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Engineering, Technology & Applied Science Research Vol. 11, No. 1, 2021, 6781-6786 6781 
 

www.etasr.com Mustafa et al.: Experimental Investigation and Control of a Hybrid (PV-Wind) Energy Power System 

 

Experimental Investigation and Control of a Hybrid 

(PV-Wind) Energy Power System. 
 

Ghulam Mustafa 

Department of Electrical Engineering 

Mehran University of Engineering and Technology 
Khairpur Mir’s, Pakistan 
gm_petarian@yahoo.com 

Mazhar Hussain Baloch 

Department of Electrical Engineering 

Mehran University of Engineering and Technology 
Khairpur Mir’s, Pakistan 

mazhar.hussain08ele@gmail.com 

Sajid Hussain Qazi 

Department of Electrical Engineering 
Mehran University of Engineering and Technology 

Khairpur Mir’s, Pakistan 

sajidhussain@muetkhp.edu.pk 

Sohaib Tahir 

Department of Electrical and Computer Engineering 
COMSATS University Islamabad 

Sahiwal Campus, Pakistan 

sohaibchauhdary@hotmail.com 

Noman Khan 

Department of Electrical Engineering 

Mehran University of Engineering and Technology 
Khairpur Mir’s, Pakistan 

nomankhan@muetkhp.edu.pk 

Baqir Ali Mirjat 

Department of Electrical Engineering 

Mehran University of Engineering and Technology 
Khairpur Mir’s, Pakistan 

baqirali@muetkhp.edu.pk 
 

 

Abstract-The most essential infrastructure of today’s modern 

civilization is the energy system. A new energy revolution is 

ongoing worldwide in understanding the affordability, reliability, 

and sustainability of energy supply. One of the major challenges 

and opportunities considered in this energy revolution is the 

integration of the energy system. The varying dynamics of 

renewable energy production and the environmental conditions 
between the different energy sources are the major reasons for 

this challenge. Wind and solar energies are considered the best 

renewable sources and the foremost substitute sources for power 

generation. These energies are playing a vital role as alternates of 

nuclear energy and fossil fuels. Electricity is generated through 

wind energy conversion systems and photovoltaic (PV) cells. 

These technologies are clean and environmentally friendlier than 
non-renewable energies. A hybrid PV-wind generation system is 

more effective and consistent than a single-source system because 

the solar system cannot work at night or in cloudy weather while 

the wind speed is variable. The current study proposes an 

experimental-based analysis. The hardware used is the Squirrel 

Cage Induction Generator (SCIG) and solar panels. A boost 
converter is added for Maximum Power Point Tracking (MPPT) 
at variable wind speed and available sunlight. 

Keywords—WECS; PV cells; SCIG; MPPT 

I. INTRODUCTION  

Wind and solar energy are the most favorable renewable 
energy sources due to their low cost of energy production. 
Many studies have considered only one of these energy sources 
(solar or wind), which has disadvantages. Wind speed 
variations disturb the generated power through WECS, whereas 

the power produced through PVs is affected by the deviation in 
solar radiation and varying temperature. Hybrid solar/wind 
generation is much more effective and consistent, because the 
solar system cannot work at night or in cloudy weather and 
wind speed is varying with time and season. Moreover, usually 
low winds flow on sunny days when solar generation works 
with higher efficiency [1]. For achieving maximum power, 
DC/DC converters are used in systems [2-7]. Dual input 
recommendations are given in [2] in order to get maximum 
power by using buck/buck boost converters for solar and wind 
systems. The grid connection of a hybrid system based on 
solar/fuel and cell/wind was suggested in [3]. Another 
configuration of multi input booster was proposed for hybrid 
solar/wind generation systems in [8]. In [1], PMSG machines 
were utilized for the wind turbine and two DC/DC converters 
were used for wind and solar energy, whereas in the proposed 
work, a SCIG machine is used for the wind turbine, to get 
maximum power and two separate boost converters are used 
for the wind generator and the PV system. In the proposed 
model, the characteristic of wind energy conversion system, 
exhibits maximum power of 3kW and the PV module 
characteristic exhibits maximum generated power of 44.71W. 

II. PROPOSED HYBRID SYSTEM CONFIGURATION 

This hybrid system is an assemblage of SCIG based WECS, 
PV and super capacitor connected MPPT-based boost 
converters separately at the output of WECS and solar as 
displayed in Figure 1. The converter is easily controlled by 
varying the duty cycle with high efficiency and minimum 

Corresponding author: Mazhar Hussain Baloch 



Engineering, Technology & Applied Science Research Vol. 11, No. 1, 2021, 6781-6786 6782 
 

www.etasr.com Mustafa et al.: Experimental Investigation and Control of a Hybrid (PV-Wind) Energy Power System 

 

power variability. The output of both boost converters is 
connected to a mutual DC bus bar. 

