Five-Phase Inverters with Synchronized PWM

Oleschuk, V.; Profumo, F.; Tenconi, Alberto; Yaroshenko, E.

doi:10.1109/eurcon.2007.4400495

Cited by 16 publications

(23 citation statements)

References 15 publications

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“…16 shows the basic ten large (1, 2, 3, 4, 5, 6, 7, 8, 9, 10) and ten medium (1', 2', 3', 4', 5', 6', 7', 8', 9', 10') switching vectors for a five-phase inverter in accordance with conventional designation (in brackets) of switching state of every switch of the inverter, where "1" corresponds to the switch-on state of the corresponding switch of the upper group of switches of the phases a -e. This control scheme includes also two zero switching states (00000 and 11111), providing zero voltage at the outputs of the inverter. Although total number of available voltage space vectors in five-phase inverter is equal to 32, the using only of the mentioned above 20 vectors (ten large and ten medium active vectors) plus two zero switching sequences allows minimum number of switchings and minimal switching losses, combined with good spectrum of the phase-to-neutral voltage in the linear modulation range [14], [15]. Overmodulation control of five-phase systems can be based on the use of ten large vectors and two zero switching sequences [15].…”

Section: Five-phase Inverters With Synchronized Pwmmentioning

confidence: 99%

“…Although total number of available voltage space vectors in five-phase inverter is equal to 32, the using only of the mentioned above 20 vectors (ten large and ten medium active vectors) plus two zero switching sequences allows minimum number of switchings and minimal switching losses, combined with good spectrum of the phase-to-neutral voltage in the linear modulation range [14], [15]. Overmodulation control of five-phase systems can be based on the use of ten large vectors and two zero switching sequences [15].…”

Section: Five-phase Inverters With Synchronized Pwmmentioning

confidence: 99%

“…19, modulation index m=0.62 in the case of scalar control mode), and to 39 Hz (Fig. 20, m=0.78) [15]. The switching frequency is 2.3 kHz.…”

Section: Five-phase Inverters With Synchronized Pwmmentioning

confidence: 99%

See 2 more Smart Citations

Methods of voltage synchronization in multiphase power conversion systems

Oleschuk

Griva

Profumo

et al. 2008

2008 10th IEEE International Workshop on Advanced Motion Control

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Novel method (methodology) of synchronized pulsewidth modulation (PWM) is powerful instrumentation for elimination of sub-harmonics in the spectra of output voltage of both three-phase and multiphase voltage source inverters. This paper presents examples of dissemination of this new method for control of: a) five-phase inverters; b) six-phase inverters for drive system with symmetrical six-phase induction machine, and c) six-phase inverters for asymmetrical six-phase motor drive. Basic peculiarities of the method have been described. Simulations give a behavior of multiphase drive systems fed by inverters with basic continuous and discontinuous schemes of synchronized PWM, providing quarter-wave symmetry of the phase voltage during the whole control range.

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Section: Five-phase Inverters With Synchronized Pwmmentioning

confidence: 99%

Section: Five-phase Inverters With Synchronized Pwmmentioning

confidence: 99%

See 1 more Smart Citation

Methods of voltage synchronization in multiphase power conversion systems

Oleschuk

Griva

Profumo

et al. 2008

2008 10th IEEE International Workshop on Advanced Motion Control

View full text Add to dashboard Cite

show abstract

“…Although total number of available voltage space vectors in five-phase inverter is equal to 32, the using only of the mentioned above 20 vectors (ten large and ten medium active vectors) plus two zero switching sequences allows minimum number of switchings and minimal switching losses, combined with good spectrum of the phase-to-neutral voltage in the linear modulation range [16], [17]. During overmodulation control of five-phase systems is based on the using of only ten large vectors and two zero switching sequences [17].…”

Section: Pwm Control Of Five-phase Inverters In the Linear Modulationmentioning

confidence: 99%

“…Ones of the interesting structures of multiphase systems are five-phase power conversion systems based on five-phase inverters [15]- [17]. Basic topology of power circuit of a five-phase voltage source inverter with a star-connected load with the neutral point n is presented in Fig.…”

Section: Space-vector Pwm In Five-phase Inverter Systemsmentioning

confidence: 99%

Simplifying approach for analysis of space-vector PWM for three-phase and multiphase converters

Oleschuk

Profumo

Tenconi

2007

2007 European Conference on Power Electronics and Applications

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Direct time-domain approach, which is characterized by the simplicity and clarity, is proposed for the study and design of algorithms of voltage space-vector modulation for basic topologies of the threephase two-level and three-level inverters, and five-phase voltage source inverters. This approach is based on the detailed consideration of switching state sequences of inverters (with the corresponding duty-cycles), which are integrated characteristics of space-vector-based schemes and versions of pulsewidth modulation (PWM). It also permits providing of continuous synchronization of output voltage waveforms of converters during the whole control range, including overmodulation zone.

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Analysis and assessment of electrical and thermal performance of five‐phase voltage source inverter under different modulation strategies: Comparative study under balanced and unbalanced load

Sabri,

Benachour,

Guessar

et al. 2024

Circuit Theory & Apps

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SummaryThis paper compares four modulation strategies applied to five‐phase voltage source inverters (5PH‐VSI). The modulation strategies under investigation are sine wave pulse width modulation (S‐PWM), fifth‐harmonic injection PWM (FH‐PWM), space vector‐PWM using two large vectors (2V‐SVPWM), and space vector‐PWM using two medium and two large vectors (4V‐SVPWM). The study utilizes simulations to analyze the results based on four performance criteria: low‐order harmonics (LOH), maximum modulation index (MMI), common mode voltage (CMV), and total harmonic distortion (THD) under balanced and unbalanced load. To validate the simulation results for these criteria, an experimental test‐bench is employed, which includes a 5PH‐VSI feeding an R‐L load, and controlled by a low‐cost STM32F4‐DISCOVERY microcontroller board. Additionally, a mathematical approach is used to calculate the total thermal losses (TTL) then simulations are performed using Piecewise Linear Electrical Circuit Simulation (PLECS) software to assess the modulation schemes based on additional thermal performance criteria: conduction losses (CL), switching losses (SL), TTL, the efficiency, and the maximum permissible heat sink thermal resistance (MPHTR) at the steady‐state regime. The results indicate that the 4V‐SVPWM method demonstrates superior efficiency in terms of THD. Furthermore, it showcases the lowest TTL at high switching frequencies, allowing for the best efficiency and minimizing MPHRT, therefore providing the largest margin for the heat sink thermal resistance design. On the other hand, the 2V‐SVPWM offers the highest MMI, but this comes at the cost of high TTL and some LOHs appearing. In addition, it exhibits the highest CMV for unbalanced load. S‐PWM and FH‐PWM offer the advantage of simpler implementation.

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Five-Phase Inverters with Synchronized PWM

Cited by 16 publications

References 15 publications

Methods of voltage synchronization in multiphase power conversion systems

Methods of voltage synchronization in multiphase power conversion systems

Simplifying approach for analysis of space-vector PWM for three-phase and multiphase converters

Analysis and assessment of electrical and thermal performance of five‐phase voltage source inverter under different modulation strategies: Comparative study under balanced and unbalanced load

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