THD Analysis in Multilevel Inverter Fed Induction Motors Using Particle Swarm Optimization
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This paper presents a novel design for multilevel inverters using particle swarm optimization (PSO) to minimize total harmonic distortion (THD) in induction motors. The study addresses the challenges of harmonics generated by inverters, which can affect motor performance, and compares the proposed method to existing techniques, showing improved results. The authors conclude that PSO enhances inverter control and suggest future exploration of other algorithms and configurations.
![Heena Manhas et al. Int. Journal of Engineering Research and Applications www.ijera.com
ISSN: 2248-9622, Vol. 5, Issue 9, (Part - 1) September 2015, pp.69-72
www.ijera.com 69 | P a g e
THD Analysis in Multilevel Inverter Fed Induction Motors Using
Particle Swarm Optimization
Heena Manhas1
, Baljit Singh2
, Gagandeep Sharma3
M tech Student1
, DAV Institute of engineering and technology, Jalandhar
Assistant professor2
, DAV Institute of engineering and technology, Jalandhar
Assistant professor3
, DAV Institute of engineering and technology, Jalandhar
ABSTRACT
Harmonics measurement of an industrial unit is done to aid the power quality aspects in a typical factory. The
real issues are the harmonics generated by the inverters which affects the induction machine performance.
Several inverters like Voltage Series Inverters, PWM fed Inverters, Multilevel inverters etc. exist in literature.
Amongst all these, multilevel inverters have been very popular due to its several advantages. But there is a
challenge of optimal design of the inverter and optimal selection of pulse width of each level so as to get
minimal Total Harmonic Distortion. For these reasons a novel multilevel inverter design based on Particle
Swarm Optimization is proposed in this paper for obtaining the optimal width of the pulse of each level so as to
get minimal Total Harmonic distortion. The results has been compared to that of the existing techniques and
found to be quite better than the existing ones.
Index Terms— Particle Swarm Optimization, cascaded Multilevel Inverter (CMLI), Induction Motor, Multi-
level Inverter (MLI)
I. INTRODUCTION
In various industrial applications, usually, DC
motors were the work horses for the adjustable Speed
Drives (ASDs) due to their excellent speed and
torque response. But, they have the intrinsic
disadvantage of commutator and mechanical brushes,
which endure wear and tear with the passage of time.
Mostly AC motors are preferred to DC motors,
mostly, an induction motor due to its low cost, low
maintenance, lower weight, higher efficiency,
improved ruggedness and reliability. All these
features make the use of induction motors necessary
in many areas of industrial applications. The
advancement in Power electronics and semi-
conductor technology has encouraged the
development of high power and high speed
semiconductor devices in order to attain a smooth,
continuous and step less variation in motor speed.
Applications of solid state converters/inverters for
adjustable speed induction motor drive are wide
spread in electromechanical systems for a large
spectrum of industrial systems. Modified CSI based
induction motor drive is given by Gopukumar [1].
Multilevel inverter modulation schemes to eliminate
common mode voltage is given by Zhang, 2000.
Modulation schemes for six phase induction motor
are given by Mohapatra [2]. Active harmonic
elimination for multilevel inverters is given by
Tolbert [3]. The inverters are either Current Source
Inverter (CSIs) or Voltage Source Inverters (VSIs).
Current source inverters are widely used for the
application of fully generative induction machine
variable speed drives. An important and attractive
feature of CSI is its good fault protection capability
and the inherent regeneration capability. But, CSI-fed
induction motor suffers from severe torque
pulsations, especially at low speeds, which manifest
themselves in cogging of the shaft. The usual
technique of overcoming such problems in Voltage
Source Inverters (VSIs) is to pulse width modulate
the input voltage waveforms. Pulse width modulated
voltage source inverters are invariably used for
AC/DC/AC conversion to provide a variable ac
voltages to the induction motor. However, inverter
fed induction motor suffers from the presence of
significant amount of harmonics which causes
undesired motor heating, torque pulsation and EMI
[4]. The reduction in harmonics calls for large sized
filters, resulting in increased size and cost of the
system However, the advancements in the field of
power electronics and microelectronics made it
possible to reduce the magnitude of harmonics with
multilevel inverters, in which the number of levels of
the inverters are increased rather than increasing the
size of the filters [5]. The performance of multilevel
inverters will be better than a classical inverter. The
THD for multilevel inverters will be lower than that
of a classical inverter [6].
