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Multilevel inverters (MLIs) have drawn much attention in recent years in medium and higher
power applications because of their low switching frequencies and ability to withstand higher
voltages without requiring high voltage rated power devices. The primary benefits of MLIs
are lower electromagnetic interference, lower total harmonic distortion of the output voltage,
higher efficiency and the ability to operate at higher voltages. In general, MLIs can be
classified into diode-clamped MLIs (DC-MLIs), flying capacitor MLIs (FC-MLIs) and
cascaded H-bridge MLIs (CHB-MLIs). DC-MLIs have been utilized in high power AC motor
drives, pumps and mills. FC-MLIs have been used in medium voltage traction drives. CHB MLIs have been used in applications such as reactive power compensation, uninterrupted
power supplies and photovoltaic inverters. DC-MLIs have been much prevalent in the
industrial applications due to their simple structure. However, they require large number of
diodes. On the other hand, FC-MLIs provide more flexibility than DC-MLIs, but require
higher number of floating capacitors. Hence, complicated capacitor voltage balancing
mechanism is required in them. CHB-MLIs avoid the use of diodes or capacitors, but larger
number of isolated DC voltage sources are required to generate higher output voltage levels,
which makes it uneconomical.
In earlier published works related to CHB-MLIs, each H-bridge module was supplied by
separate DC sources. Subsequent works showed that single DC source or a battery can be
used to supply some of the H-bridges of MLI and the remaining H-bridges of MLI can be iv
supplied by capacitors. Such a topology is known as hybrid cascaded MLI (HC-MLI),
wherein the capacitor voltages are maintained constant at desired values.
The methods used for switching HC-MLIs are either based on sinusoidal pulse width
modulation (SPWM) or space vector modulation (SVM) techniques for higher switching
frequencies and staircase modulation technique for fundamental switching frequency. The
switching losses are more and harmonics also appear at higher frequencies in SPWM. The
computational intricacy is considered as a significant drawback of SVM, which limits its
real-time applications. In case of staircase modulation technique, the switching losses are less
but harmonics appear at lower frequencies of the generated output voltage. Several methods
have been reported to selectively eliminate lower order harmonics of HC-MLIs in case of
staircase modulation technique, out of which the selective harmonics elimination PWM
(SHE-PWM) is the most widely used technique. The major complexity associated with SHE PWM method is to solve the non-linear transcendental equations using Newton–Raphson or
mathematical theory of resultant method. These methods are not suitable for solving large
number of switching angles as the degree of polynomials in the equations become high and
it becomes difficult to solve them.
The aforementioned problems can be solved using modern stochastic search techniques
such as genetic algorithm (GA), particle swarm optimization (PSO), whale optimization
(WO), grey wolf optimization (GWO), etc. These optimization methods have many
limitations. The two major limitations related to GA are its premature convergence and weak
local search ability. Unlike GA, PSO has no evolution operators, such as crossover and
mutation. PSO locates nearly optimal solution with a fast convergence speed. However,
increase in number of switching angles in PSO results in increase in complexity of the search v
space and ultimately it is trapped in the local optima of the search domain. In order to take
care of this problem, a local search technique, named as mesh adaptive direct search is
combined with PSO to accelerate the convergence rate and refine the local search of the
algorithm to prevent it being stuck in the local optima. The method thus evolved is named as
modified PSO (MPSO).
WO is a recently developed optimization algorithm, which mimics the social behaviour
of humpback whales. WO has improved feature of exploration due to its rapid position
updating mechanism. However, the encircling mechanism in WO mostly focuses on the
exploration in search domain. Hence, WO has less capability to jump out from local optima,
in case it falls in it. To improve the convergence speed and to avoid local optima stagnation
during encircling mechanism, a local search algorithm, called chaotic search mechanism is
combined with WO. The evolved method is named as modified WO (MWO) in this work.
GWO is one of the recently developed meta-heuristic algorithms, which mimics the
hunting mechanism and leadership hierarchy of grey wolves. The GWO algorithm also
suffers from premature convergence and weak local search ability. In order to take care this
problem, a local search algorithm, called chaotic searching mechanism is combined with
GWO to enhance the rate of convergence and avoid it from being stuck at local optima. The
method thus evolved is known as modified GWO (MGWO).
SHE-PWM technique implemented through MPSO, MWO and MGWO has been used
for synthesizing an eleven-level output voltage of three-phase HC-MLIs in this work. The
capacitor voltage balancing, even at higher modulation indices, has been resolved by
exploiting the redundant switching states of HC-MLI. Finally, the performance of the three phase, eleven-level HC-MLI has been verified through simulation and experimentation in vi
this work. The results obtained through MPSO, MWO and MGWO are compared with the
results obtained through GA, PSO, WO and GWO in terms of convergence rate and harmonic
content. It has been found that MGWO gives improved results in comparison to other
optimization methods discussed in this work.
In order to reduce the number active, passive components and capacitor voltage balancing
issues in HC-MLIs, switched-capacitor multilevel inverters (SC-MLIs) have been evolved
recently. To further improve the SC-MLIs, two new topologies, namely, a 17-level diode
assisted switched-capacitor MLI (DASC-MLI) and a 17-level reduced voltage stress
switched-capacitor MLI (RVSC-MLI) are proposed in this work. These topologies generate
higher output voltages using single DC voltage source and lower number of active and
passive components along with reduced total standing voltage (TSV) and peak inverse
voltage (PIV). The capacitors are periodically charged and discharged without any additional
balancing circuit in DASC-MLI and RVSC-MLI. The performance of the proposed DASC MLI and RVSC-MLI are validated through simulation studies and experimental prototypes |
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