Microsoft Word - ETASR_V11_N6_pp7846-7852


Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7846-7852 7846 
 

www.etasr.com Hussain et al.: Design and Analysis of a Dual Rotor Multiphase Brushless DC Motor for its Application … 

 

Design and Analysis of a Dual Rotor Multiphase 

Brushless DC Motor for its Application in Electric 

Vehicles 
 

Mujtaba Hussain 

Department of Electrical Power Engineering 
U.S.-Pakistan Center for Advanced Studies in Energy 
National University of Sciences and Technology 

Islamabad, Pakistan 
mujtaba.hussein@gmail.com 

Abasin Ulasyar 

Department of Electrical Power Engineering 
U.S.-Pakistan Center for Advanced Studies in Energy 
National University of Sciences and Technology 

Islamabad, Pakistan 
abasin@uspcase.nust.edu.pk 

Haris Sheh Zad 

Department of Mechanical & Manufacturing Engineering 
Pak-Austria Fachhochshule Institute of Applied Sciences and 

Technology 

Haripur, Pakistan 
haris.shehzad@fcm3.paf-iast.edu.pk 

Abraiz Khattak 

Department of Electrical Power Engineering 
U.S.-Pakistan Center for Advanced Studies in Energy 

National University of Sciences and Technology 

Islamabad, Pakistan 
abraiz@uspcase.nust.edu.pk 

Shibli Nisar 

Military College of Signals 

National University of Sciences and Technology 

Islamabad, Pakistan 

shiblinisar@mcs.edu.pk 

Kashif Imran 

Department of Electrical Power Engineering 

U.S.-Pakistan Center for Advanced Studies in Energy 

National University of Sciences and Technology 

Islamabad, Pakistan 
kashifimran@uspcase.nust.edu.pk 

 

Abstract-The main objective of this paper is to study the effect of 

phase numbers in the dual rotor Brushless DC (BLDC) motor for 

its application in Electric Vehicles (EVs). The performance of two 

novel 5-, and 7-phase dual rotor BLDC motors is compared 

against the standard 3-phase dual rotor BLDC motor. The 

proposed motors combine the positive characteristics of 

multiphase BLDC motor and the dual rotor BLDC motor thus 

achieving better fault tolerance capability, high power density, 

and less per phase stator current. Finite Element Method (FEM) 

was used to design the 3-, 5-, and 7-phase dual-rotor BLDC 
motors. The design parameters and operating conditions are kept 

the same for a fair comparison. The stator current and torque 

performance of the proposed motors were obtained with FEM 

simulation and were compared with the standard 3-phase dual 

rotor BLDC motor. It is possible to use low power rating power 

electronics switches for the proposed motor. The simulation 
results also validate low torque ripples and high-power density in 

the proposed motors. Finally, the fault analysis of the designed 

motors shows that the fault tolerance capability increases as the 

phase number increases. 

Keywords-dual rotor; Brushless DC (BLDC); Electric Vehicle 

(EV); multiphase; Finite Element Method (FEM) 

 

I. INTRODUCTION  

Electric Vehicles (EVs) are the future of road 
transportation. Extensive research has been conducted on the 
drive system of EVs to provide low-cost and energy-efficient 
solutions. The electric motor is an integral part of its propulsion 
system along with the transmission system, the power 
electronics, and the battery [1]. The basic requirements of the 
electric motor for EV applications include high torque and 
power density, varied speed range (high speed cruising and low 
speed crawling), high efficiency over wide torque and speed 
ranges, wide constant power operation region, high intermittent 
overload capability, and high reliability and robustness [2-6]. 
The main advantages of the Brushless DC (BLDC) motor are 
its small size, the absence of rotor copper losses due to yhe 
absence of rotor windings, and its low maintenance cost [7]. 
The BLDC motor offers high efficiency, high power, and 
torque density, but the conventional BLDC motor topologies 
do not provide all the requirements for EV application [8-10]. 