This paper aims at designing of a multilevel
inverter based on an Improved Particle Swarm
Optimization technique [10] for reduction of
harmonics in induction motor control.
Section 2 describes theory of cascaded multilevel
inverter. Section 3 describes harmonic elimination in
RESEARCH ARTICLE OPEN ACCESS](https://image.slidesharecdn.com/l59016972-150924093912-lva1-app6892/85/THD-Analysis-in-Multilevel-Inverter-Fed-Induction-Motors-Using-Particle-Swarm-Optimization-1-320.jpg)
![Heena Manhas et al. Int. Journal of Engineering Research and Applications www.ijera.com
ISSN: 2248-9622, Vol. 5, Issue 9, (Part - 1) September 2015, pp.69-72
www.ijera.com 70 | P a g e
multi-level inverters. Section 4 introduces our
methodology and discusses the implementation of
our proposed algorithm. Section 5 shows the results
of our approach and finally Section 6 concludes the
paper with a discussion on the future scopes of this
method.
II. POWER TOPOLOGY OF
CASCADE MULTILEVEL
INVERTERS
Cascaded Multilevel Inverter (CMLI) topology
is the most advantageous topology in the family of
multilevel inverters. It needs less number of
components as compared to diode-clamped and
flying capacitors type multilevel inverters. It has
modular structure with easier switching Strategy and
occupies less space [7] - [8].Fig. 1(a) shows the
structure of a single-phase H-bridge cascaded
multilevel converter topology that is used to
synthesize a 2s + 1 staircase output waveform. Fig.
1(b) also shows the staircase voltage waveform
produced by multilevel converters.
Fig.1. (a) Topology of a single-phase cascaded
inverter (b) Staircase output phase voltage
A cascaded H-bridge multilevel converter
comprises of some SDCS. The advantage of this
topology is that the modulation, control, and
protection requirements of each bridge are modular.
It should be pointed out that, unlike the diode-
clamped and flying-capacitor topologies, isolated dc
sources are required for each cell in each phase. The
number of output-phase-voltage levels in a cascade
multilevel inverter is 2s + 1, where s is the number of
SDCSs. To obtain the three-phase configuration, the
outputs of three single-phase cascaded inverters can
be connected in Y or Δ.
III. HARMONIC ELIMINATION IN
MULTILEVEL INVERTER
Harmonics are unwanted current or voltage
[9].They exist at some integer multiple or fraction of
the fundamental frequency. The harmonics orders
and magnitude depend on the inverter topology and
the modulation technique, for example in single
phase VSI, only odd harmonics are present in the
output voltage waveform. The even harmonics are
absent due to the half wave symmetry of the output
voltage harmonics. For three phase VSI, in addition
to the even harmonics triplet (third and multiple of
third harmonics) are also absent. The output voltage
V (t) as in eqn. 1 of the multi-level inverter can be
expressed in Fourier series as:
V (t) = (𝑎 𝑛
∞
𝑛=1 𝑠𝑖𝑛𝑛α+𝑏 𝑛 𝑐𝑜𝑠𝑛𝛼) … (1)
Even harmonics are absent (𝑏 𝑛 =0) due to quarter
wave symmetry of the output voltage and only odd
harmonics are present. The amplitude of the nth
harmonic an is expressed only with the first quadrant
switching angle𝛼1,𝛼2, 𝛼3 …….. 𝛼 𝑚 as shown in
eqn.(2) and (3).
