting, and can be used for various 
applications (Zahedi 2002). Unlike other non-
renewable energy sources, solar energy sources 
produce few or no waste products such as 
carbon dioxide and other harmful chemical 
substances (Subudhi and Pradhan 2013).  
     The major challenge in PV conversion is to 
use the proper power converter circuits in order 
to convert produced direct current (DC) to 
practical DC-alternating current (AC) 
(Chakraborty et al. 2009). In a standalone or 
grid-connected system, the conversion of DC to 
AC with the proper power quality is important 
(Atcitty et al. 2011). A number of PV inverter 
topologies have been presented in the literature 
(Kerekes et al. 2011). The major challenges are a 
reduction of switches to reduce losses and the 
generation of nearly sinusoidal voltage with 
reduced total harmonic distortion (Kjaer et al. 
2005). These converters, which can be 
configured in many ways, including DC-DC, 
DC-AC, AC-DC, and AC-AC and have many 
advantages over other types of converters. 
Specifically, these converters are more compact 
and reliable, and offer longer lift-time (Qin et al. 
2002). However, one complication is that these 
converters employ more switches than any 
other power processors (Sood et al. 1988). Their 
remarkable merits have paved the way for a 
soft-switching AC-link universal power 
converter which has received noticeable 
attention during the last few years (Amirabadi 
et al. 2009).  
     In spite of advantages over the AC-link buck-
boost inverter, a soft-switching AC-link 
universal power converter requires many 
switches when compared to a more 
conventional inverter (Amirabadi 2013); hence, 
the control method is complicated. In a 
conventional AC-link buck-boost inverter, the 
complementary switches are added to provide 
the    pathway     for    an      AC-link      current  
 
 

(Balakrishnan et al. 2008). This AC-link current 
may reduce the system efficiency with  an 
increased harmonic content. Due to this 
potential issue, the sparse AC-link inverter is 
considered, and the configuration with the 
reduced number of switches is called a sparse 
AC-link buck-boost inverter. The operating 
principle of a sparse AC-link inverter is similar 
to that of a conventional one. The proposed 
inverter has high reliability and low switching 
loss (Toliyat et al. 2008). The most important 
feature of a sparse inverter is that it has 
unidirectional switches which can be fabricated 
by switch modules. The sparse configuration is 
considered to be less expensive, less 
complicated, and more compact compared to 
the AC-link buck-boost inverter (Amirabadi   
2013). The sparse AC-link inverter supports 
bidirectional power flow. In this inverter, the 
complimentary switches are not essential, 
although they provide AC (Amirabadi 2014). 
The converter transfer power through the DC-
link inductor is charged in the input phase and 
discharged at the output phase. The link 
frequency is greater than the output line 
frequency. During the resonance mode, no 
switches conduct, initiating the soft switching 
principle (Amirabadi et al. 2009). However, due 
to the number of switches in the sparse AC-link 
inverter, the switching loss can be increased, 
affecting the system’s efficiency. Hence, in this 
paper, the sparse AC-link inverter is proposed 
with a reduced number of switches. Due to the 
reduced number of switches, the control 
method is very simple compared to a 
conventional AC-link inverter. In the proposed 
method, a reduced number of switches is used 
which makes the control process easier. A soft-
switching AC-link buck-boost inverter 
traditionally uses 20 switches, but the sparse 
configuration proposed by Amirabadi et al. 
(2014) used 18 switches instead of 20. 
     In this paper, a sparse configuration with 10 
switches was implemented for PV interface. The 
operation was checked with 
MATLAB/SIMULINK software (MathWorks, 
Natick, Massachusetts, USA) and validated 
through practical implementation. The paper is 
organized as follows: Section 2 describes the 
design and operation of sparse configuration. 
Section 3 presents the simulation results, and 
section 4 presents the hardware implementation. 
The conclusion is presented in section 5. 
 



 
Realization of a Photovoltaic Fed Sparse Alternating Current (AC)-Link Inverter 

 

151 
 

2. Design and Operation of  PV  
Connected Sparse AC–link 
Inverter 

 
The basic circuit configuration of PV connected 
sparse AC link inverter is shown in Fig 1. The 
input side and the output side are formed by 
four unidirectional switches and six bi-
directional switches respectively. This inverter is 
most similar to a DC-AC buck-boost converter in 
which the link is charged through PV array and 
discharged into the output phases. 
     The charging and discharging of the link in 
reverse is facilitated by the complementary 
switches in each leg. This style of discharging 
leads to an AC in the link, which leads to better 
utilization of the link inductor and capacitor.  
     A single-phase high-frequency transformer 
can be added to the link if isolation is required. 
The PV panel was modelled using a one-diode 
model which consists of a current source in  
parallel  with  a diode  (Villava et al. 2009), a 
shunt resistance, and a series resistance (Fig. 2). 
Key modelling is shown in Eqns. 1–4. 

     In this case, the link inductance of the 
transformer is playing the role of magnetizing 
inductance (Amirabadi et al. 2014). 
 