The dual-rotor BLDC machine promises high torque 
density and high efficiency. This motor consists of an outer 
rotor, an inner rotor, and a stator between them. In other words, 
two separate motors share the same stator nested between them 

Corresponding author: Abasin Ulasyar 



Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7846-7852 7847 
 

www.etasr.com Hussain et al.: Design and Analysis of a Dual Rotor Multiphase Brushless DC Motor for its Application … 

 

[11-12]. Since both sides of the stator are used as compared to 
single rotor Permanent Magnet (PM) BLDC, this structure 
improves the torque density. The topology reduces the copper 
quantity, which in turn reduces the winding resistance. Thus, 
the copper losses are reduced, and efficiency is improved. The 
reduced copper usage also cuts down the cost [13-15]. 

The next important requirement for PM BLDC machines 
used in EV applications is fault tolerance which is the ability of 
a system to continue working even if a fault occurs. The fault-
tolerant capability of the PM BLDC motors can be enhanced 
by increasing the number of stator phases (more than three-
phase). In a multiphase PM BLDC drive system, increasing the 
phase number also increases the number of power electronic 
switches while it reduces the converter rating required per 
phase [16-17]. The multiphase PM BLDC motors have low 
torque ripple and high torque density as compared to the three-
phase electric motors [18-20]. It is now evident that dual-rotor 
PM BLDC and multiphase PM BLDC topologies offer unique 
advantages for EV application. These two topologies can be 
combined to get the positive characteristics of multiphase PM 
BLDC machines and dual-rotor PM BLDC machines. 

In our research work, two dual rotor BLDC motors with 5, 
and 7 phases are designed for EV application. These motors are 
fed with square wave currents and have trapezoidal back EMF 
waveform unlike the sinusoidal PMSM motors. The 
characteristics of these two motors are compared against the 
standard 3-phase dual rotor BLDC motor. They combine the 
positive characteristics of the dual rotor and multiphase BLDC 
motors, thus achieving less per phase stator current, high power 
and torque density, and better fault tolerance capability. The 
main contributions of the current paper are: 

• Two new dual rotor multiphase BLDC motors as 5-, and 7-
phase are designed to drive an EV. The characteristics of 
these motors are compared with the standard 3-phase dual 
rotor BLDC motor. Finite Element Method (FEM) based 
two-dimensional models of the motors were developed with 
the JMAG Designer. 

• Load and no-load analysis of the three designed motors 
were performed.  

• Fault analysis of the three motors is provided to compare 
their fault tolerance. Open circuit faults, high-impedance 
faults, and demagnetization of the permanent magnets are 
studied. 

II. ANALYTICAL STUDY 

The main design parameters of the BLDC motor are the 
diameter of the armature, the stack length, and the air-gap 
length, through which the energy conversion process is 
completed. The calculation of these three design parameters is 
a fundamental step in any electric motor design. BLDC motor’s 
electromagnetic loading comprises of the specific electrical 
loading and the specific magnetic loading. These loads define 
torque, efficiency, and other mechanical characteristics of the 
motor. Even though the motors in this study have two rotors, 
the design of any BLDC motor starts with the general sizing 
equation. The sizing equation gives the relationship between 
the main design parameters and the electromagnetic load of the 

dual-rotor BLDC motor. The main design specifications of the 
dual-rotor BLDC motor are derived as follows. 

���	 � 	11. �	. 
�. ��. 
 ������� . ����� . ��    (1) 
where ���	is the apparent power, � is the stator’s stack length, 
D is the armature’s diameter, 
�  is the specific magnetic 
loading, and �� is the specific electrical load. The rated speed 
of the motor represented by	��	and �	 is a constant which 
depends on the pole arc of the motor.  

The BLDC motor having trapezoidal back EMF is modeled 
using the equivalent circuit shown in Figure 1. The voltage of 
the single phase can be derived as: 

�� � ���� � �� 	����� �� � !�    (2) 
where �� is the phase voltage, �� is the phase resistance, �� is 
the phase inductance, !� is the generated back EMF, and �� is 
the phase current.  

