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Smoothing the Power Output of a Wind Turbine 

Group with a Compensation Strategy of Power 

Variation  

Phan Dinh Chung 

Faculty of Electrical Engineering 

The University of Danang-University of Science and Technology  

Danang, Vietnam 
pdchung@dut.udn.vn 

 

 

Abstract-This paper proposes a new scheme to reduce the output 

power variation range of a wind turbine group without an energy 

storage system. This proposal is based on the active power 

compensation principle for each wind turbine. In this research, 

the wind turbine operates in the active power control mode. The 
reference active power is calculated in such a way that it 

compensates for the difference between the average output power 

and the actual output power. To verify and evaluate the proposed 

method, we simulated a group of two 1.5MW-wind turbines in 

the Simulink environment of MATLAB. Simulation results were 

compared to the ones of a wind turbine group without any 

smoothing scheme and the ones of the same group with the 

Exponential Moving Average method. From this comparison, we 

can conclude that with the proposed method, the actual output 

power of the wind turbine group becomes smoother than that of 

the wind turbine group without any smoothing scheme. 

Moreover, the performance of the wind turbine group with the 

proposed method is better than that of the wind turbine group 
with the Exponential Moving Average method. 

Keywords-DFIG; fluctuating compensation; power control; 

smoothing power; wind turbine   

I. INTRODUCTION  

The energy demand has been increased rapidly in many 
developing countries whereas conventional energy resources 
are gradually exhausted [1]. This has boosted the exploiting of 
renewable energy resources such as wind, solar, geothermal, 
etc. to gradually replace fossil fuel-based resources like coal, 
oil, and natural gas. In many countries, wind energy has been 
practically accounted for a substantial rate in electricity 
demand [1]. However, the main drawback of wind turbines or 
wind farms is that they bring a negative impact on the 
connected grid because the output power fluctuates due to the 
natural variation of wind speed [2]. Until now, many useful 
schemes were proposed to reduce the fluctuation in the output 
power of a wind turbine [2-19]. These schemes can be 
generally divided into two groups, energy storage system 
utilization [2-3, 8-13] and storage energy system misutilization 
[2,4-7]. By using an energy storage system as battery, super 
capacitor, etc. [8-13], we can adjust the amount of active power 
charging/discharging from the energy storage system to smooth 
the output power quite easily and hence, wind turbines can 

completely operate on their optimal power points to yield 
maximum available power. However, to obtain this benefit we 
must invest on the storage energy system installation and 
expect expensive operation cost. In contrast with the method of 
the energy storage system utilization, the controller utilization 
is hard to make the wind turbine operate completely on the 
maximum-power-point-tracking curve [2, 4]. Moreover, by 
using the controller, the output power of the wind turbine is 
hardly as smooth as that using the energy storage system. The 
main reason is that it cannot store the redundant electrical 
power to release it as the output power is inadequate. However, 
the misutilization of an energy storage system does not require 
huge investments and maintenance cost. 

For the controller utilization of the wind turbine, some 
methods to smooth the power output of a wind turbine are 
inertia control [7], pitch control [14-17], DC link voltage 
control [18], etc. Utilizing the inertia of the wind turbine can 
cause stress on its mechanical system whereas it is hard to 
respond quickly by using the pitch controller and a large 
amount of wind energy is wasted. In both pitch control and 
inertia methods, an anemometer must be used to provide the 
wind speed variation to the controller [2]. The DC voltage 
control method works on the principal of utilizing the DC link 
of the power converter, which is interfaced to the connected 
grid, as a small storage energy system to charge/discharge a 
small electrical energy amount during its operation interval, 
and hence the voltage on the DC-link is varied and this may 
bring a negative impact on the voltage at the point of common 
connection. Moreover, this method is only applied in wind 
turbines that use a full-scale converter and is hard to implement 
in a Doubly Fed Induction Generator (DFIG) wind turbine 
because of the converter’s small capacity. Another way to 
smooth the output power is the use of the Exponential Moving 
Average (EMA) method to determine the average reference 
signal for the controller. Depending on the smooth factor, this 
method can be either effective or ineffective. It is also noted 
that this method was not only used in the controller of a wind 
turbine but also in the controller of the energy storage system 
[4, 13, 19]. 

The objective of this research is the proposition of a new 
scheme for smoothing the output power of a wind turbine 

Corresponding author: Dinh Chung Phan



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group without an energy storage system. The basis of the 
proposed scheme is to compensate the active power for the 
fluctuation in the output power. To obtain this objective, one 
must calculate the reference power, using it as an input signal 
of the RSC controller, such that it can compensate the variation 
in the actual output power. This scheme is evaluated via 
simulations in the Simulink environment of MATLAB 
software. The simulation results of a wind turbine group with 
the proposed method will be compared to the ones without a 
smoothing method and with the EMA method.  

