Academic literature on the topic 'Switched Capacitor Multilevel Inverter'

This study proposed a Multilevel Inverter (MLI) topology that generates a high number of output voltage levels with a reduced number of components. The proposed topology was configured with symmetrical, asymmetrical, and hybrid configurations. Each configuration generates a different level of output voltage. In parallel to the increased output level, the output voltage has a better output quality (i.e., a lower percentage of total harmonic distortion), simple design and less demanding operation.

Thesis (MScEng (Electrical and Electronic Engineering))--University of Stellenbosch, 2005.<br>A switching state substitution must be developed that will make use of both single-phase redundancies and three-phase redundancies in the flying-capacitor topology. Losses should be taken into consideration and the algorithm must be designed for implementation on the existing PEC33 system, with on-board DSP (TMS320VC33) and FPGA (EP1K50QC208). The specific power-electronics application is a medium-voltage active filter. Existing capacitor voltage stabilisation schemes are investigated and a capacitor-voltage based algorithm is developed that is investigated in parallel with the Donzel and Bornard algorithm. Detailed simulation models are built for the evaluation of both existing and the proposed algorithm. Three-phase control is also evaluated. Timing analysis of the proposed algorithm shows that a DSP-only implementation of the proposed capacitor-based solution is not feasible. Detail design of the digital controller hereof is implemented in VHDL. Finally, a four-cell controller is fitted into the FPGA. A scalable hardware sorting architecture is utilised.

This thesis presents a new DC/AC inverter circuit which is based on a switched-capacitor circuit topology with reduced components (power switch and capacitor) count for low power applications. The proposed circuit has distinct features of both voltage boost-up and near sinusoidal (multi-level/staircase) AC output voltage. The main idea is to utilise a simple circuit technique called resonant-based Double Switch Single Capacitor Switched-Capacitor (DSSC SCC) with variable duty cycle Pulse Width Modulation (PWM) control technique in such a way that multi-level voltage can be realised across a capacitor. In order to show the superiority of the applied technique, comparisons with other techniques/circuits configurations are presented. The circuit technique can significantly reduce the number of multiple stages of switched-capacitor circuit cells of the recent switched-capacitor multi-level inverter topology. The proposed inverter (with integrated DSSC SCC technique) can generate a line-frequency with 13-levels near sinusoidal AC output voltage with low total harmonics distortion. The output voltage can be achieved with the least number of components use and only a single DC source is used as an input. The proposed inverter topology is also reviewed against other inverter-based switched-capacitor circuit topology and the well-known multi-level inverter topology. The proposed inverter has shown a tremendous reduction in the total harmonics distortion and circuit component count in comparison with the recent Switched-Capacitor Boost multi-level inverter and the classical Cascaded H-Bridge multi-level inverter. Mathematical analysis shows the design of the proposed inverter and PSPICE simulation result to verify the design is also presented. The practical experiment implementation of the proposed system is presented and proves the correct operation of the proposed inverter topology by showing consistency between simulation results and practical results.

Die vorliegende Arbeit befasst sich mit einem detaillierten Vergleich von Mehrpunkt-Schaltungstopologien mit zentralem Gleichspannungszwischenkreis für den Einsatz in Mittelspannungsanwendungen. Im Rahmen dieser Untersuchungen wird die 3-Level Neutral Point Clamped Spannungswechselrichter Schaltungstopologie (3L-NPC VSC) sowohl mit Multilevel Flying Capacitor (FLC) als auch mit Multilevel Stacked Multicell (SMC) Schaltungstopologien verglichen, wobei unter Verwendung von aktuell verfügbaren IGBT-Modulen Stromrichterausgangsspannungen von 2.3 kV, 4.16 kV und 6.6 kV betrachtet werden. Neben der grundlegenden Funktionsweise wird die Auslegung der aktiven Leistungshalbleiter und der passiven Energiespeicher (Zwischenkreiskondensatoren, Flying Capacitors) für die untersuchten Stromrichtertopologien dargestellt. Unter Berücksichtigung verschiedener Modulationsverfahren und Schaltfrequenzen werden Kennwerte für den Oberschwingungsgehalt in der Ausgangsspannung und dem Ausgangsstrom vergleichend evaluiert. Die installierte Schalterleistungen, die Halbleiterausnutzungsfaktoren, die Stromrichterverlustleistungen sowie die Verlustleistungsverteilungen werden für die betrachteten Stromrichtertopologien detailliert gegenübergestellt und bewertet<br>The thesis deals with a detailed comparison of voltage source converter topologies with a central dc-link energy storage device for medium voltage applications. The Three-Level Neutral Point Clamped Voltage Source Converter (3L-NPC VSC) is compared with multilevel Flying Capacitor (FLC) and Stacked Multicell (SMC) Voltage Source Converters (VSC) for output voltages of 2.3 kV, 4.16 kV and 6.6 kV by using state-of-the-art 6.5 kV, 3.3 kV, 4.5 kV and 1.7kV IGBTs. The fundamental functionality of the investigated converter topologies as well as the design of the power semiconductors and of the energy storage devices (Flying Capacitors and Dc-Link capacitors) is described. The installed switch power, converter losses, the semiconductor loss distribution, modulation strategies and the harmonic spectra are compared in detail