The generated back EMF and torque constant are functions 
of the relative rotor position. The voltage equation for multiple 
phases based on the back EMF is expressed as: 

"#
##
$���%⋮⋮�' ()

))
* � 	+�� 0 … 00 �% … 0⋮0 ⋮0 ⋱ ⋮⋯ �'0 "##

#$���%⋮⋮�'()
))* � ��� "##

#$���%⋮⋮�'()
))* � "##

#$!�!%⋮⋮!'()
))*    (3) 

 
Fig. 1.  Equivalent circuit of the n-phase BLDC motor. 

For single phase, the expression for the current is derived as 
a function of supplied voltage, phase inductance, and back 
EMF as: 

��� �� �	 �1�� 22�%% � �%4 5 3���� � ∅89��52!�: � !%: � !4: ; (4) 
where <� is the rotational speed, 8	is the pole pair number, 
and ∅	is the induced flux. The phase inductance is considered 
constant as the relative rotor position does not affect it. The 
following equation shows phase inductances BLDC motor: 

 



Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7846-7852 7848 
 

www.etasr.com Hussain et al.: Design and Analysis of a Dual Rotor Multiphase Brushless DC Motor for its Application … 

 

�� � ��� 5 = �% � �%% 5 = 
. 

. 

. �' � �'' 5 =    (5) 
where = is the mutual inductance, �' is the phase inductance 
for the n-phase and �'' is the self-inductance. From (3) and 
(5), the equation for phase voltages can be rewritten as: 

"#
##
$���%⋮⋮�' ()

))
* � 	+�� 0 … 00 �% … 0⋮0 ⋮0 ⋱ ⋮⋯ �'0 "##

#$���%⋮⋮�'()
))* � +

�� 0 … 00 �% … 0⋮0 ⋮0 ⋱ ⋮⋯ �'0
��� "##
#$���%⋮⋮�'()

))* � "##
#$!�!%⋮⋮!'()

))*    (6) 
The back EMF of the motor depends on rotor speed, rotor 

relative position, magnetic field intensity, and the number of 
turns. For a n-phase BLDC motor, the phase angle difference is 
(360/n) for each phase of the back EMF. So, the back EMF of 
each phase is: 

"##
#$!�!%⋮⋮!'()

))* � 	
"#
###
#$ >?@�A >?@ 
A 5	 �B' �⋮⋮>?@ CA 5	 �B' 	�� 5 1 D()

)))
)* . <    (7) 

In (7), the back electromotive force constant of one phase 
of n-phase BLDC motor is represented by >?@. The per phase 
output torques are derived as: 

"#
##
$E�E%⋮⋮E'()

))
* � 	

"#
###
#$ >F@�A >F@ 
A 5	 �B' �⋮⋮>F@ CA 5	 �B' 	�� 5 1 D()

)))
)* .

"#
##
$G�G%⋮⋮G'()

))
*H�
    (8) 

where >F@ is the torque constant of one phase of the n-phase 
BLDC motor. The total electromagnetic torque is given as: E� � 	 E� �	E% � ⋯ � E'    (9) 

III. DUAL ROTOR MULTIPHASE BLDC MOTOR DESIGN  

A. Structure of the Dual Rotor BLDC Motor 

Figure 2 represents the cross-section of the 2D CAD model 
of a dual rotor BLDC motor. The motor consists of a stator 
sandwiched between two (outer and inner) rotors. The magnets 
of both rotors are polarized in the same direction. The flux 
generated by the outer magnets goes through the outer teeth of 
the stator and the flux driven by the inner magnets goes 
through the inner teeth of the stator. This structure enables the 
motor to have low overall volume and improved torque 
density. With this structure, high torque to volume ratio is 
obtained, which is critical for EV applications. In the designed 
dual-rotor multiphase BLDC motor, full-pitched concentrated 

windings are used. This winding configuration reduces the 
requirement of greater stator slot numbers and reduces the use 
of copper.  

 

 
Fig. 2.  Structure of the proposed dual rotor BLDC motor. 