𝑎 𝑛 =
4 𝑉 𝑑𝑐
𝑛𝛱
𝑐𝑜𝑠𝑛𝛼𝑘 …∞
𝑘=1 (2)
0<𝛼1 <𝛼2 <𝛼3 < … 𝛼 𝑚 < π/2 …(3)
For any odd harmonics can be expressed up to kth
term where m is the number of variable
corresponding to switching angle α1 through αm of
the first quadrant. THD expression is shown as in
eqn. (4)
THD=
1
fundamental
…… (4)
= 𝑛𝑡ℎ ℎ𝑎𝑟𝑚𝑜𝑛𝑖𝑐 𝑐𝑜𝑚𝑝𝑜𝑛𝑒𝑛𝑡 2∞
𝑛=1 ]2
IV. PROPOSED METHODOLOGY
Proposed methodology for the problem
discussed in Section 3 is mentioned. The technique
Particle Swarm Optimization for multilevel inverter
has been applied on the induction motor model and
then their performance was compared on the basis of
Total Harmonic Distortion, machine performance etc.
4.1 Particle Swarm Optimization (PSO)
Kennedy and Eberhart [10] first introduced PSO
in 1995 as a new heuristic method. Basically, the
PSO was inspired by the sociological behaviour
associated with swarms such as flocks of birds and
schools of fish. The individuals in the population are
called particles. Each particle is a potential solution
for the optimization problem and tries to search the
best position through flying in a multidimensional
space. The sociological behaviour which is modelled
in the PSO system is used to guide the swarm, hence
probing the most promising areas of search space.
The movement of each particle is governed by the
efficiency of their own previous position and that of
the neighbours. Each particle can be described by two
parameters- position (xi) and velocity (vi), which is
updated by the following rule:
𝑣𝑖 𝑡 + 𝑑𝑡 = 𝑤∗
𝑣𝑖 𝑡 + 𝑐1 𝑟1(𝑝𝑏𝑒𝑠𝑡𝑖(𝑡)) − 𝑥𝑖 𝑡 +
𝑐2 𝑟2(𝑔𝑏𝑒𝑠𝑡𝑖(𝑡)) − 𝑥𝑖 𝑡
𝑥𝑖 𝑡 + 𝑑𝑡 = 𝑥𝑖 𝑡 + 𝑣𝑖 𝑡 𝑑𝑡
Here, pbesti is the best position obtained by
𝑖𝑡ℎ particle and gbest is the best position obtained by
any particle till current iteration. c1, c2 are known as
acceleration vectors whereas r1, r2 are two random
vectors uniformly distributed between “0” and “1”
and w denotes inertial weight.](https://image.slidesharecdn.com/l59016972-150924093912-lva1-app6892/85/THD-Analysis-in-Multilevel-Inverter-Fed-Induction-Motors-Using-Particle-Swarm-Optimization-2-320.jpg)
![Heena Manhas et al. Int. Journal of Engineering Research and Applications www.ijera.com
ISSN: 2248-9622, Vol. 5, Issue 9, (Part - 1) September 2015, pp.69-72
www.ijera.com 72 | P a g e
the update rule of PSO. The best position of each
particle is found out and called pbest and the best of
all pbest is called as gbest.
Fig 6: Simulation results of currents, capacitor
voltage, electromagnetic torque, and rotor speed of
Induction Motor using PSO.
VI. CONCLUSIONS AND FUTURE
SCOPE
PSO (Particle swarm optimization) based
harmonic elimination technique has been applied in
this paper for control of induction motors and the
various simulations has been performed on Simulink.
The results have been shown and it is supposed that
the use of PSO improves the performance and also
the multilevel inverters have an edge over other
designs due to their design simplicity and
performance. In future, other algorithms can be
implemented for the same problem and other
configurations of inverters can be verified. Further,
better objective functions can be considered and
effect of other parameters can be considered in
future.
REFERENCES
[1] Gopukumar K, Biswas SK, Satish Kumar S
and Joseph Vithyanthil. “Modified current
source inverter fed induction motor drive
with reduced torque pulsation”. IEEE Proc.
313(4): 150-164 1984.
[2] Mohapatra. KK, Gopukumar K,
Somashekhar VT and Umanand L. “ A
Modulation scheme for six phase induction
motor with an open-end winding”. 25th
Annual Conference IECON 02, Spain. pp.
810-815 2002.
[3] Zhong DuLeon, M. Tolbert and John N.
Chiasson. “ Active Harmonic Elimination
for Multilevel Converters”. IEEE
Transactions on Power Electronics. 21(2):
459-469 2006.