 

 
Fig. 1.  Diagram of the proposed hybrid system. 

A. Maximum Power Point Tracking Algorithm 

The algorithm used in this model is P&O (Perturbation and 
Observation). It is easy to device, low-cost, and simple. The 
flow chart of P&O MPPT is shown in Figure 2. The scheme 
constantly perturbs the operative voltage after equating the 
output power with its earlier value. 

 

 

Fig. 2.  P&O flow chart. 

B. Characteristics of the WECS Generator Model 

In the impacted area on the turbine, the power produced is 
articulated as [9]: 

�� � 	0.5�	
�	�
	, ��²��³    (1) 
where the co-efficient of power is Cp=0.3-0.59, Vω is the speed 

of wind, β is the pitch angle for Zone-2 supposing 0°, 

ρ=1.25kg/m³, and λ is speed ratio of tip and can defined by: 


 � ���     (2) 
Here, ω is denoted as the rotor speed of the wind generator. 

Wind power and the turbine power relations are expressed as: 

�� � ���� � 
��
,����    (3) 

Equation (4) illustrates wind generator’s turbine power 
captured by the wind turbine system. Cp is the performance 
coefficient, � is free wind speed and ω is the turbine's angular 
speed. 


� � �0.73�151 !��� �� " 13 ⋅ 635% &
!

��� ��'(.(()*
'!

   (4) 

The turbine power of the wind generator taken by the 
turbine system is defined by the wind speed given in (4)-(7), 
whereas the speed of the wind turbine is expressed as in [10, 
11]. Equation (5) expresses the power of the wind turbine 
versus its speed, where P is mechanical power, ρ is air density, 
and A is the turbine swept area. 

�� � 55 ⋅ 155�+ ,��-. �� " 0.09exp&
,-
��� " 0.003*

'!
    (5) 

Figure 3 shows the speed of the wind turbine versus the 
wind turbine power expressed from (5), where Vw is wind 
velocity. It should be noted that at different wind speeds, the 
turbine power changes with respect to the speed of turbine. 
Figure 3 shows that the turbine power varies at differed wind 
speeds. The maximum power moves on a 3rd order curve, 
which shows the maximum power produced by the turbine at 
each wind speed. 

 

 
Fig. 3.  Turbine power versus turbine speed. 

C. Wind Generator System’s Controller Model 

Through a rectifier wind-generator system, the three-phase 
AC voltage is inverted to DC voltage (Vin) by back 
electromagnetic force. This review mainly consists on 
maximum power tracking control performed by the varying 
duty cycle of the DC-DC boost converter to the DC side. 
Figure 4 shows the generator control of the DC-DC equivalent 
circuit. The input voltage adjusted through voltage/current is 
controlled by the DC-DC boost converter. As a control variable 
of the duty cycle, the speed of the generator is varied with 
respect to the turbine in the same proportion. 



Engineering, Technology & Applied Science Research Vol. 11, No. 1, 2021, 6781-6786 6783 
 

www.etasr.com Mustafa et al.: Experimental Investigation and Control of a Hybrid (PV-Wind) Energy Power System 

 

 
Fig. 4.  Circuit diagram with the DC-DC booster converter. 

D. PV Cell Modeling 

An equivalent circuit of a single PV cell can be shown by 
applying a source of current, two resistors, and a diode. The 
model of the PV cell with the single diode is shown in Figure 5, 
and its description in Table I. 

 

 

Fig. 5.  Equivalent circuit of the PV cell. 

The PV cell equation for V-I characteristic is expressed as: 

3 � 3�4 " 35 " 367    (6) 
� 3�4'89:;<=> ?@ABC��D8�E�F'!G'

HIJKE
KEL

    (7) 

where: 

3M9 � 3N9 & OCONPQ*
) &RSTUA V

!
ONPQ "

!
OC
W*    (8) 