B. Determination of Motor Power 

The first step in any motor design is to determine the motor 
toque and the nominal speed. Two parameters define the motor 
dimensions, motor radius and stack length. The required power 
to drive the vehicle can be deduced as [21]: 8�� I JKL28�, 8�, 84;    (10) 
where 8� is the maximum power of the motor when the vehicle 
achieves maximum speed, 8�	is the maximum power of the 
motor when the vehicle is at highest gradient, and 84 is the 
maximum power of the motor when the vehicle achieves 
maximum acceleration. 8�, 8� and 84 are defined by (11), (12) 
and (13) respectively: 

8� � 	 NO�P1Q�RS 
JTU	 � 	VWXNOY 	��.�Z �    (11) 
8� � 	 N[1Q�RS 
JTU	\]^���_ � JT	^�����_ � VWXN[Y	��.�Z �    (12) 
84 �	 �1Q���RS C	`J N�Y�a�� � JTU N��.Z b� � VWXN�c��.�Z∗�.Z b�D    (13) 

where e� is the initial velocity, e��_ is the maximum velocity, e�	 is the final velocity, and `  is the mass conversion 
coefficient of the vehicle.  

The maximum speed ���_ of the motor is calculated as: 
���_ � 	 NO�P∗��c���Bf     (14) 

The nominal speed �� is related to maximum speed as: ���_	 � 	g��    (15) 
where g is the coefficient of constant power meter. Increasing 
the value of g  will increase the generated torque. Its value 
ranges between 2 and 4. A large size power converter is needed 
to achieve a greater value of g. 



Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7846-7852 7849 
 

www.etasr.com Hussain et al.: Design and Analysis of a Dual Rotor Multiphase Brushless DC Motor for its Application … 

 

C. Machine Design and Comparison 

To study the effect of different phase numbers on the 
performance of motors, three different BLDC (3-phase, 5-
phase, and 7-phase) motors were designed. To allow a fair 
comparison of the three motors, similar materials were used 
and most of the geometric parameters were kept the same. The 
three motors were analyzed with FEM. Table I shows the 
design parameters of the three dual rotor BLDC motors. The 
cross sections of the simulation models for the three motors are 
shown in Figure 3. 

 

(a) 

 

(b) 

 

(c) 

 

Fig. 3.  Cross section of the simulation models. (a) 3-phase dual rotor 
motor, (b) 5-phase dual rotor motor, (c) 7-phase dual rotor motor. 

TABLE I.  DESIGN PARAMETERS  

Designed Motors 3- Ph 5- Ph 7- Ph 

Number of poles (p) 20 20 20 

Number of turns  35 35 35 

Number of slots 27 40 63 

Outer diameter(mm) 110 110 110 

Stack length (mm) 50 50 50 

Current density (A/mm
2
)) 5 5 5 

Rated speed 900rpm 900rpm 900rpm 

Magnetic loading (T) 0.8 0.8 0.8 

Magnets NdFeB NdFeB NdFeB 
 

 

IV. NO LOAD OPERATION 

In dual rotor BLDC motor, two independent flux loops are 
formed in the outer and inner air gaps as displayed in Figure 1. 
The flux flows from one magnet in the outer rotor through the 
outer air gap to the teeth of the outer stator. Following the core 
of the outer stator, the flux flows back to the opposite polarity 

of the magnet and thus completes a loop. In a similar fashion, a 
flux loop is created in the lower air gap between the inner rotor 
and the stator. A different amount of flux is generated in each 
air gap and two independent back EMFs are generated in each 
stator. At no-load conditions, no current flows in the armature 
winding, and a magnetic field is generated by the permanent 
magnet. The no-load characteristics of the motor are obtained 
by running the motor without input current. Cogging torque is 
generated due to the interaction of magnets and coils at no load. 
The cogging torques of the three designed motors were 
compared. The conventional three-phase BLDC motor 
demonstrated a greater cogging torque as compared to the two 
proposed motors. Furthermore, the 7-phase dual rotor BLDC 
motor indicated a reduction in cogging torque than the 5-phase 
dual rotor BLDC motor.  

 

 
Fig. 4.  Cogging torque of the 3-phase BLDC motor. 

 
Fig. 5.  Cogging torque of the 5-phase BLDC motor. 