[4] Shivakumar E.G, Gopukumar K, Sinha S.K
and Ranganathan V.T, “ Space vector PWM
control of dual inverter fed open-end
winding induction motor drive”. IEEE
APEC Conf. 1: 399-405 2006.
[5] Juan Dixon and Luis Mora, “ High-Level
Multi-step Inverter Optimization Using a
Minimum Number of Power Transistors”.
IEEE Transactions on Power Electronics.
21(2): 330-337 2006.
[6] Chunmei Feng and Vassilions G Agelidis, “
On the Comparison of fundamental and high
frequency Carrier based techniques for
multilevel NPC Inverters”. IEEE PES Conf.
2: 520-525 2002.
[7] Jih-Sheng Lai, Fang Zheng Peng,
“Multilevel Converters- A New Breed of
Power Converters”, IEEE Trans. On
Industry Applications, vol. 32, no. 3, pp.
509-517, May/June 1996.
[8] Fang Zheng Peng, Jih-Sheng Lai, et al, “A
Multilevel Voltage-Source Inverter with
Separate DC Sources for Static Var
Generation”, IEEE Trans. on Industry
Applications, vol. 32, no. 5, pp. 1130-1138,
September/October 1996
[9] A. K. Ali Othman “Elimination of
harmonics in multi-level inverter with non-
equal DCsources using PSO”.IEEE conf.
proce EPEPEMC2008.
[10] Kennedy, James. "Particle swarm
optimization." Encyclopedia of Machine
Learning. Springer US, 2010. 760-766.](https://image.slidesharecdn.com/l59016972-150924093912-lva1-app6892/85/THD-Analysis-in-Multilevel-Inverter-Fed-Induction-Motors-Using-Particle-Swarm-Optimization-4-320.jpg)
THD Analysis in Multilevel Inverter Fed Induction Motors Using Particle Swarm Optimization
- 1. Heena Manhas et al. Int. Journal of Engineering Research and Applications www.ijera.com ISSN: 2248-9622, Vol. 5, Issue 9, (Part - 1) September 2015, pp.69-72 www.ijera.com 69 | P a g e THD Analysis in Multilevel Inverter Fed Induction Motors Using Particle Swarm Optimization Heena Manhas1 , Baljit Singh2 , Gagandeep Sharma3 M tech Student1 , DAV Institute of engineering and technology, Jalandhar Assistant professor2 , DAV Institute of engineering and technology, Jalandhar Assistant professor3 , DAV Institute of engineering and technology, Jalandhar ABSTRACT Harmonics measurement of an industrial unit is done to aid the power quality aspects in a typical factory. The real issues are the harmonics generated by the inverters which affects the induction machine performance. Several inverters like Voltage Series Inverters, PWM fed Inverters, Multilevel inverters etc. exist in literature. Amongst all these, multilevel inverters have been very popular due to its several advantages. But there is a challenge of optimal design of the inverter and optimal selection of pulse width of each level so as to get minimal Total Harmonic Distortion. For these reasons a novel multilevel inverter design based on Particle Swarm Optimization is proposed in this paper for obtaining the optimal width of the pulse of each level so as to get minimal Total Harmonic distortion. The results has been compared to that of the existing techniques and found to be quite better than the existing ones. Index Terms— Particle Swarm Optimization, cascaded Multilevel Inverter (CMLI), Induction Motor, Multi- level Inverter (MLI) I. INTRODUCTION In various industrial applications, usually, DC motors were the work horses for the adjustable Speed Drives (ASDs) due to their excellent speed and torque response. But, they have the intrinsic disadvantage of commutator and mechanical brushes, which endure wear and tear with the passage of time. Mostly AC motors are preferred to DC motors, mostly, an induction motor due to its low cost, low maintenance, lower weight, higher efficiency, improved ruggedness and reliability. All these features