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www.etasr.com Bakar et al.: Decentralized Virtual Impedance-based Circulating Current Suppression Control for … 

 

Decentralized Virtual Impedance-based Circulating 

Current Suppression Control for Islanded Microgrids 
 

Afarulrazi Abu Bakar 

Department of Electrical Power Engineering 
Faculty of Electrical and Electronic Engineering 

University Tun Hussein Onn Malaysia 

Johor, Malaysia  
afarul@uthm.edu.my  

Erum Pathan 

Electronic Engineering Department 
Quaid-e-Awam University of Engineering Science and 

Technology 

Nawabshah, Pakistan  
erumasad79@gmail.com  

Mubashir Hayat Khan 

Department of Electrical Power Engineering 
Faculty of Electrical and Electronic Engineering 

University Tun Hussein Onn Malaysia 

Johor, Malaysia  
mubashir.uthm@gmail.com  

Muhammad Ahsan Sadiq 

Department of Electrical Engineering 
Faculty of Engineering & Technology 

University of Poonch Rawalakot 

Poonch, Pakistan  
engr.ahsan@upr.edu.pk 

Muhammad Imran Rabani  

Department of Electrical Contracting & Maintenance 
XERVON 

Saudia Arabia 
mimranbzu@gmail.com  

Sai Babu Goli 

Commissioning Division-COA 
Saudi Electricity Company 

Saudia Arabia 
saibabu27@hotmail.com  

Farheen Pathan 

Department of Telecommunication Engineering 

Mehran University of Engineering and Technology 
Jamshoro, Pakistan 

engrfarheen83@gmail.com 

Muammad Asad Shaikh 

Protection and SAS Commission 

National Grid SA 
Saudi Arabia 

csd_sec@yahoo.com 
 

 

Abstract-Parallel connected inverters in islanded mode, are 

getting momentous attention due to their ability to increase the 

power distribution and reliability of a power system. When there 

are different ratings of Distributed Generation (DG) units, they 

will operate in parallel connection due to different output 

voltages, impedance mismatch, or different phase that can cause 

current to flow between DG units. The magnitude of this 
circulating current sometimes can be very large and damage the 

DG inverters and also cause power losses that affect power-

sharing accuracy, power quality, and the efficiency of the 

Microgrid (MG) system. Droop control, improved droop control, 

and virtual impedance control techniques and modifications in 

the virtual impedance control technique are widely used to 

suppress the circulating current. However, the addition of the 
virtual impedance to each inverter to compensate the output 

impedance is resistive or inductive in nature. The resistive nature 

of the output impedance always causes a certain voltage drop, 

whereas the inductive nature of the output impedance causes 

phase delay for the output voltage. Both problems are addressed 

by the proposed control mechanism in this paper. Negative 

resistance, along with virtual impedance, is utilized in the 

proposed control strategy. The output impedance is to be 

maintained as inductive in nature to achieve good load sharing in 

droop control MGs. The simulation results validate the proposed 

control scheme. 

Keywords-circulating current; droop control; virtual 

impedance; distributed generations; decentralized control 

I. INTRODUCTION  

In a microgrid (MG) system the i-th power electronic 
interface is integrated utilizing different Distributed 
Generations (DGs) in both islanded and grid-connected mode. 
Besides the many advantages of the MG system, it can also 
operate at a plug and play function and as bidirectional energy 
management system [1-3] for continuous power supply. 
However, there are some control issues in MGs, the islanded 
mode of operation in particular may have power quality and 
stability issues. In islanded mode, the suppression of circulating 
current is much needed, because it may cause instability in the 
system. Overheating of the system components can lead the 

Corresponding author: Afarulrazi Abu Bakar



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entire system to failure because large circulating currents flow 
through the inverters. The circulating current is also a 
significant cause of reduction of MGs' transmission efficiency. 
Moreover, the decentralized control mechanism of the DG 
inverters connected in parallel faces more circulating current 
issues than the centralized control mechanism [4-7]. Line 
impedance mismatch in parallel connected inverters is the main 
cause of the generation of circulating currents between the 
inverters and can affect power-sharing among different DGs. 
Voltage output inequalities between DGs connected in parallel 
is another cause of generation of circulating currents. Several 
techniques have been implemented to reduce circulating 
currents. A multicarrier PWM method was implemented on 
parallel two-level converters to suppress the circulating 
currents in [8]. The generation mechanism of circulating 
currents was studied in [9-11] and a mathematical model was 
established for circulating current generation.  