 
Fig. 6.  Cogging torque of the 7-phase BLDC motor. 

C
o
g
g
in
g
 T
o
rq
u
e
 (
N
m
)

C
o
g
g
in
g
 T
o
rq
u
e
 (
N
m
)

C
o
g
g
in
g
 T
o
rq
u
e
 (
N
m
)



Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7846-7852 7850 
 

www.etasr.com Hussain et al.: Design and Analysis of a Dual Rotor Multiphase Brushless DC Motor for its Application … 

 

V. LOAD OPERATION 

To analyze the dual rotor multi-phase motors under load 
conditions, they were driven by a trapezoidal current source. A 
logic commutation was developed for each motor [22]. The 
interaction of permanent magnets and the magnetic field of the 
stator coils produce torque. For an n-phase dual rotor BLDC 
motor, one phase is positively energized, another phase is 
negatively energized, and the remaining phases are not 
energized.  

 

(a) 
 

(b)
 

Fig. 7.  Stator winding configuration: (a) 5-phase motor (b) 7-phase motor. 

As shown in Figure 8, each phase of the n-phase BLDC 
motor is star-connected using 2n switches, where n is the 
number of phases. Since all three dual rotor BLDC motors are 
designed with the same electric and magnetic loading, the per 
phase rms current of the three-phase motor is the largest. As 
shown in Figure 9, the peak value of the 3-phase motor is 86A, 
of the 5-phase motor is 45A, and of the 7-phase motor is 32A.  

 

 
Fig. 8.  Winding diagram of the n-phase BLDC motor. 

 
Fig. 9.  Stator phase current waveforms. 

Figures 10-12 show the wave forms of the steady state 
output electromagnetic torques of the three motors. The torque 
ripples of the 3-phase motor are the highest, whereas the torque 
ripples are reduced with increasing number of phases. 
However, the torque ripples of the 5-phase motor can be 
considered satisfactory. Hence, a phase number greater than 5 
is only necessary to reduce the stator current.  

 

 
 

Fig. 10.  Torque waveform of the 3-phase motor. 

 
 

Fig. 11.  Torque waveform of the 5-phase motor. 

 
 

Fig. 12.  Torque waveform of the 7-phase motor. 

C
u
rr
e
n
t 
(A
)

T
o
rq
u
e
 (
N
m
)

T
o
rq
u
e
 (
N
m
)

T
o
rq
u
e
 (
N
m
)



Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7846-7852 7851 
 

www.etasr.com Hussain et al.: Design and Analysis of a Dual Rotor Multiphase Brushless DC Motor for its Application … 

 

VI. FAULT ANALYSIS 

This section analyzes the transient process of the three 
designed dual rotor BLDC motors under various fault 
conditions. The performance of the three motors under various 
short and open circuit faults was analyzed. Figure 13 shows the 
comparison of the average output torque of each motor under 
different faults. The Figure shows either an open circuit fault or 
short circuit faults by phase number. To simulate these faults, a 
fault was introduced at certain time using switches. At the time 
of the fault, there was a sudden dip in the average torque and 
the torque ripples were increased.  

 

 
Fig. 13.  Average torque under various open or short circuit fault conditions. 

High impedance faults occur due to broken strands of the 
motor winding. The most common type is the high resistance 
fault. This fault was simulated using extra resistance in series 
with the phase winding. The value of this resistance is obtained 
from: 

��_�f� � 	 ��H	h ���'�N4�if � ��'�     (16) 
where j defines the percentage of the broken wires. Tables II-
IV compare the effect of this fault on the three motors. 
Increasing the phase number makes the motor more prone to 
broken strand faults. 