It is noted that in order to evaluate the performance of the 
methods that smooth the output active power, we will use two 
indices, namely the smoothing function ∆�������	 and the 
electrical energy output of wind turbine group as (1)-(2) [3]: 

∆������� 	 
���� ���
�    (1) 
� 	 
��
�    (2) 

It is desired that the smoothing function ∆������� should be 
smaller in order for the output power to become smoother. 
Moreover, the wind turbine group is always expected to 
withdraw as much electrical energy as possible and hence, a 
preferable method will provide a small value of the smoothing 
function and a high value of output electrical energy. 

II. RESEARCH CONFIGURATION 

In this research, we consider a wind turbine group, as 
shown in Figure 1, in which a DFIG with 1.5MW capacity is 
employed. 

 

 
Fig. 1.  Configuration of the wind turbine group. 

Generally, a DFIG wind turbine system consists of a 3-
blade system, a shaft system, and a DFIG [20]. In the DFIG 
wind turbine, the stator winding is connected directly to the 
grid whereas the rotor winding is interfaced to the grid via a 
back-to-back small capacity converter [21, 22]. This converter 
consists of a Rotor Side Converter (RSC), a Grid Side 
Converter (GSC) and a DC-link. Via the RSC controller, we 
can adjust the output active power of the wind turbine.  

A. Wind Turbine 

The blade system converts wind energy to mechanical 
energy on its shaft. The efficiency of the conversion is 

represented by ����,��, namely power coefficient [8, 23]. This 
coefficient is reliant on both pitch angle � and tip speed ratio � 
[8, 24]: 

� 	 � ����    (3) 
where R is the length of the blade, �� is the rotational velocity 
of the shaft, and ��  the wind velocity at the wind turbine 
location.  

According to [8, 23], the coefficient ����,��	versus the tip 
speed ratio � at different values of � of a typical wind turbine 
is shown in Figure 2(a) [8, 26]. It is easy to see that with a 

constant pitch angle, the power coefficient ����� reaches a 
maximum value at an optimal tip speed ratio. When we keep 
�=0, ����� will reach its maximum value ��� ! at ���� [25]. 
At a wind velocity ��	and rotational velocity of shaft ��,	the 
mechanical power on the wind turbine shaft is defined by [8, 
24]: 

�� 	 "# $%�#���λ,β���(    (4) 
where $ is the density of air at the wind turbine location. 

 

(a) 

 

(b) 

 
Fig. 2.  (a) Power coefficient versus tip speed ratio at different pitch angles 

and (b) mechanical power versus rotor velocity at different wind velocities. 

Obviously, this mechanical power is reliant on the cubic of 
the wind velocity ��. When the wind velocity is over the rated 
value, the wind turbine should be remained at its rated power 
by adjusting the pitch angle � . By contrast, when the wind 
velocity is below the rated value, the pitch angle should be kept 
at a minimum value and the rotor speed should be adjusted so 
that the wind turbine operates at its optimal point 
(����,��� !�. From (3), (4), for �� 	 ��� ! and � 	 ����, we 
obtain [24]: 

�� 	 "# $%�#��� !��( 	 )��������(     (5) 
where: 



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)��� 	 "# $%�*��� !/��(     (6) 
����� 	 ,-./��0     (7) 

When the wind velocity varies, the optimal rotor velocity 

�����  will be varied proportionally (7). Hence, the locus of 
optimal operation point which is named Maximum Power Point 
Tracking (MPPT) curve is computed as in (8). This locus is 
represented in Figure 2(b). 

����� 	 "# $%�#��� !��( 	 )�����(    (8) 
B. Doubly Fed Induction Generator 

A DFIG is principally an asynchronous generator and it 
consists of 2 windings, namely a stator winding and a rotor 
winding. In the 
1 axis system, the rotor side voltage of a 
DFIG is described as [24]: 

2��3 	 ��4��3 5 67� �8�9:�� 5 ��6;7� <
0 >1
1 0 @4��3 5

�AB
AC
D0��E    (9) 

where: 

6 	 A�AB >
AB
AC

    (10) 

; 	 1 >
��

�C
    (11) 

��  is the resistance of rotor winding, 7� , 7�,  and 7� 
represent the inductance of the rotor winding, the stator 
winding, and the magnetizing core respectively, 2��3 and 4��3 

are the rotor voltage and rotor current in the 
1 axis system, �� 
is the flux rotational velocity or angular frequency in the stator 
winding, ; is the slip factor, and �� the voltage magnitude in the 
stator winding terminal. 