make the use of induction motors necessary in many areas of industrial applications. The advancement in Power electronics and semi- conductor technology has encouraged the development of high power and high speed semiconductor devices in order to attain a smooth, continuous and step less variation in motor speed. Applications of solid state converters/inverters for adjustable speed induction motor drive are wide spread in electromechanical systems for a large spectrum of industrial systems. Modified CSI based induction motor drive is given by Gopukumar [1]. Multilevel inverter modulation schemes to eliminate common mode voltage is given by Zhang, 2000. Modulation schemes for six phase induction motor are given by Mohapatra [2]. Active harmonic elimination for multilevel inverters is given by Tolbert [3]. The inverters are either Current Source Inverter (CSIs) or Voltage Source Inverters (VSIs). Current source inverters are widely used for the application of fully generative induction machine variable speed drives. An important and attractive feature of CSI is its good fault protection capability and the inherent regeneration capability. But, CSI-fed induction motor suffers from severe torque pulsations, especially at low speeds, which manifest themselves in cogging of the shaft. The usual technique of overcoming such problems in Voltage Source Inverters (VSIs) is to pulse width modulate the input voltage waveforms. Pulse width modulated voltage source inverters are invariably used for AC/DC/AC conversion to provide a variable ac voltages to the induction motor. However, inverter fed induction motor suffers from the presence of significant amount of harmonics which causes undesired motor heating, torque pulsation and EMI [4]. The reduction in harmonics calls for large sized filters, resulting in increased size and cost of the system However, the advancements in the field of power electronics and microelectronics made it possible to reduce the magnitude of harmonics with multilevel inverters, in which the number of levels of the inverters are increased rather than increasing the size of the filters [5]. The performance of multilevel inverters will be better than a classical inverter. The THD for multilevel inverters will be lower than that of a classical inverter [6]. This paper aims at designing of a multilevel inverter based on an Improved Particle Swarm Optimization technique [10] for reduction of harmonics in induction motor control. Section 2 describes theory of cascaded multilevel inverter. Section 3 describes harmonic elimination in RESEARCH ARTICLE OPEN ACCESS
- 2. Heena Manhas et al. Int. Journal of Engineering Research and Applications www.ijera.com ISSN: 2248-9622, Vol. 5, Issue 9, (Part - 1) September 2015, pp.69-72 www.ijera.com 70 | P a g e multi-level inverters. Section 4 introduces our methodology and discusses the implementation of our proposed algorithm. Section 5 shows the results of our approach and finally Section 6 concludes the paper with a discussion on the future scopes of this method. II. POWER TOPOLOGY OF CASCADE MULTILEVEL INVERTERS Cascaded Multilevel Inverter (CMLI) topology is the most advantageous topology in the family of multilevel inverters. It needs less number of components as compared to diode-clamped and flying capacitors type multilevel inverters. It has modular structure with easier switching Strategy and occupies less space [7] - [8].Fig. 1(a) shows the structure of a single-phase H-bridge cascaded multilevel converter topology that is used to synthesize a 2s + 1 staircase output waveform. Fig. 1(b) also