TABLE II.  HIGH IMPEDANCE FAULT CONDITION IN 3-PHASE MOTOR 

Condition Average torque Percentage of normal torque 

Normal condition 30 100% 

20% Broken strands 21.708 72.36% 

35% Broken strands 20.319 67.3% 

65% Broken strands 14.469 48.23% 

TABLE III.  HIGH IMPEDANCE FAULT CONDITION IN 5-PHASE MOTOR 

Condition Average torque Percentage of normal torque 

Normal condition 30 100% 

20% Broken strands 26.41 88.04% 

35% Broken strands 23.54818966 76.8% 

65% Broken strands 20.15 67.17% 

TABLE IV.  HIGH IMPEDANCE FAULT CONDITION IN 7-PHASE MOTOR 

Condition Average torque Percentage of normal torque 

Normal condition 30 100% 

20% Broken strands 28.43 84.76% 

35% Broken strands 26.02 86.73% 

65% Brokens strands 23.72 79.06% 

 

Extreme temperature and high electrical loading can cause 
demagnetization of the BLDC motors, decreasing the average 
output torque. The designed motors were studied under 
different demagnetization conditions. When all magnets were 
demagnetized by 4%, the average torque decreased by 12.7%, 
8.3%, and 6.6% for the 3-phase, 5-phase, and 7-phase BLDC 
motors respectively.  

VII. COMPARISON WITH THE AVAILABLE LITERATURE 

The combination of the characteristics of the dual rotor and 
multiphase permanent motors is available in literature for 
Permanent Magnet Synchronous Motors (PMSM) [23-24]. In 
[23], a dual-rotor PMSM was designed, a motor with sinusoidal 
back EMF, to get high torque density and good fault tolerance 
capability. The performance and fault tolerance of the same 
dual-rotor five phase PMSM is investigated in [24].  

To the best of our knowledge, no literature is available with 
regard to the dual-rotor multiphase BLDC motors. In the 
current research work, two dual rotor BLDC motors with 5 and 
7 phases were designed for EV application. These motors were 
fed with square wave currents having trapezoidal back EMF 
waveforms unlike the sinusoidal back EMF in PMSM motors. 
The characteristics of the two proposed motors were compared 
against the standard 3-phase dual rotor BLDC motor. The 
designed motors have the advantages of the dual rotor and 
multiphase motors, thus achieving less per phase stator current, 
high power and torque density, and better fault tolerance 
capability. 

VIII. CONCLUSION 

Considering the requirements of a high torque EV, two new 
dual rotor BLDC motors were designed and studied in this 
paper. The dual-rotor PM BLDC motor promises high torque 
density and high efficiency. This machine consists of an inner 
rotor, an outer rotor, and a stator between the two rotors. Three 
motors: 3-phase, 5-phase, and 7-phase have been designed and 
FEM was utilized to analyze their performance. The main 
design parameters and materials are preliminarily decided by 
standard methods. Analytical modeling of the multiphase 
BLDC motor has been presented. The performance of the 5- 
and 7-phase dual rotor BLDC motors has been evaluated under 
load and no-load conditions and the results were compared 
with the standard 3-phase dual rotor BLDC motor. 

To allow a fair comparison, most of the design parameters 
and operating conditions of the motors were kept the same with 
the ones of the base motor. The number of stator slots for each 
motor has been determined by the phase number. The cogging 
torque and back EMF waveforms were obtained at no load. 
Average torque and stator current waveforms were obtained at 
loaded conditions. The results show that increasing the phase 
number decreases phase current. This enables the use of low 
rating power electronic switches. The output torque can also be 
increased per RMS current for the same volume of the motor. 
Torque ripples also decreased as the number of phases 
increased. Finally, fault analysis of the three motors has been 
performed to analyze their performance under fault conditions. 
It was found that the increased phase number makes the motor 
more fault tolerant and increases reliability.  



Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7846-7852 7852 
 

www.etasr.com Hussain et al.: Design and Analysis of a Dual Rotor Multiphase Brushless DC Motor for its Application … 

 

REFERENCES 

[1] P. Zheng, Y. Liu, Y. Wang, and S. Cheng, "Magnetization analysis of 
the brushless DC motor used for hybrid electric vehicle," IEEE 
Transactions on Magnetics, vol. 41, no. 1, pp. 522–524, Jan. 2005, 

https://doi.org/10.1109/TMAG.2004.838746. 