The Queensland University of Technology (QUT) allows the presentation of theses for the Degree of Doctor of Philosophy in the format of published or submitted papers, where such papers have been published, accepted or submitted during the period of candidature. This thesis is composed of ten published /submitted papers and book chapters of which nine have been published and one is under review. This project is financially supported by an Australian Research Council (ARC) Discovery Grant with the aim of investigating multilevel topologies for high quality and high power applications, with specific emphasis on renewable energy systems. The rapid evolution of renewable energy within the last several years has resulted in the design of efficient power converters suitable for medium and high-power applications such as wind turbine and photovoltaic (PV) systems. Today, the industrial trend is moving away from heavy and bulky passive components to power converter systems that use more and more semiconductor elements controlled by powerful processor systems. However, it is hard to connect the traditional converters to the high and medium voltage grids, as a single power switch cannot stand at high voltage. For these reasons, a new family of multilevel inverters has appeared as a solution for working with higher voltage levels. Besides this important feature, multilevel converters have the capability to generate stepped waveforms. Consequently, in comparison with conventional two-level inverters, they present lower switching losses, lower voltage stress across loads, lower electromagnetic interference (EMI) and higher quality output waveforms. These properties enable the connection of renewable energy sources directly to the grid without using expensive, bulky, heavy line transformers. Additionally, they minimize the size of the passive filter and increase the durability of electrical devices. However, multilevel converters have only been utilised in very particular applications, mainly due to the structural limitations, high cost and complexity of the multilevel converter system and control. New developments in the fields of power semiconductor switches and processors will favor the multilevel converters for many other fields of application. The main application for the multilevel converter presented in this work is the front-end power converter in renewable energy systems. Diode-clamped and cascade converters are the most common type of multilevel converters widely used in different renewable energy system applications. However, some drawbacks – such as capacitor voltage imbalance, number of components, and complexity of the control system – still exist, and these are investigated in the framework of this thesis. Various simulations using software simulation tools are undertaken and are used to study different cases. The feasibility of the developments is underlined with a series of experimental results. This thesis is divided into two main sections. The first section focuses on solving the capacitor voltage imbalance for a wide range of applications, and on decreasing the complexity of the control strategy on the inverter side. The idea of using sharing switches at the output structure of the DC-DC front-end converters is proposed to balance the series DC link capacitors. A new family of multioutput DC-DC converters is proposed for renewable energy systems connected to the DC link voltage of diode-clamped converters. The main objective of this type of converter is the sharing of the total output voltage into several series voltage levels using sharing switches. This solves the problems associated with capacitor voltage imbalance in diode-clamped multilevel converters. These converters adjust the variable and unregulated DC voltage generated by renewable energy systems (such as PV) to the desirable series multiple voltage levels at the inverter DC side. A multi-output boost (MOB) converter, with one inductor and series output voltage, is presented. This converter is suitable for renewable energy systems based on diode-clamped converters because it boosts the low output voltage and provides the series capacitor at the output side. A simple control strategy using cross voltage control with internal current loop is presented to obtain the desired voltage levels at the output voltage. The proposed topology and control strategy are validated by simulation and hardware results. Using the idea of voltage sharing switches, the circuit structure of different topologies of multi-output DC-DC converters – or multi-output voltage sharing (MOVS) converters – have been proposed. In order to verify the feasibility of this topology and its application, steady state and dynamic analyses have been carried out. Simulation and experiments using the proposed control strategy have verified the mathematical analysis. The second part of this thesis addresses the second problem of multilevel converters: the need to improve their quality with minimum cost and complexity. This is related to utilising asymmetrical multilevel topologies instead of conventional multilevel converters; this can increase the quality of output waveforms with a minimum number of components. It also allows for a reduction in the cost and complexity of systems while maintaining the same output quality, or for an increase in the quality while maintaining the same cost and complexity. Therefore, the asymmetrical configuration for two common types of multilevel converters – diode-clamped and cascade converters – is investigated. Also, as well as addressing the maximisation of the output voltage resolution, some technical issues – such as adjacent switching vectors – should be taken into account in asymmetrical multilevel configurations to keep the total harmonic distortion (THD) and switching losses to a minimum. Thus, the asymmetrical diode-clamped converter is proposed. An appropriate asymmetrical DC link arrangement is presented for four-level diode-clamped converters by keeping adjacent switching