shows the staircase voltage waveform produced by multilevel converters. Fig.1. (a) Topology of a single-phase cascaded inverter (b) Staircase output phase voltage A cascaded H-bridge multilevel converter comprises of some SDCS. The advantage of this topology is that the modulation, control, and protection requirements of each bridge are modular. It should be pointed out that, unlike the diode- clamped and flying-capacitor topologies, isolated dc sources are required for each cell in each phase. The number of output-phase-voltage levels in a cascade multilevel inverter is 2s + 1, where s is the number of SDCSs. To obtain the three-phase configuration, the outputs of three single-phase cascaded inverters can be connected in Y or Δ. III. HARMONIC ELIMINATION IN MULTILEVEL INVERTER Harmonics are unwanted current or voltage [9].They exist at some integer multiple or fraction of the fundamental frequency. The harmonics orders and magnitude depend on the inverter topology and the modulation technique, for example in single phase VSI, only odd harmonics are present in the output voltage waveform. The even harmonics are absent due to the half wave symmetry of the output voltage harmonics. For three phase VSI, in addition to the even harmonics triplet (third and multiple of third harmonics) are also absent. The output voltage V (t) as in eqn. 1 of the multi-level inverter can be expressed in Fourier series as: V (t) = (𝑎 𝑛 ∞ 𝑛=1 𝑠𝑖𝑛𝑛α+𝑏 𝑛 𝑐𝑜𝑠𝑛𝛼) … (1) Even harmonics are absent (𝑏 𝑛 =0) due to quarter wave symmetry of the output voltage and only odd harmonics are present. The amplitude of the nth harmonic an is expressed only with the first quadrant switching angle𝛼1,𝛼2, 𝛼3 …….. 𝛼 𝑚 as shown in eqn.(2) and (3). 𝑎 𝑛 = 4 𝑉 𝑑𝑐 𝑛𝛱 𝑐𝑜𝑠𝑛𝛼𝑘 …∞ 𝑘=1 (2) 0<𝛼1 <𝛼2 <𝛼3 < … 𝛼 𝑚 < π/2 …(3) For any odd harmonics can be expressed up to kth term where m is the number of variable corresponding to switching angle α1 through αm of the first quadrant. THD expression is shown as in eqn. (4) THD= 1 fundamental …… (4) = 𝑛𝑡ℎ ℎ𝑎𝑟𝑚𝑜𝑛𝑖𝑐 𝑐𝑜𝑚𝑝𝑜𝑛𝑒𝑛𝑡 2∞ 𝑛=1 ]2 IV. PROPOSED METHODOLOGY Proposed methodology for the problem discussed in Section 3 is mentioned. The technique Particle Swarm Optimization for multilevel inverter has been applied on the induction motor model and then their performance was compared on the basis of Total Harmonic Distortion, machine performance etc. 4.1 Particle Swarm Optimization (PSO) Kennedy and Eberhart [10] first introduced PSO in 1995 as a new heuristic method. Basically, the PSO was inspired by the sociological behaviour associated with swarms such as flocks of birds and schools of fish. The individuals in the population are called particles. Each particle is a potential solution for the optimization problem and tries to search the best position through flying in a multidimensional space. The sociological behaviour which is modelled in the PSO system is used to guide the swarm, hence probing the most promising areas of search space. The movement of each particle is governed by the efficiency of their own previous position and that of the neighbours. Each particle can be described by two parameters- position (xi) and velocity (vi), which is updated by the following rule: 𝑣𝑖 𝑡 + 𝑑𝑡 = 𝑤∗ 𝑣𝑖 𝑡 + 𝑐1 𝑟1(𝑝𝑏𝑒𝑠𝑡𝑖(𝑡)) − 𝑥𝑖 𝑡 + 𝑐2 𝑟2(𝑔𝑏𝑒𝑠𝑡𝑖(𝑡)) − 𝑥𝑖 𝑡 𝑥𝑖 𝑡 + 𝑑𝑡 = 𝑥𝑖 𝑡 + 𝑣𝑖 𝑡 𝑑𝑡 Here, pbesti is the best position obtained by 𝑖𝑡ℎ particle and gbest is the best position obtained by any particle till current iteration. c1, c2 are known as acceleration vectors whereas r1, r2 are two random vectors uniformly distributed between “0” and “1” and w denotes inertial weight.