[2] J. A. Sanguesa, V. Torres-Sanz, P. Garrido, F. J. Martinez, and J. M. 
Marquez-Barja, "A Review on Electric Vehicles: Technologies and 

Challenges," Smart Cities, vol. 4, no. 1, pp. 372–404, Mar. 2021, 
https://doi.org/10.3390/smartcities4010022. 

[3] K. T. Chau, C. C. Chan, and C. Liu, "Overview of Permanent-Magnet 
Brushless Drives for Electric and Hybrid Electric Vehicles," IEEE 
Transactions on Industrial Electronics, vol. 55, no. 6, pp. 2246–2257, 

Jun. 2008, https://doi.org/10.1109/TIE.2008.918403. 

[4] W. Cai, X. Wu, M. Zhou, Y. Liang, and Y. Wang, "Review and 
Development of Electric Motor Systems and Electric Powertrains for 

New Energy Vehicles," Automotive Innovation, vol. 4, no. 1, pp. 3–22, 
Feb. 2021, https://doi.org/10.1007/s42154-021-00139-z. 

[5] A. Eldho Aliasand and F. T. Josh, "Selection of Motor foran Electric 
Vehicle: A Review," Materials Today: Proceedings, vol. 24, pp. 1804–

1815, Jan. 2020, https://doi.org/10.1016/j.matpr.2020.03.605. 

[6] T. A. Zarma, A. A. Galadima, and M. A. Aminu, "Review of Motors for 
Electric Vehicles," Journal of Scientific Research and Reports, pp. 1–6, 

Oct. 2019, https://doi.org/10.9734/jsrr/2019/v24i630170. 

[7] M. Yildirim, H. Kurum, D. Miljavec, and S. Corovic, "Influence of 
Material and Geometrical Properties of Permanent Magnets on Cogging 

Torque of BLDC," Engineering, Technology & Applied Science 
Research, vol. 8, no. 2, pp. 2656–2662, Apr. 2018, https://doi.org/ 

10.48084/etasr.1725. 

[8] Z. Q. Zhu and D. Howe, "Electrical Machines and Drives for Electric, 
Hybrid, and Fuel Cell Vehicles," Proceedings of the IEEE, vol. 95, no. 

4, pp. 746–765, Apr. 2007, https://doi.org/10.1109/JPROC.2006.892482. 

[9] T.-Y. Lee, M.-K. Seo, Y.-J. Kim, and S.-Y. Jung, "Motor Design and 
Characteristics Comparison of Outer-Rotor-Type BLDC Motor and 

BLAC Motor Based on Numerical Analysis," IEEE Transactions on 
Applied Superconductivity, vol. 26, no. 4, pp. 1–6, Jun. 2016, 

https://doi.org/10.1109/TASC.2016.2548079. 

[10] M. Dahbi, S. Doubabi, A. Rachid, and D. Oulad-Abbou, "Performance 
evaluation of electric vehicle brushless direct current motor with a novel 

high-performance control strategy with experimental implementation," 
Proceedings of the Institution of Mechanical Engineers, Part I: Journal 

of Systems and Control Engineering, vol. 234, no. 3, pp. 358–369, Mar. 
2020, https://doi.org/10.1177/0959651819854562. 

[11] Y. Li, D. Bobba, and B. Sarlioglu, "Design and Optimization of a Novel 
Dual-Rotor Hybrid PM Machine for Traction Application," IEEE 

Transactions on Industrial Electronics, vol. 65, no. 2, pp. 1762–1771, 
Feb. 2018, https://doi.org/10.1109/TIE.2017.2739686. 

[12] B. V. R. Kumar and K. S. Kumar, "Design of a new Dual Rotor Radial 
Flux BLDC motor with Halbach array magnets for an electric vehicle," 
in International Conference on Power Electronics, Drives and Energy 

Systems, Trivandrum, India, Dec. 2016, pp. 1–5, https://doi.org/ 
10.1109/PEDES.2016.7914552. 

[13] Y.-H. Yeh, M.-F. Hsieh, and D. G. Dorrell, "Different Arrangements for 
Dual-Rotor Dual-Output Radial-Flux Motors," IEEE Transactions on 
Industry Applications, vol. 48, no. 2, pp. 612–622, Mar. 2012, 

https://doi.org/10.1109/TIA.2011.2180495. 