The active power output of the DFIG in total is calculated 
as [24, 25]: 

PG 	 PH 5 PI 	 (1 > s)PH    (12) 

where �� is the active power exchanging to grid via the rotor 
side and �� the active power supplying to the connected grid 
via the stator side and in the 
1 axis system. It is defined as 
[24]: 

�� 	
#

(
�� 4�3 	 >

#

(

AB

AC
�� 4�3    (13) 

In the 
1 axis system, the electromechanical torque of the 
DFIG can be calculated as: 

KL 	 >
#

(

AB

AC �C
�� 4�3    (14) 

and the change of the rotational velocity of the rotor shaft in the 
DFIG-wind turbine can be represented by [24]: 

M
�

��
�� 	 K� > KL   (15) 

where M is the inertia constant of the wind turbine system and 
K� the mechanical torque.  

III. THE SCHEME TO SMOOTH THE OUTPUT POWER  

To mitigate the fluctuation in the output power of the wind 
turbine, in this research the wind turbine must be operated in 

the power control mode. To adjust the output active power of 
the wind turbine, we should adjust the 4�3 component because 
by adjusting this component we can accommodate the torque 
(14) and hence the rotor velocity will be changed as in (15). As 
a result, the output active power will approach the desired 
value. In this research, we reuse the structure of RSC and GSC 
and utilize the controllers applied to RSC and GSC in [26]. The 
role of the RSC controller is to control the active power and the 
reactive power output of the wind turbine and the role of the 
GSC controller is to maintain a constant voltage on the DC-link 
and a zero reactive current output. However, the reference 
power of the RSC controller is modified. Principally, it must 
compensate the fluctuation in its actual active power. The 
average output active power of each wind turbine is calculated 
as [8]: 

��N O 	 PQ 	
"
Q 
 ��
�

Q
R     (16) 

where K  is the time interval, � 	 
 ��
�QR  is the electrical 
energy output of each wind turbine in the period T, �� is the 
actual output power of each wind turbine, and ��N O  the 
average active power of each wind turbine in the period T. 

The fluctuation in the output power can be calculated as: 

∆�S� 	 �� > ��N O    (17) 
∆�S�	 varies around zero, it can be either positive or 

negative. When ∆�S� is negative it means that the actual output 
power is lower than the average output power, and hence the 
reference power should be increased. On the contrary, with a 
positive ∆�S�, the actual output power is over the average value 
so the reference power should be reduced. Hence, the power 
reference is defined by (18). Equation (18) indicates that the 
reference power of each wind turbine compensates the 
variation of the actual output power. This is the main idea of 
the proposed method. 

��LT 	 ����� > ∆�S�    (18) 
The reference power of the RSC controller is described in 

Figure 3(a). Figure 3(b) describes the reference power in the 
case of wind turbine using the EMA method [4, 13, 19].  

 

(a) 

 

(b) 

 
Fig. 3.  Reference power for RSC controller: (a) Proposed method and 

(b) EMA method. 

IV. RESULTS AND DISCUSSION 

The Simulink environment in MATLAB software was used 
to simulate a group of two DFIG-wind turbines using the 



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proposed scheme in order to verify it. The details of some 
models are shown in the Appendix. The wind turbine capacity 
is 1.5MW and its power coefficient is described by (19) [23]: 

����,�� 	 0.5176Y""Z[\ > 0.4� > 5^_
N`ab\ 5 0.0068�    (19) 

where: 

1
�8 	

1
� 5 0.008β >

0.035
�( 5 1 

This wind turbine's characteristics are described in Figure 2. 
To simulate the wind turbine system, we assume the wind 
speed data presented in Figure 4. We use the DFIG parameters 
described in detail in [27]. 

 

 
Fig. 4.  Wind velocity data. 

Here, we will compare the simulation results of the wind 
turbine group using the proposed method with the wind turbine 
group without any smoothing scheme (Original) and with the 
wind turbine group using the EMA method. The objective of 
the comparison to the original case is to verify the applicability 
of the proposed method to the wind turbines, whereas the 
comparison to the EMA method is to indicate the benefits of 
the proposed method.  