3�7 � X39Y Z [3��\ " 298�_    (9) 
TABLE I.  PV MODULE PARAMETERS 

Parameter Variable Values 

Maximum power Pm 260W 

Output tolerance 
 

±3% 

Maximum voltage Vm 30.82V 

Maximum current Im 8.44A 

Open circuit voltage Voc 36.97V 

Short circuit current Isc 8.94A 

Reference solar irradiation Sref 1000W/m
2
 

Reference temperature Tref 25
o
C 

Nominal operating cell temperature Tnoct 45±2℃ 
 

E. Super-Capacitor 

It comprises of two actuated carbon electrodes, which are 
electrically shielded by an absorbent separator. The current 
accumulators permit current transferring to the external 
terminals. The entire system is saturated with electrolyte 
permitting the ion transportation between both electrodes. Low 
internal resistance is a property of the super-capacitor. There is 
contact resistance in the electrode between the current collector 
and carbon particles, with increase to the non-significant 

resistance values given by electrode [12-14]. There are many 
advantages of super-capacitors for hybrid systems where 
energy storage devices are needed. The use of these capacitors 
as secondary power systems allows them to respond quickly 
during the high load demand. These capacitors have lower time 
constant than the conventional electrochemical generators 
(perhaps release charge in a few seconds). Moreover, these 
capacitors have the ability to deliver bulk power in a very short 
time. Due to the lack of electrochemical response at the 
electrodes, the super-capacitors are considered to be used for 
stability as storage devices [13]. 

The equivalent model of the super-capacitor is shown in 
Figure 6. Equation (10) gives the expression of Vsc of the 
voltage of the super-capacitor in relation with the internal 
resistance Rsc and the current ISC of the super-capacitor as: 

�9Y � �1 " a9Y39Y � MEbcEb " a9Y39c    (10) 
 

 
Fig. 6.  Equivalent model of the super-capacitor. 

For the proposed hybrid system, the super-capacitor is used 
for storage and stability and is connected to the DC bus. The 
capacitor bank is shown in Figure 7 and the parameters of the 
super-capacitor are given in Table II.  

 

 
Fig. 7.  Super capacitor bank. 

TABLE II.  PARAMETERS OF THE SUPER-CAPACITOR 

Characteristic Value 

Rated capacitance (total) 2.640mF 

Measured capacitance (total) 2.376mF 

Absolute maximum voltage 450V 

Rated capacitance of individual cells 0.22mF 

Number of cells 12 

Temperature 105°C 
 

III. EXPERIMENTAL MODEL AND ANALYSIS 

To study the factual and tangible status, the real setup of the 
wind and solar energy conversion system is required, which is 
mostly set up to generate simulated controlled wind speed to 



Engineering, Technology & Applied Science Research Vol. 11, No. 1, 2021, 6781-6786 6784 
 

www.etasr.com Mustafa et al.: Experimental Investigation and Control of a Hybrid (PV-Wind) Energy Power System 

 

operate the WECS and extract solar energy, which requires 
high cost and big area. A simpler way is software simulation, 
but it has limitations for real-time investigation. The best way 
is to follow the wind turbine norms by using a Motor-
Generator (MG) setup, where a motor replicates the wind 
turbine sketch under varying wind speed and a PV panel with 
artificial generated irradiation represents the solar setup. 

TABLE III.  EQUIPMENT AND TOO L LIST WITH DESCRIPTION 

Equipment name Description 

Prime mover (DC permanent magnet 

machine) 

180Vdc, 2.7A, 0.4KW, 2500rpm. 

Type:EM-3330-1A, S/N: 201 

3 phase squirrel motor (SCIG) 

3-phase, 220V,1.4A, 50/60Hz, 

0.3KW,1420/1670rpm. Type:EM-

3330- 3C S/N: 201 

SolarpPanel Maximum power 260W 

Tachometer Tachometer 20713A 

Rectifier (for 3phase) PE-5310-5A 

Measuring instrument 

Company Yalong: YL195 

Company Rohde & Schwarz 

RTH1002 

Load (resistor) 3.3kΩ (variable) 

Capacitor (excitation cap) 10uf ±5%, 350-400VAC 

Super capacitor bank 2.640mF, 450V 

Power supply 
Power Electronics Universal 

SupplyMod: AEP-1/EV 

Booster 

Capacitor : 470uf 450v*3 

Inductor: 1.8mH 

5ADiode: FR205 

Digital oscilloscope GWInstek GDS-2074A, 60Mhz 

 

 
Fig. 8.  Experimental model setup for the hybrid power system. 

After ample study, an MG set was taken as a prototype for 
WECS based entirely on the experimental model. A squirrel 
cage induction motor machine generated power and a 
permanent magnet DC machine was chosen to emulate the 
wind turbine in order to investigate the wind turbine non-linear 
performance. For the analysis of the output power of SCIG, the 
motor operated at variable speed. The aim is to experimentally 
investigate and control the hybrid power system, which is 
based on WECS and PV through MPPT. The model setup is 
shown in Figure 8. The WECS was operated with a DC-DC 
converter connected to the SCIG rectified output. The PV was 
operated with a DC-DC converter connected to the panel 
output in order to analyze output factors, i.e. power, voltage, 
and current. To get the succeeding power values a resistive 
load was connected as dummy load. 