[14] A. Dalal and P. Kumar, "Design, Prototyping, and Testing of a Dual-
Rotor Motor for Electric Vehicle Application," IEEE Transactions on 

Industrial Electronics, vol. 65, no. 9, pp. 7185–7192, Sep. 2018, 
https://doi.org/10.1109/TIE.2018.2795586. 

[15] P. Pisek, B. Stumberger, T. Marcic, and P. Virtic, "Design Analysis and 
Experimental Validation of a Double Rotor Synchronous PM Machine 
Used for HEV," IEEE Transactions on Magnetics, vol. 49, no. 1, pp. 

152–155, Jan. 2013, https://doi.org/10.1109/TMAG.2012.2220338. 

[16] G. Boztas, M. Yildirim, and O. Aydogmus, "Design and Analysis of 
Multi-Phase BLDC Motors for Electric Vehicles," Engineering, 

Technology & Applied Science Research, vol. 8, no. 2, pp. 2646–2650, 
Apr. 2018, https://doi.org/10.48084/etasr.1781. 

[17] M. Salehifar, R. S. Arashloo, J. M. Moreno-Equilaz, V. Sala, and L. 
Romeral, "Fault Detection and Fault Tolerant Operation of a Five Phase 

PM Motor Drive Using Adaptive Model Identification Approach," IEEE 
Journal of Emerging and Selected Topics in Power Electronics, vol. 2, 

no. 2, pp. 212–223, Jun. 2014, https://doi.org/10.1109/JESTPE.2013. 
2293518. 

[18] L. Parsa and H. A. Toliyat, "Five-phase permanent-magnet motor 
drives," IEEE Transactions on Industry Applications, vol. 41, no. 1, pp. 
30–37, Jan. 2005, https://doi.org/10.1109/TIA.2004.841021. 

[19] H. Lu, J. Li, R. Qu, D. Ye, and Y. Lu, "Fault-Tolerant Predictive Control 
of Six-Phase PMSM Drives Based on Pulsewidth Modulation," IEEE 
Transactions on Industrial Electronics, vol. 66, no. 7, pp. 4992–5003, 

Jul. 2019, https://doi.org/10.1109/TIE.2018.2868264. 

[20] E. Levi, "Multiphase Electric Machines for Variable-Speed 
Applications," IEEE Transactions on Industrial Electronics, vol. 55, no. 
5, pp. 1893–1909, May 2008, https://doi.org/10.1109/TIE.2008.918488. 

[21] Y. Yuan, W. Meng, X. Sun, and L. Zhang, "Design Optimization and 
Analysis of an Outer-Rotor Direct-Drive Permanent-Magnet Motor for 
Medium-Speed Electric Vehicle," World Electric Vehicle Journal, vol. 

10, no. 2, Jun. 2019, Art. no. 16, https://doi.org/10.3390/wevj10020016. 

[22] C. Oprea, C. Martis, and B. Karoly, "Six-phase brushless DC motor for 
fault tolerant electric power steering systems," in International Aegean 

Conference on Electrical Machines and Power Electronics, Bodrum, 
Turkey, Sep. 2007, pp. 457–462, https://doi.org/10.1109/ACEMP.2007. 

4510543. 

[23] Y. Li, J. Zhao, Z. Chen, and X. Liu, "Investigation of a Five-Phase Dual-
Rotor Permanent Magnet Synchronous Motor Used for Electric 

Vehicles," Energies, vol. 7, no. 6, pp. 3955–3984, Jun. 2014, 
https://doi.org/10.3390/en7063955. 

[24] J. Zhao, X. Gao, B. Li, X. Liu, and X. Guan, "Open-Phase Fault 
Tolerance Techniques of Five-Phase Dual-Rotor Permanent Magnet 
Synchronous Motor," Energies, vol. 8, no. 11, pp. 12810–12838, Nov. 

2015, https://doi.org/10.3390/en81112342.