vectors. In this way, five-level inverter performance is achieved for the same level of complexity of the four-level inverter. Dealing with the capacitor voltage imbalance problem in asymmetrical diodeclamped converters has inspired the proposal for two different DC-DC topologies with a suitable control strategy. A Triple-Output Boost (TOB) converter and a Boost 3-Output Voltage Sharing (Boost-3OVS) converter connected to the four-level diode-clamped converter are proposed to arrange the proposed asymmetrical DC link for the high modulation indices and unity power factor. Cascade converters have shown their abilities and strengths in medium and high power applications. Using asymmetrical H-bridge inverters, more voltage levels can be generated in output voltage with the same number of components as the symmetrical converters. The concept of cascading multilevel H-bridge cells is used to propose a fifteen-level cascade inverter using a four-level H-bridge symmetrical diode-clamped converter, cascaded with classical two-level Hbridge inverters. A DC voltage ratio of cells is presented to obtain maximum voltage levels on output voltage, with adjacent switching vectors between all possible voltage levels; this can minimize the switching losses. This structure can save five isolated DC sources and twelve switches in comparison to conventional cascade converters with series two-level H bridge inverters. To increase the quality in presented hybrid topology with minimum number of components, a new cascade inverter is verified by cascading an asymmetrical four-level H-bridge diode-clamped inverter. An inverter with nineteen-level performance was achieved. This synthesizes more voltage levels with lower voltage and current THD, rather than using a symmetrical diode-clamped inverter with the same configuration and equivalent number of power components. Two different predictive current control methods for the switching states selection are proposed to minimise either losses or THD of voltage in hybrid converters. High voltage spikes at switching time in experimental results and investigation of a diode-clamped inverter structure raised another problem associated with high-level high voltage multilevel converters. Power switching components with fast switching, combined with hard switched-converters, produce high di/dt during turn off time. Thus, stray inductance of interconnections becomes an important issue and raises overvoltage and EMI issues correlated to the number of components. Planar busbar is a good candidate to reduce interconnection inductance in high power inverters compared with cables. The effect of different transient current loops on busbar physical structure of the high-voltage highlevel diode-clamped converters is highlighted. Design considerations of proper planar busbar are also presented to optimise the overall design of diode-clamped converters.

MU LT I L E V E L inverters are becoming the preferred choice for medium voltage high power applications. Multilevel inverters have a number of inherent advantages over conventional two level inverters. The output voltage has multiple steps or levels, resulting in reduced dV/dt, which leads to lower electromagnetic interference, making it easier to meet electromagnetic compatibility (EMC) regulations. Multilevel inverters have a much lower effective switching frequency, which leads to a reduction in switching losses. The output voltage of multilevel inverters has a much lower harmonic content. In applications such as power conversion or grid-connection, filters need to be much smaller, or can be eliminated. In motor drive applications, the low harmonic content results in smoother, ripple-free shaft torque. The neutral-point clamped (NPC), cascaded H-bridge (CHB) and flying capacitor (FC) topologies were among the earliest multilevel topologies. NPC topologies require additional clamping diodes to clamp the output to the DC bus midpoint. CHB topologies use a number of isolated DC suplies to generate multilevel output. FC topologies work with a single DC link but use additional floating capacitors. Since then, a number derivatives and improvements to these topologies have been proposed. Topologies with low switch counts are desirable because of the corresponding reduction in system size and cost. A low total component count is also desirable since it results in better reliability. Induction motors in high power applications are often operated in the open-end configuration. Here, the start terminals of the motor phase windings are connected to one three phase inverter, while the end terminals are connected to a second three-phase inverter. The two inverters are typically powered by isolated supplies to prevent the flow of common mode currents through the motor. The open end configuration has a number of advantages It can be used with nearly all high power motors with no need for electrical or mechanical modification, since all six winding terminal are available externally. The two inverters driving the open-end motor are effectively cascaded. As a result, two inverters of lower voltage and power rating can replace a single inverter with higher voltage and power rating. In addition, if one of the inverter fails, it can be bypassed and the system can be operated at reduced power. In many applications such as heating, ventilation and air conditioning (HVAC), the load power is proportional to the cube of the shaft speed, so a 50% reduction in power translates to only 20% reduction in speed, thereby improving overall system reliability. The cascading of inverters also enables multilevel operation, which is exploited for the topologies proposed in this thesis. In the open-end configuration it is important to ensure that both the DC supplies deliver power to the load. Otherwise, power can circulate through the motor windings. In addition, if the two inverters are powered by rectifier