In the islanded (stand-alone) mode of operation, droop 
control is widely used due to its favorable characteristics such 
as simplicity, good active power, and the reactive power 
sharing capability in multiple distribution generation systems 
[12]. Conventional droop control is basically designed for 
inductive transmission lines with primary control level [13] that 
do not need a communication link [14]. Meanwhile, for low 
voltage grids with resistive impedance characteristics, the 
conventional droop control is not able to provide active and 
reactive power-sharing [15-18]. In the presence of local loads 
and large line impedance, MGs face voltage deviation issues 
and that causes an increase in the circulating currents and 
power sharing issues. To fix the voltage deviation problem, the 
conventional droop is required to be modified [19-20]. 
Therefore, the mitigation of the frequency issue is done by 
angle droop control, while voltage regulation and power-
sharing accuracy [20] use Q-U dot droop control. In order to 
create a suppression of the circulating current a multi-loop 
control mechanism for parallel-connected inverter control is 
needed to improve system reliability and adaptability with 
effective utilization of droop capability with voltage and 
current control mechanism [21]. Non-dominated Sorting Sine 
Cosine Algorithm (NSSCA) and Improved Particle Swarm 
Optimization control techniques were used in [22, 23] for MG 
control in order to enhance power quality. In the context of 
circulating current suppression, an impedance mismatch has 
been addressed through adaptive virtual impedance where the 
values change at every instant, inequalities are removed, and 
the circulating current is minimized, hence, the accuracy on 
power-sharing is improved [24-26]. In the presence of local 
loads during an abrupt change in loads, a conventional virtual 
impedance control strategy does not give appropriate results. 
Faster response to load variation can be attained by virtual 
complex impedance [27] to improve power-sharing accuracy. 
One of the methods is by having a coupling inductor to 
overcome the circulating current issue in the voltage source 
converters. Saturation of the coupled inductor may occur when 
the low frequency circulating current is high because the 
coupled inductor is sensitive to low order harmonic contents 
that occur due to the inequalities of the converters. The 
mismatch in line impedance leads the system to inaccurate 
power-sharing in parallel connected inverters with the same 

power rating. An improved droop with voltage drops 
compensator with no load was suggested in [24], while a 
proportional resonant controller was used to ensure system 
stability by reducing the low frequency circulating current. A 
control technique for the suppression of cross circulating 
current based on virtual impedance control was presented in 
[28].  

This paper presents the decentralized virtual impedance-
based control technique for parallel-connected islanded MGs to 
suppress the circulating current. Voltage and current tracking 
are conducted with load changing conditions. The proposed 
controller responded accordingly and mitigated voltage, 
frequency, and power sharing accuracy errors and the 
circulating current was suppressed effectively. The proposed 
control scheme was tested to a multi DG MG system with 
different loads. The conventional droop control was modified 
and implemented with virtual impedance. Moreover, the 
stability of the MG system was within the permissible limits. 

II. DROOP BASED CONTROL METHODS FOR CIRCUILATING 

CURRENT SUPPRESSION  

In Figure 1, an inverter with given voltage impedance 
parameters: open-circuit voltage V<ϕ, output impedance of the 
inverter Z<θ, apparent power (S), and output current of the 
inverter (I), is shown.  

 

  
Fig. 1.  Inverter equivalent circuit. 

The active and reactive powers P and Q in simplified form 
are taken as: 

2

cos( ) cos
o oVV V

P
Z Z

θ φ θ= − −     (1) 

2

sin( ) sin
o oVV V

Q
Z Z

θ φ θ= − −     (2) 

Neglecting output impedance resistance, the above 
equations are further simplified with a same voltage phase 
difference, such as θ = 90o, Z=X, sinϕ=ϕ and cosϕ=1. 

oVV
P

X
φ=     (3) 

( )oV V V
Q

X

−
=     (4) 

From (3) and (4) it is concluded that P and Q are dependent 
on phase difference ϕ and voltage magnitude difference (V-Vo) 
respectively. Subsequently, the control equations with 
frequency voltage droop can be given as: 

mPω ω∗= −     (5) 

V V nQ∗= −     (6) 



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where ω*, V*, n, and m are frequency, voltage, and drop 
coefficients respectively.  