 

1
taV

dTvKocnVexp

dTiKscnIoI























                          (1) 

nG
G

pvnIdTiKpvI 





                                 (2) 

q
aKTsN

taV                                               (3)  


























1VI
N

N
R

N

V
exp

NINII

pp

ss
s

s

ta

ppopppvm

                 (4) 

 
 

 

 

Figure 1.  Photovoltaic (PV) interfaced sparse alternating current (AC)-link inverter. 

 

Figure 2.  Circuit model used for modelling a photovoltaic (PV) panel. 



R. Ramaprabha, G. Ramya, U. Ashwini and A.H. Fathima Humaira 

 

152 

  
     The PV array is sized accordingly 
(considering maximum power point voltage, 
Vmpp and current, Impp) and the system 
parameters are listed in Table 1.  

Table 1.  System parameters. 
 

Parameters Standards 

Vmpp of single panel 16.54 V 

Impp of single panel 2.55 A 

PV array size/arm 15×2 (15 panels in 
series) 

PV = photovoltaic; V = volts; A = amps. 
 
     The design of an AC link PV inverter is 
explained below (Amirabadi et al. 2012). For the 
purpose of simplicity, a resonating time which 
is less than the power transfer time at full power 
is neglected. The phase carrying maximum 
current is involved in de-energizing of the link 
at modes three and five. The equivalent output 
voltage and current is given by 
 

cosθ
2

opeakπV
oeqV                                     (5) 

 

π
opeak3I

oeqI                                                  (6) 

 
where, Iopeak is the output peak phase current, 
Vopeak is the output peak phase voltage, and cos 
(θ) is the output power factor. The link current 
during energizing and de-energizing is given by 
 

L
chargetpvV

peaklink,I


                             (7) 

 

L
dischargetoeqV

peaklink,I


                    (8) 

   
where, tcharge and tdischarge are the total charging 
times during mode one and total discharging  
time   during modes three and five.  
  
 
 

The average PV current based on the peak of the 
link current is given as follows: 
 














 chargetpeaklink,IT

1
pvI                        (9) 

 
where, T is the period of the link current. Based 
on the above equations, the peak link current 
can be written as: 
 







  oeqIpvI2peaklink,I                        (10) 

 
     The frequency of the link current is 
determined based on the power rating of the 
system and the characteristics of available 
switches. The link inductance is calculated by: 
 







































oeqV
pvV12f

1

peaklink,I
pvVL                      (11) 

     Link capacitance is calculated such that the 
resonating periods within 5% of the link cycle at 
full power.  There are 12 operating modes in 10 
switch sparse AC link inverter. The link is 
energized from the input during modes 1 and 7 
and is de-energized to the outputs during modes 
3, 5, 9 and 11. Modes 2, 4, 6, 8, 10 and 12 are 
devoted to resonance. The link current during 
mode 1 is given by as below: 
 

dt

tlinkdiLpvV







                                             (12) 

 














 


 0LinkiL

tpvVdt
t

0
pvVL

1tLinki

                         (13) 
 
     The operation in different modes is depicted 
in Table 2. The operating principle is shown in 
Fig.  3 for each mode (Amirabadi 2013). 
 
 

 
 

 



 
Realization of a Photovoltaic Fed Sparse Alternating Current (AC)-Link Inverter 

 

153 
 

 
Figure 3.  Operating principle of sparse AC link inverter. 
 
Table 2.  Modes of operation of 10 switch sparse AC-link inverter. 
 

Mode Link operation 
Switches in 
ON state 

Switches in 
conduction 

1 Energizing S0 and S3 S0 and S3 
2 Partial Resonance S10, S14 and S15 None 
3 De-energizing S10, S14 and S15 S10 and S14 
4 Partial Resonance S10 and S15 None 
5 De-energizing S10 and S15 S10 and S15 
6 Partial Resonance S1 and S2 None 

7-12 
The operations are similar to modes 1 to 6. But the link 
charges and discharges in the reverse direction 
through complimentary switch at each leg.  

 
Table 3.  Simulation Parameters 
 

Parameter Values 
Nominal PV voltage (DC link) 240 V 

Output voltage 230 V 

Link inductance 5.5 Μh 

Link capacitor  1000 Μf 

PV side filter  0.001 μH, 1000 μF 

AC side filter  0.200 μH, 200 μF 
                  PV = photovoltaic; DC = direct current; V = volt; Mh = megahertz; Mf = megaXXX;  
                 AC = alternating current; Μh = millihenry; Μf = millifarad. 

 
3.  Simulation Results 
 
     The circuit shown in Fig. 1 was simulated for 
a 1kW PV system using MATLAB/SIMULINK 
(Fig. 4),  and   the   simulation    parameters   are  
 
 

presented in Table 3. The filter components were 
designed using the equations given by 
Amirabadi et al. (2014). Pulse width modulation 
(PWM) pulses were generated in proper 
sequence to turn on the switches. 



R. Ramaprabha, G. Ramya, U. Ashwini and A.H. Fathima Humaira 

 

154 
 

 
 
Figure 4.  MATLAB model of the 10-switch sparse alternating current (AC)-link inverter. 
 
 

 
Figure 5.  Control circuit for pulse width modulation (PWM) generation. 
 