supplies, the DC bus of one inverter can charge uncontrollably, resulting in distortion of phase voltages and currents. If DC bus overcharging continues unchecked the DC bus voltage can even exceed the system rating, resulting in permanent damage. This thesis proposes two novel topologies for open-end induction motor drives with low switch counts. Both topologies are powered by two unequal, isolated DC sources having DC voltages in a 3:1 ratio. Multiple levels in the output voltage are obtained using a number of floating capacitors in each phase. Modulation and control schemes are also proposed for both topologies to ensure that DC bus overcharging never occurs, while all the capacitor voltages are kept balanced at their nominal values. The first of these two topologies is a nine level inverter for open end induction motor drives. It consists of two three-level flying capacitor inverters connected to the induction motor in the open end configuration. The two inverters are powered by DC sources of voltage 6VDC/8 and 2VDC/8, which generates an effective phase voltage having nine levels in steps of VDC/8. This topology has only eight switches and two floating capacitors per phase. The space vector structure for this topology is hexagonal, and has 217 space vector locations. A space-vector based formulation is used to determine the pole voltage of the inverter such that DC bus over charging is prevented. In addition, selection of switching states is used to balance the voltages of all floating capacitors. This scheme allows the floating capacitors to be charged up during system startup, thereby eliminating the need for separate pre-charging circuitry. A level-shifted carrier PWM based modulation scheme has been developed, which can be used with both scalar and vector control schemes. The gating signal for switches turning on must be delayed by a small amount (to allow the complementary switch to turn of), failing which current shoot through can occur. This delay is called dead time, during which gate signals to both complementary devices are turned of. Under certain conditions in the flying capacitor topology, the pole voltage can contain large undesirable transients during the dead time which result in phase current distortion, and electromagnetic noise. A novel scheme to eliminate this problem is proposed using a digital state machine approach. The switching state for each subsequent switching interval is determined based on the present switching state such that the pole voltage does not contain a transient, without affecting the phase voltage of the inverter, and irrespective of the current magnitude or direction. The state machine was implemented using an FPGA, and required an additional computation time of just 20ns, which is much smaller than the inverter dead time duration of typically 2.5µs. The second novel topology proposed in this thesis is a seventeen level inverter for an open end induction motor drive. Here, one three-level inverter and one seven-level inverter are connected to the two ends of the induction machine. The three-level inverter is a flying capacitor inverter. The seven-level inverter is a hybrid topology – it consists of an H-bridge cascaded to each phase of a three level flying capacitor inverter. This scheme is also powered by two isolated DC sources in 3:1 ratio with magnitudes 12VDC/16 and 4VDC/16. The effective phase voltage has seventeen levels in steps of VDC/16. This topology has a total of twelve switches and three floating capacitors per phase. The space vector structure for this topology is hexagonal, and has 817 space-vector locations. Space vector analysis was used to determine the pole voltages, and the switching states such that DC bus overcharging is prevented while also balancing the voltages of the floating capacitors. A non-iterative algorithm was developed for determining the switching states, suitable for implementation in digital logic using an FPGA. The scheme is able to charge the all capacitors at startup as well, eliminating the need for separate pre-charging circuits. Hardware prototypes were built for both the topologies described above for experimental verification, and used to drive a three phase 50Hz, 1.5kW, four pole induction motor in V/f control mode. The inverters topologies were built using 1200V, 75A IGBT half-bridge modules (Semikron SKM75GB12T4) with hybrid opto-isolated gate drivers (Mitsubishi M57962). Three phase rectifiers were used to create the asymmetric DC supplies Hall effect sensors were used to sense the DC link and floating capacitor voltages and phase currents (LEM LV20P voltage sensors and LA55 current sensors). Signal conditioning circuitry was built using discrete components. The PWM signals and V/f controller were implemented using a digital signal processor (Texas Instruments TMS320F28335). Synchronous PWM with was used to eliminate sub-harmonics from the phase voltage, and to ensure three-phase and half-wave symmetry. The internal ADC of the DSP was used for sampling all voltages and currents. The remaining digital logic for switch state selection was implemented on a FPGA (Xilinx Spartan3 XC3S200). Dead time functionality was also implemented within the FPGA, eliminating the need for separate dead time hardware. Both topologies were first tested for steady state operation over the full modulation range, and the pole voltages, phase voltages and phase currents were recorded. System startup, and the ability of the controllers to balance all the capacitors at startup was tested next. The capacitor voltages were also observed during sudden loading, by quickly accelerating the motor. Finally, the phenomenon of DC bus overcharging was also demonstrated. These results demonstrate the suitability of the proposed topology for a number of applications, including industrial drives, alternate energy systems, power conversion and electric traction.