III. VIRTUAL IMPEDANCE ANALYSIS  

Droop control technique has two major flaws: a) it neglects 
the resistive component, which is not practically applicable and 
b) for double-loop control, the control parameters are affected, 
so the load sharing accuracy is not guaranteed. The different 
aspects of output impedance are given below.  

A. Inverter Output Impedance  

Practically, when different DG inverters are connected in 
parallel, the possibility to have the same parameters for each 
DG inverter is significantly less. The difference in the output 
impedance of every unit of the DG inverter causes circulating 
current, which needs to be suppressed. Droop control provides 
wireless control with virtual impedance, as shown in Figure 2. 
Droop characteristics and virtual impedance control technique 
with the transfer function of output impedance are given as: 

2
1

2 2
1 2 2

( )

( ) ( 1)

pi PWM

o

pi PWM pi PWM Pv pi PWM Pv

Ls r K K K s
Z

LCs K K K C rC s K K K K s K K K K

+ +
=

+ + + + +

    (7) 

where K1 and K2 are the current and voltage co-efficients and 
Kpi, Kpv, and KPWM are the proportion parameters and equivalent 
parameters respectively. 

From (7), it is clear that the output impedance is influenced 
by the controller parameters. The virtual impedance shown in 
Figure 3 aims to manipulate the output impedance features. 

 

  

Fig. 2.  Virtual impedance loop control. 

  

Fig. 3.  Virtual impedance implementation. 

B. Resistive Virtual Impedance  

In Figure 4, (7) is plotted for different values of Rvir with 
the condition Zvir = Rvir. The virtual impedance influences the 
output impedance and both are changing accordingly. 

C. Inductive Virtual Impedance 

Equation (7) is plotted in Figure 5 with the different values 
of Lvir for Zvir = Lvir, when the values of output impedance are 
purely inductive. It is clearly shown that the output impedance 
is influenced by the virtual impedance and both are changing 
accordingly. 

 

Fig. 4.  Bode plot Zo with Rvirtual. 

 
Fig. 5.  Phase, frequency, and magnitude plot. 

D. Proposed Negative Resistance Control  

In parallel-connected inverter-based MGs, the mismatch in 
line impedance is covered by virtual impedance. The above 
analysis indicates that the changing virtual impedance changes 
the output impedance. This means that the virtual impedance 
characteristics are manipulated in such a way that the output 
impedance of the parallel-connected DG units in the MGs 
changed according to the demand of the load for accurate load 
sharing. Figures 4 and 5 illustrated that there is a massive drop 
in voltage amplitude and a phase delay while utilizing the 
resistive or inductive virtual impedance. The output impedance 
is changed by adding the inductive virtual impedance. The 
overview of the control scheme is shown in Figure 6. To 
analyze the output impedance, bode plots are shown in Figure 7 
where the parameters for the controller are given in Table I. It 
is clearly shown that the addition of the virtual impedance 
increases the phase when it is compared with Figure 5. The 
change in phase is approximately from 86.96º to 89.99º, which 
is quite significant. It is noticed that the output impedance is 
purely inductive in nature after the addition of the virtual 
impedance. From the above analysis, it can be concluded that 
the improvement in active and reactive power decoupling 
improves the load sharing in parallel connected inverters, and 
the circulating current is also suppressed. 

 

  
Fig. 6.  Proposed virtual impedance control. 



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Fig. 7.  Bode plot of the proposed control technique. 

IV. SIMULATION RESULTS 

The proposed control strategy was built in 
MATLAB/Simulink for two parallel-connected inverters with 
the system parameters given in Table I. The comparison 
between the conventional strategies and the proposed control 
strategy is conducted considering fixed load and sudden change 
in load conditions. Figure 8 shows the MATLAB/Simulink 
model and the sub model of the proposed control system. 

 

(a) 

 
 

 

(b) 

 

Fig. 8.  Simulation (a) two VSC-based inverters system, (b) sub-model of the proposed controller. 