- 3. Heena Manhas et al. Int. Journal of Engineering Research and Applications www.ijera.com ISSN: 2248-9622, Vol. 5, Issue 9, (Part - 1) September 2015, pp.69-72 www.ijera.com 71 | P a g e 4.2 Modification with PSO of Induction Motor For better search, acceleration vectors c1 and c2 should be retained small, which however decreases the convergence rate and has to be selectively chosen varying from application to application. For a problem having large numbers of local extrema, the values of c1 and c2 should be kept low, so as to increase the chance of finding the global extrema at the cost of convergence time and vice-versa. Similarly, the inertial weight w is adjusted, depending on the amount of influence desired in a particles previous position on its current movement. This optimization algorithm is finally said to converge, when each particle reaches the global best or the preset extremum value of the cost function. V. SIMULATION RESULTS AND DISCUSSION All the simulations were prepared in MATLAB R2013, 2.7GHz processor with 4 GB RAM. The proposed model of Multilevel Inverter fed Induction Motor was designed in Simulink as shown in Fig 2. Figure 2: Complete Design of Multilevel Inverter fed Induction Motor model using PSO Figure 2 shows the complete model of the multilevel inverter fed induction motor, tuned by Particle Swarm optimization. The PSO is employed using MATLAB s-function and is operated for the tuning of firing angles after taking feedback from the calculated THD. Fig. 3 Complete Design of Multilevel Inverter fed Induction Motor model without PSO Fig. 3 shows the complete model of the multilevel inverter fed induction motor, without Particle Swarm optimization. THD analysis is done without using any algorithm. Figure 4: Individual components of H-Bridge Inverter Figure 4 shows the individual H-bridge inverter which is implemented and cascaded using subsystem in the main model. The output of the individual inverters is kept around 8V. Figure 5: Output of Multilevel inverter Figure 5 shows the motor voltage when PSO algorithm is applied and is compared to the reference sine wave. The total Harmonic distortion is found to be 8.03% without using PSO while it comes down to 6.9% when PSO algorithm is applied. Algorithm Without PSO With PSO THD Value (%) 8.03% 6.9% The THD has been taken as the optimization function for the Particle Swarm Optimization. The PSO is implemented by generating random particles in the given range and updating each particle suing
- 4. Heena Manhas et al. Int. Journal of Engineering Research and Applications www.ijera.com ISSN: 2248-9622, Vol. 5, Issue 9, (Part - 1) September 2015, pp.69-72 www.ijera.com 72 | P a g e the update rule of PSO. The best position of each particle is found out and called pbest and the best of all pbest is called as gbest. Fig 6: Simulation results of currents, capacitor voltage, electromagnetic torque, and rotor speed of Induction Motor using PSO. VI. CONCLUSIONS AND FUTURE SCOPE PSO (Particle swarm optimization) based harmonic elimination technique has been applied in this paper for control of induction motors and the various simulations has been performed on Simulink. The results have been shown and it is supposed that the use of PSO improves the performance and also the multilevel inverters have an edge over other designs due to their design simplicity and performance. In future, other algorithms can be implemented for the same problem and other configurations of inverters can be verified. Further, better objective functions can be considered and effect of other parameters can be considered in future. REFERENCES [1] Gopukumar K, Biswas SK, Satish Kumar S and Joseph Vithyanthil. “Modified current source inverter fed induction motor drive with reduced torque pulsation”. IEEE Proc. 313(4): 150-164 1984. [2] Mohapatra. KK, Gopukumar K, Somashekhar VT and Umanand L. “ A Modulation scheme for six phase induction motor with an open-end winding”. 25th Annual Conference IECON 02, Spain. pp. 810-815 2002. [3] Zhong DuLeon, M. Tolbert and John N. Chiasson. “ Active Harmonic Elimination for Multilevel Converters”. IEEE Transactions on Power Electronics. 21(2): 459-469 2006. [4] Shivakumar E.G, Gopukumar K, Sinha S.K and Ranganathan V.T, “ Space vector PWM control of dual inverter fed open-end winding induction motor drive”. IEEE APEC Conf. 1: 399-405 2006. [5] Juan Dixon and Luis Mora, “ High-Level Multi-step Inverter Optimization Using a Minimum Number of Power Transistors”. IEEE Transactions on Power Electronics. 21(2): 330-337 2006. [6] Chunmei Feng and Vassilions G Agelidis, “ On the Comparison of fundamental and high frequency Carrier based techniques for multilevel NPC Inverters”. IEEE PES Conf. 2: 520-525 2002. [7] Jih-Sheng Lai, Fang Zheng Peng, “Multilevel Converters- A New Breed of Power Converters”, IEEE Trans. On Industry Applications, vol. 32, no. 3, pp. 509-517, May/June 1996. [8] Fang Zheng Peng, Jih-Sheng Lai, et al, “A Multilevel Voltage-Source Inverter with Separate DC Sources for Static Var Generation”, IEEE Trans. on Industry Applications, vol. 32, no. 5, pp. 1130-1138, September/October 1996 [9] A. K. Ali Othman “Elimination of harmonics in multi-level inverter with non- equal DCsources using PSO”.IEEE conf. proce EPEPEMC2008. [10] Kennedy, James. "Particle swarm optimization." Encyclopedia of Machine Learning. Springer US, 2010. 760-766.