MU LT I L E V E L inverters are becoming the preferred choice for medium voltage high power applications. Multilevel inverters have a number of inherent advantages over conventional two level inverters. The output voltage has multiple steps or levels, resulting in reduced dV/dt, which leads to lower electromagnetic interference, making it easier to meet electromagnetic compatibility (EMC) regulations. Multilevel inverters have a much lower effective switching frequency, which leads to a reduction in switching losses. The output voltage of multilevel inverters has a much lower harmonic content. In applications such as power conversion or grid-connection, filters need to be much smaller, or can be eliminated. In motor drive applications, the low harmonic content results in smoother, ripple-free shaft torque. The neutral-point clamped (NPC), cascaded H-bridge (CHB) and flying capacitor (FC) topologies were among the earliest multilevel topologies. NPC topologies require additional clamping diodes to clamp the output to the DC bus midpoint. CHB topologies use a number of isolated DC suplies to generate multilevel output. FC topologies work with a single DC link but use additional floating capacitors. Since then, a number derivatives and improvements to these topologies have been proposed. Topologies with low switch counts are desirable because of the corresponding reduction in system size and cost. A low total component count is also desirable since it results in better reliability. Induction motors in high power applications are often operated in the open-end configuration. Here, the start terminals of the motor phase windings are connected to one three phase inverter, while the end terminals are connected to a second three-phase inverter. The two inverters are typically powered by isolated supplies to prevent the flow of common mode currents through the motor. The open end configuration has a number of advantages It can be used with nearly all high power motors with no need for electrical or mechanical modification, since all six winding terminal are available externally. The two inverters driving the open-end motor are effectively cascaded. As a result, two inverters of lower voltage and power rating can replace a single inverter with higher voltage and power rating. In addition, if one of the inverter fails, it can be bypassed and the system can be operated at reduced power. In many applications such as heating, ventilation and air conditioning (HVAC), the load power is proportional to the cube of the shaft speed, so a 50% reduction in power translates to only 20% reduction in speed, thereby improving overall system reliability. The cascading of inverters also enables multilevel operation, which is exploited for the topologies proposed in this thesis. In the open-end configuration it is important to ensure that both the DC supplies deliver power to the load. Otherwise, power can circulate through the motor windings. In addition, if the two inverters are powered by rectifier supplies, the DC bus of one inverter can charge uncontrollably, resulting in distortion of phase voltages and currents. If DC bus overcharging continues unchecked the DC bus voltage can even exceed the system rating, resulting in permanent damage. This thesis proposes two novel topologies for open-end induction motor drives with low switch counts. Both topologies are powered by two unequal, isolated DC sources having DC voltages in a 3:1 ratio. Multiple levels in the output voltage are obtained using a number of floating capacitors in each phase. Modulation and control schemes are also proposed for both topologies to ensure that DC bus overcharging never occurs, while all the capacitor voltages are kept balanced at their nominal values. The first of these two topologies is a nine level inverter for open end induction motor drives. It consists of two three-level flying capacitor inverters connected to the induction motor in the open end configuration. The two inverters are powered by DC sources of voltage 6VDC/8 and 2VDC/8, which generates an effective phase voltage having nine levels in steps of VDC/8. This topology has only eight switches and two floating capacitors per phase. The space vector structure for this topology is hexagonal, and has 217 space vector locations. A space-vector based formulation is used to determine the pole voltage of the inverter such that DC bus over charging is prevented. In addition, selection of switching states is used to balance the voltages of all floating capacitors. This scheme allows the floating capacitors to be charged up during system startup, thereby eliminating the need for separate pre-charging circuitry. A level-shifted carrier PWM based modulation scheme has been developed, which can be used with both scalar and vector control schemes. The gating signal for switches turning on must be delayed by a small amount (to allow the complementary switch to turn of), failing which current shoot through can occur. This delay is called dead time, during which gate signals