IV. RESULTS AND DISCUSSION 

The experimental results of the hybrid wind/PV power 
system under different scenarios and conditions are discussed 
below. 

Figure 9 shows the bus bar output voltages when both 
sources are available and ON (hybrid state). Maximum output 
voltage of 320V is generated by the hybrid system on the bus 
bar by maintaining the common bus voltage and Figure 10 
shows the output current of the hybrid system (0.408A). Figure 
11 shows the maximum output power (130.56W) generated by 
the proposed hybrid system when maintaining common bus 
power sharing. 

 

 
Fig. 9.  Bus bar output voltage. 

 
Fig. 10.  Hybrid output current. 

 
Fig. 11.  Hybrid output power. 

Figure 12 shows the voltages before and after the boost 
converter with respect to generator speed (rpm), when WECS 
us ON and PV is OFF. It is clearly shown from the output 
results that at 37s a high rectified output voltage of 280V is 
generated while out of the DC/DC boost converter the output 
voltage received is 340V. The speed of the generator was 
660rpm when these maximum voltages were recorded. So the 
voltages of WECS before boost converter was augmented by 



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www.etasr.com Mustafa et al.: Experimental Investigation and Control of a Hybrid (PV-Wind) Energy Power System 

 

21% by using the designed boost converter, working on the 
principle of P&O algorithm. 

 

 
Fig. 12.  Output voltages before and after boost w.r.t speed. 

Figure 13 shows the voltage before and after the boost 
converter along with the power after the boost converter 
(44.71W). It is clearly shown from the output results that at 
31s, the maximum generated output voltage of the solar panel 
is 34V while at out of DC/DC boost converter the output 
voltage received is 324V. The voltage of the solar source 
before the boost converter is maximized by using the designed 
buck-boost converter working on the principles of genetic 
algorithm. The results are summarized in Table IV. 

 

 
Fig. 13.  PV output vs boost converter output. 

TABLE IV.  RESULT SUMMARY 

Hybrid PV-Wind Power System 

S.No. Wind Rpm PV Irradiation Voltage Power 

1 ON 660 OFF N/A 340 100.3 

2 OFF N/A ON 9.164 324 44.71 

3 ON 621 ON 9.164 320 130.56 

 

V. CONCLUSION 

The achieved experimental results show the below 
mentioned conclusions, which can be extracted from this study. 
At present, standalone wind and PV systems are globally 
supported on a relatively large-scale but are not able to give 
consistence energy. The hybrid system based on Wind/PV is a 
smart scheme for the utilization of the emergent substitute and 
renewable sources of energy. This study shows a hybrid 
WECS/PV system connected to a DC bus with MPPT. The 
analysis and results of the proposed experimental model 
signified the output power produced by the hybrid scheme 

which can supply continuous power with improved consistency 
in comparison with a single power source system. The results 
of the system in three different conditions were analyzed. 

• When the WECS system was ON and the PV was OFF, the 
characteristic of wind energy conversion system, exhibited 
maximum power of 100.3W. 

• When the WECS system was OFF and the PV was ON, the 
PV module characteristic exhibited maximum power of 
44.71W. 

• When both sources were ON (hybrid state), the maximum 
power generated by the hybrid system was 130.56W by 
maintaining the common bus voltages and power-sharing. 

The hardware-based experimental model of the hybrid 
system proved to provide fruitful results under varying 
environmental conditions. In the proposed model, two boost 
converters are separately used for PV and wind having MPPT 
functions. The converters were based on the P&O and Genetic 
MPPT algorithms, which transferred maximum power to the 
DC bus from the WECS and the PV cell. 

REFERENCES 

[1] S. P. LakshmanRao, C. P. Kurian, B. K. Singh, and V. Athulya Jyothi, 

"Simulation and Control of DC/DC Converter for MPPT Based Hybrid 

PV/Wind Power System," International Journal of Renewable Energy 

Research, vol. 4, no. 3, pp. 801–809, Sep. 2014. 

[2] Y. S. Rao, A. J. Laxmi, and M. Kazeminehad, "Modeling and Control of 

Hybrid Photovoltaic Wind Energy Conversion System," International 

Journal of Advances in Engineering & Technology, vol. 3, no. 2, pp. 