TABLE I.  SYSTEM PARAMETERS 

Parameters Inverter1 Inverter 2 

Voltage amplitude at no load=V* (V) 700 700 

DC Bus Voltage =VDC (V) 400 400 

Active power=P (kW) 450 450 

Reactive power=Q (kVar) 350 350 

Output frequency at no load =f (Hz) 50 50 

Line impedance = Z (Ω) 0.3 + j0.0002 
0.167 + 

j0.00052 

Integral parameter of voltage controller = 

kpi 
2400 2200 

Inverter switching frequency = f (kHz) 20 20 

Droop coefficient frequencies=m,n 
6.5*10-5, 

2.2*10-3 

6.5*10-5, 

2.2*10-3 

Output filter capacitor = C (µF) 30 30 

Output filter inductor resistance =r (Ω) 0.11 0.17 

 

A. Comparison in Fixed Load Conditions 

The fixed load conditions are categorized in three cases: 

• Case 1  

At t=0.5s, conventional droop control is applied to the 
system, as shown in Figure 9. Circulating current, output power 
ratio and output power magnitude difference are shown 
separately for each inverter. 

• Case 2 

After t=1s, improved droop control is applied to the system 
up to t=1.5s. Circulating current, output power ratio, and output 
power magnitude difference are shown separately for each 
inverter (Figure 9). 

• Case 3 

From t=1.5s up to t=2s, the proposed virtual impedance 
control scheme is applied to the system. It is clearly shown in 
Figure 9 that the circulating current is not reduced initially 
when even there is a same voltage for each inverter. The 
circulating current is suppressed only when a voltage drop is 
recompensed by equalizing impedance mismatch in the 



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connected feeders. The output magnitude difference of the 
inverters is separately presented here. When t=0.5s, both DG 
inverters have the same voltage to the load connected to the 
system in convention droop control. The circulating current is 
larger and power distribution deviations are clearly observed 
due to the mismatch in line impedance. From t=1s, by 
implementing the improved droop control the errors due to line 
impedance mismatch are reduced and the circulating current is 
suppressed effectively to some extent. It is clearly shown that 
from t=1.5s to 2s, by implementing the virtual impedance 
control scheme, the mismatch of line impedance is covered 
efficiently, and the circulating current is suppressed. Moreover, 
power-sharing accuracy increased by implementing the 
proposed control scheme. 

B. Comparison in Suddden Load Change 

Implementing the proposed virtual impedance control 
scheme to an MG based on DG inverters connected in parallel, 
the circulating current is suppressed efficiently and the power 
sharing accuracy improves in the case of sudden load change. 
During the sudden load change, the conditions are the 
following: P=450kW and Q=350kVar. It is clearly shown that 
when t=0.5s the system is instable. When the power is reduced 
to 50% from 450kW to 225kW and from 350kVar to 175kVar 
for P and Q respectively, at time t=1.0s, each load is analyzed 
as in condition 2. In condition 3, the power is raised by 20 % as 
of condition 1 at time t= 1.5s. In Figure 10, it is shown that the 
deviation in frequency is in the allowable range and the 
circulating current for each inverter is less than 5% of the rated 
current.  

 

 

 

 

  

Fig. 9.  Comparison of control techniques with different 

schemes for inverters 1 and 2: (a) circulating current, (b) magnitude 

difference, (c) output power ratio. 

Fig. 10.  Simulation results with load change for inverters 1 and 2:  (a) frequency of the 

system, (b) output power ratio, (c) Lvi , (d) circulating current, (e) output power, and (f) Rvi. 

 

V. CONCLUSION 

A circulating current suppressed scheme that utilizes the 
virtual impedance along with improved droop control and 
negative resistance is presented in this paper. The proposed 
control strategy offers decentralized control, which is the most 
stable and reliable among control strategies. Moreover, the use 
of virtual impedance to equalize the output impedance of the 
feeders as purely inductive provides equal power-sharing 
according to the capacity of the inverters connected in parallel 
in the MG system. The simulation results indicate that the 

proposed decentralized virtual impedance control strategy can 
efficiently compensate the voltage drop of the reference voltage 
and suppress circulating currents. The proposed control 
strategy equally shares the load in the case of sudden change in 
connecting loads without having any significant effect on the 
stability of the system. 

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