to both complementary devices are turned of. Under certain conditions in the flying capacitor topology, the pole voltage can contain large undesirable transients during the dead time which result in phase current distortion, and electromagnetic noise. A novel scheme to eliminate this problem is proposed using a digital state machine approach. The switching state for each subsequent switching interval is determined based on the present switching state such that the pole voltage does not contain a transient, without affecting the phase voltage of the inverter, and irrespective of the current magnitude or direction. The state machine was implemented using an FPGA, and required an additional computation time of just 20ns, which is much smaller than the inverter dead time duration of typically 2.5µs. The second novel topology proposed in this thesis is a seventeen level inverter for an open end induction motor drive. Here, one three-level inverter and one seven-level inverter are connected to the two ends of the induction machine. The three-level inverter is a flying capacitor inverter. The seven-level inverter is a hybrid topology – it consists of an H-bridge cascaded to each phase of a three level flying capacitor inverter. This scheme is also powered by two isolated DC sources in 3:1 ratio with magnitudes 12VDC/16 and 4VDC/16. The effective phase voltage has seventeen levels in steps of VDC/16. This topology has a total of twelve switches and three floating capacitors per phase. The space vector structure for this topology is hexagonal, and has 817 space-vector locations. Space vector analysis was used to determine the pole voltages, and the switching states such that DC bus overcharging is prevented while also balancing the voltages of the floating capacitors. A non-iterative algorithm was developed for determining the switching states, suitable for implementation in digital logic using an FPGA. The scheme is able to charge the all capacitors at startup as well, eliminating the need for separate pre-charging circuits. Hardware prototypes were built for both the topologies described above for experimental verification, and used to drive a three phase 50Hz, 1.5kW, four pole induction motor in V/f control mode. The inverters topologies were built using 1200V, 75A IGBT half-bridge modules (Semikron SKM75GB12T4) with hybrid opto-isolated gate drivers (Mitsubishi M57962). Three phase rectifiers were used to create the asymmetric DC supplies Hall effect sensors were used to sense the DC link and floating capacitor voltages and phase currents (LEM LV20P voltage sensors and LA55 current sensors). Signal conditioning circuitry was built using discrete components. The PWM signals and V/f controller were implemented using a digital signal processor (Texas Instruments TMS320F28335). Synchronous PWM with was used to eliminate sub-harmonics from the phase voltage, and to ensure three-phase and half-wave symmetry. The internal ADC of the DSP was used for sampling all voltages and currents. The remaining digital logic for switch state selection was implemented on a FPGA (Xilinx Spartan3 XC3S200). Dead time functionality was also implemented within the FPGA, eliminating the need for separate dead time hardware. Both topologies were first tested for steady state operation over the full modulation range, and the pole voltages, phase voltages and phase currents were recorded. System startup, and the ability of the controllers to balance all the capacitors at startup was tested next. The capacitor voltages were also observed during sudden loading, by quickly accelerating the motor. Finally, the phenomenon of DC bus overcharging was also demonstrated. These results demonstrate the suitability of the proposed topology for a number of applications, including industrial drives, alternate energy systems, power conversion and electric traction.

Indiana University-Purdue University Indianapolis (IUPUI)<br>This research proposes state-of-the-art multilevel converter topologies and their modulation strategies, the implementation of a conventional flying-capacitor converter topology up to four-level, and a new four-level flying-capacitor H-Bridge converter confi guration. The three phase version of this proposed four-level flying-capacitor H-Bridge converter is given as well in this study. The highlighted advantages of the proposed converter are as following: (1) the same blocking voltage for all switches employed in the con figuration, (2) no capacitor midpoint connection is needed, (3) reduced number of passive elements as compared to the conventional solution, (4) reduced total dc source value by comparison with the conventional topology. The proposed four-level capacitor-clamped H-Bridge converter can be utilized as a multilevel inverter application in an electri fied railway system, or in hybrid electric vehicles. In addition to the implementation of the proposed topology in this research, its experimental setup has been designed to validate the simulation results of the given converter topologies.