192–201, May 2012. 

[3] N. A. Ahmed, A. K. Al-Othman, and M. R. AlRashidi, "Development of 

an efficient utility interactive combined wind/photovoltaic/fuel cell 

power system with MPPT and DC bus voltage regulation," Electric 

Power Systems Research, vol. 81, no. 5, pp. 1096–1106, May 2011, 

https://doi.org/10.1016/j.epsr.2010.12.015. 

[4] S. Mahesar et al., "Power Management of a Stand-Alone Hybrid 

(Wind/Solar/Battery) Energy System: An Experimental Investigation," 

International Journal of Advanced Computer Science and Applications, 

vol. 9, no. 6, Jan. 2018, https://doi.org/10.14569/IJACSA.2018.090631. 

[5] M. Muralikrishna and V. Lakshminarayana, "Hybrid (solar and wind) 
energy systems for rural electrification," ARPN Journal of Engineering 

and Applied Sciences, vol. 3, no. 5, pp. 50–58, Oct. 2008. 

[6] Y. Chen, Y. Liu, S. Hung, and C. Cheng, "Multi-Input Inverter for Grid-

Connected Hybrid PV/Wind Power System," IEEE Transactions on 

Power Electronics, vol. 22, no. 3, pp. 1070–1077, May 2007, 

https://doi.org/10.1109/TPEL.2007.897117. 

[7] M. Hussain, M. H. Baloch, A. H. Memon, and N. K. Pathan, "Maximum 

Power Tracking System Based on Power Electronic Topology for Wind 

Energy Conversion System Applications," Engineering, Technology & 

Applied Science Research, vol. 8, no. 5, pp. 3392–3397, Oct. 2018, 

https://doi.org/10.48084/etasr.2251. 

[8] B. M. Shagar, S. Vinod, and S. Lakshmi, "Design of DC - DC converter 

for hybrid wind solar energy system," in 2012 International Conference 

on Computing, Electronics and Electrical Technologies (ICCEET), 

Kumaracoil, India, Mar. 2012, pp. 429–435, https://doi.org/10.1109/ 

ICCEET.2012.6203805. 

[9] M. H. Baloch, J. Wang, and G. S. Kaloi, "Stability and nonlinear 

controller analysis of wind energy conversion system with random wind 

speed," International Journal of Electrical Power & Energy Systems, 

vol. 79, pp. 75–83, Jul. 2016, https://doi.org/10.1016/j.ijepes.2016.01. 

018. 

[10] M. Pucci and M. Cirrincione, "Neural MPPT Control of Wind 

Generators With Induction Machines Without Speed Sensors," IEEE 

Transactions on Industrial Electronics, vol. 58, no. 1, pp. 37–47, Jan. 

2011, https://doi.org/10.1109/TIE.2010.2043043. 



Engineering, Technology & Applied Science Research Vol. 11, No. 1, 2021, 6781-6786 6786 
 

www.etasr.com Mustafa et al.: Experimental Investigation and Control of a Hybrid (PV-Wind) Energy Power System 

 

[11] R. Cárdenas, R. Peña, J. Clare, and P. Wheeler, "Analytical and 

Experimental Evaluation of a WECS Based on a Cage Induction 

Generator Fed by a Matrix Converter," IEEE Transactions on Energy 

Conversion, vol. 26, no. 1, pp. 204–215, Mar. 2011, https://doi.org/ 

10.1109/TEC.2010.2083666. 

[12] A. Kadri, H. Marzougui, A. Aouiti, and F. Bacha, "Energy management 

and control strategy for a DFIG wind turbine/fuel cell hybrid system 

with super capacitor storage system," Energy, vol. 192, Feb. 2020, Art. 

no. 116518, https://doi.org/10.1016/j.energy.2019.116518. 

[13] O. Erdinc, B. Vural, and M. Uzunoglu, "A wavelet-fuzzy logic based 

energy management strategy for a fuel cell/battery/ultra-capacitor hybrid 

vehicular power system," Journal of Power Sources, vol. 194, no. 1, pp. 

369–380, Oct. 2009, https://doi.org/10.1016/j.jpowsour.2009.04.072. 

[14] T. R. Ayodele, A. S. O. Ogunjuyigbe, and B. E. Olateju, "Improving 

battery lifetime and reducing life cycle cost of a PV/battery system using 

supercapacitor for remote agricultural farm power application," Journal 

of Renewable and Sustainable Energy, vol. 10, no. 1, Jan. 2018, Art. no. 

013503, https://doi.org/10.1063/1.4999780.