A. Comparison with the Original Case 

The main objective of this section is to verify and evaluate 
the efficiency of the proposed method. The simulation results 
will be compared to the original case, in which the wind 
turbines do not use any smoothing method or the ∆�S�  in 
Figure 3 is set at zero. The simulation results are shown in 
Figure 5. As can be seen from Figure 5, with the proposed 
method, the wind turbine group has a better performance than 
the original case. As can be seen from Figure 5(a), the variation 
range of the power output is mitigated significantly in 
comparison to the original cage. Clearly, from 50s to 150s, in 
the original case, the output power varies from around 1.5MW 
to 2.1MW whereas with the proposed method, it varies 
between 1.6MW and 2MW. At around 245s, the output power 
is 1.47MW and 1.55MW corresponding to the proposed 
method and the original case. To obtain this power output, the 
amount of compensation power of each wind turbine is 
calculated as shown in Figure 5(b). With the proposed method, 
from 180s to 230s, the actual output power is higher than the 
average output power whereas from 230s to 310s, the actual 
output power is lower than the average output power. To 
compensate this difference, the reference power of each wind 
turbine, which is the input of the RSC controller, is shown in 
Figure 5(c). We can see that, by comparing to the original case, 
the reference power is lower in the period from 180s to 210s 

and it is higher from 215s to 230s. Clearly, the continuous 
curve in Figure 5(c) is a little different to the summation of the 
broken curve in Figure 5(c) and the curve in Figure 5(b). The 
main reason is that the operation point of wind turbines is 
changed due to the reference output power. 

 

(a) 

 

(b) 

 

(c) 

 

(d) 

 

(e) 

 

Fig. 5.  Simulation results with the proposed method and the original case: 

(a) power output, (b) compensation power, (c) reference power, (d) smoothing 
function, and (e) electrical energy. 

Figure 5(d) indicates the smoothing function of two cases. 
Obviously, with the proposed method, the smoothing function 
value is almost lower than that of the original case. At the end 
of the simulation period with the proposed method the 
smoothing function is around 3.58MW whereas with the 
original case it is around 5MW. Therefore, the proposed 
method can be completely utilized to reduce the fluctuation in 
the output power of the wind turbine group. Regarding the 
electrical energy output, Figure 5(e) shows that the proposed 
method makes the electrical energy output of the wind turbine 
group a little lower than that of the original case. However, the 
amount of decrease is insignificant. At the end of the 
simulation interval, the electrical energy output is 0.2025MWh 
and 0.2035MWh for the proposed method and the original case 



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respectively. It means only 1kWh is lost due to the application 
of the proposed method. In conclusion, by using the proposed 
method, the reference power supplying the RSC controller 
compensated the variation of the output active power and hence 
the output active power of the group wind turbine varies with a 
smaller range of that of the original case. It means we can use 
the proposed method to mitigate the variation of the output 
power of the wind turbine group. 

B. Comparison to the EMA Method 

The EMA method was used to smooth the output power of 
the wind turbine [4, 13, 19]. In this research, the EMA method 
is applied to wind turbines operating in the power control mode 
to determine the reference power (Figure 3(b)). The reference 
power is described as: 

��LT��� 	 ��LT�� > K� 5 eY�������� > ��LT�� > K�^	   (20) 
where K is the time period and e is the smoothing factor of 
EMA, 0 f e f 1. 

In this research, we use e=0.5 and T=20s. The simulation 
results are shown in Figure 6. 

 

(a) 

 

(b) 

 

(c) 

 

Fig. 6.  Comparison between the proposed method and the EMA method: 

(a) power output, (b) smoothing function, and (c) electrical energy. 

As can be seen from Figure 6(a), the output power of the 
wind turbine group using the proposed method is obviously 
smoother than that of the EMA method. Around 250s, with the 
EMA method, the output power is deeply reduced in 
comparison with that of the proposed method. By contrast, at 
the 330s, it becomes higher. Hence, the performance of the 
wind turbine group with the EMA method is not better than 
that with the proposed method. Figure 6(b) indicates the 
smoothing function value of the wind turbine group. As can be 
seen from this Figure, the smoothing function value with the 

proposed method is lower than that with the EMA method. At 
the end of the simulation interval, they are around 3.58MW and 
3.62MW for the proposed method and the EMA method 
respectively. Moreover, the electrical energy of the wind 
turbine group with the proposed method is a little higher than 
that with the EMA method. From Figure 6(c), the output 
electrical energy of the wind turbine group with the proposed 
method is 0.2025MWh whereas with the EMA method is 
0.2022MWh at the end of the simulation interval. Therefore, 
the proposed method has a better performance than the EMA 
method.  

V. CONCLUSION 

This research proposed a new scheme to mitigate the 
fluctuation in the output power of a wind turbine group without 
an energy storage system. In this research, the active power 
control mode is used in wind turbines, and the reference active 
power is calculated to compensate the difference between the 
average output power and the actual output power. The 
proposed method is verified and evaluated by in the Simulink 
environment of Matlab. The simulation results of the proposed 
method, the EMA method, and the original case were 
compared. The comparison indicated that when using the 
proposed method, the output power variation of the wind 
turbine group was mitigated significantly, and its performance 
is better than that of the EMA method. 

APPENDIX  

 
General model of the proposed method. 

 
Refference power calculation. 



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Simulation settings. 

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