 
Figure 6.  Voltage and current at the direct current (DC) link. 

     The nominal voltage of 240 V forming the PV 
array is given as an input-to-input side bridge, 
while the output is observed from the three legs 
of the output side bridge. The input side bridge 
consists of unidirectional switches while the 
output side consists of bidirectional switches. 
The PWM pulses are generated through the 
control circuit whereas the output current is 
compared with the reference current (Fig. 5). 
     The simulation was carried out using 
MATLAB, and the results are presented below.  
Figure 6 shows the DC  voltage and current from  
The PV array.  The maximum power from the 
PV  array  was  tracked  by  the maximum power  

point tracking algorithm. The maximum power 
was tracked from the PV array only when the 
source impedance matched the load impedance. 
     Figure 7 shows the PWM pulses for switches 
S0–S3. The gating sequence to switches S4–S15 is 
given by comparing the output current from the 
inverter (Fig. 8). 
     Figure 9 shows the input from the DC link 
voltage and current. In such a set-up, when the 
capacitor starts charging, the current flowing 
through the system decreases; when it starts 
discharging, the current flowing through the 
system increases. The frequency of the link 
current is much higher than the frequency of the 
line. 

 
 



 
Realization of a Photovoltaic Fed Sparse Alternating Current (AC)-Link Inverter 

 

155 
 

 

 
Figure 7.  Pulses for the switches in the input side bridge. 
 

 

Figure 8.  Pulses for the switches in the output side bridge. 

     Soft switching is carried out in the sparse AC 
link inverter. Accordingly, there is zero voltage 
switching when the voltage across the switch is 
zero. Then the capacitor starts charging. In  case 

of zero current switching, when the voltage 
across the switch is zero, the current flowing 
through the inductor is also zero. The soft 
switching principle is shown in Fig. 10



R. Ramaprabha, G. Ramya, U. Ashwini and A.H. Fathima Humaira 

 

156 
 

 
 

 

 
Figure 9.  Input dc link current and voltage. 
 

 
Figure 10.  Zero voltage and zero current switching. 
 

 

Figure 11. Voltage and current at the alternating current (AC) side. 

     Figure 11 shows the output voltage and current 
after filter. The output voltage and current are 3ϕ 
AC. The peak value of the line to line voltage of each 
phase is 230 V. The peak value of output current is 5 
A. 

     The output voltage is nearly sinusoidal but 
has a few ripples. The output voltage and 
current are lower than the input voltage and 
current. Hence, the output power is lower than 
the input power, which accounts for the losses.  
 



Realization of a Photovoltaic Fed Sparse Alternating Current (AC)-Link Inverter 
 

157 
 

4.  Hardware Implementation 
 
The experimental setup of the sparse AC link 
inverter is shown in Fig. 12. The gating pulses 
were created using a field programmable gate 
array (FPGA) board. The generated pulses are 
given to the switches of the multi mini capacitor 
(MMC) via the MCT2E opto-coupler. The power 
supply circuit for the optocoupler and processor 
was designed using a step-down transformer, 
bridge rectifier, and regulator. 

     A link inductor and link capacitor are present 
between the input and output sides to perform 
partial resonance and to provide galvanic 
isolation. In order to protect the microcontroller 
and  the  control  circuit   from   power  circuit an  
isolation circuit is provided. The experimental 
results are observed using digital storage 
oscilloscope (DSO).  Figure 13 shows the DC  
link output voltage and current. The three-phase 
output voltage and current waveform from the 
inverter is shown in Fig. 14, where the voltage 
and current are in phase with each other. The 
synchronised current is shown for phase A. 

 

 
Figure 12.  Hardware setup of the sparse AC-link inverter. 

 

 
Figure 13.  Direct current (DC) side voltage (200 V/division) and current (5 A/division). 

 
 
Figure 14.  Alternating current (AC) side voltage (200 V/division) and current (5 A/division). 



R. Ramaprabha, G. Ramya, U. Ashwini and A.H. Fathima Humaira 

 

158 
 

 

Figure 15.  Link current (20 A/division). 

 
     The output AC link current was sinusoidal 
(Fig. 15). The output AC current obtained was 
approximately 5 A. 
    From the results, it can be observed that a 
nearly sinusoidal voltage and current were 
obtained using a sparse AC-link inverter with 
reduced switches. 

 5.  Conclusion 

This paper presents a soft-switched AC-link 
sparse inverter with reduced switches. The 
proposed inverter has some advantages such as 
zero voltage upon turn ON and soft turn OFF of 
switches. Although the proposed inverter has 
reduced switches compared to the existing 
sparse inverter, the efficiency of the system is not 
affected. The inverter has an  LC (Inductor-
Capacitor) pair which acts as a partial resonant 
circuit. This inverter provides isolation between 
the input and output without a transformer. 
Therefore, the inverter is more reliable and 
compact for a grid-connected PV system. The 
performance of the inverter was evaluated 
through both simulated and experimental 
results. 

Acknowledgment 
 
The authors wish to thank the management of 
SSN College of Engineering, Chennai, India, for 
providing all the facilities to carry out this work. 
 
 

 
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