Common-Mode Reduction SVPWM for Three-Phase Motor Fed by Two-Level Voltage Source Inverter

Zheng, Jian; Lyu, Mingcheng; Li, Shengqing; Luo, Qiwu; Huang, Kan

doi:10.3390/en13153884

Cited by 8 publications

(9 citation statements)

References 24 publications

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“…In Table 2, the highest CMV is V dc /2 because SVPWM employs zero voltage vectors. In what follows, we introduce AZSPWM [2], NSPWM [14], and RSPWM [16]-these PWM techniques share the common feature of suppressing the CMV amplitude and toggling frequency. Figure 3 Under the sector , the action times of each vector can be calculated according to the volt-second principle, as in Equation ( 7) [35]:…”

Section: Conventional Modulation Methodsmentioning

confidence: 99%

“…Theoretically non-changing CMV [16] Low DC-bus utilization [16] This paper's contribution is as follows: (1) In the proposed improved commonmode reduction space vector pulse width modulation (CMRSVPWM) with 18 sub-sectors organizes the switching sequences in each sub-sector into resulting lower CMV amplitude and oscillation frequency; (2) MPC uses a large amount of virtual voltage vectors, such that all the 18 subsectors can be fully utilized. By combining the virtual vector MPC and CMRSVPWM, the CMV performance of the single-stage inverter can be improved.…”

Section: Rspwmmentioning

confidence: 99%

“…However, the corresponding DC-bus utilization factor is very poor. In addition, non-zero voltage vector modulation approaches, such as active zero-state switch PWM [2], near-state PWM [14,15], and remote-state PWM [16] have been reported in the past. Moreover, [17,18] compare the performance indices of various modulation schemes, in terms of e.g., CMV amplitude, output THD.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Common-Mode Voltage Reduction Algorithm for Photovoltaic Grid-Connected Inverters with Virtual-Vector Model Predictive Control

Goh

Lim

et al. 2021

Electronics

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Model predictive control (MPC) has been proven to offer excellent model-based, highly dynamic control performance in grid converters. The increasingly higher power capacity of a PV inverter has led to the industrial preference of adopting higher DC voltage design at the PV array (e.g., 750–1500 V). With high array voltage, a single stage inverter offers advantages of low component count, simpler topology, and requiring less control tuning effort. However, it is typically entailed with the issue of high common-mode voltage (CMV). This work proposes a virtual-vector model predictive control method equipped with an improved common-mode reduction (CMR) space vector pulse width modulation (SVPWM). The modulation technique essentially subdivides the hexagonal voltage vector space into 18 sub-sectors, that can be split into two groups with different CMV properties. The proposal indirectly increases the DC-bus utilization and extends the overall modulation region with improved CMV. The comparison with the virtual-vector MPC scheme equipped with the conventional SVPWM suggests that the proposed technique can effectively suppress 33.33% of the CMV, and reduce the CMV toggling frequency per fundamental cycle from 6 to either 0 or 2 (depending on which sub-sector group). It is believed that the proposed control technique can help to improve the performance of photovoltaic single-stage inverters.

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Section: Conventional Modulation Methodsmentioning

confidence: 99%

Section: Rspwmmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Common-Mode Voltage Reduction Algorithm for Photovoltaic Grid-Connected Inverters with Virtual-Vector Model Predictive Control

Goh

Lim

et al. 2021

Electronics

View full text Add to dashboard Cite

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“…In most of the practical real-time drive applications, the controller algorithm is coordinated with the inverter switching. Hence, the adjustable switching frequency disturbs the drive performance when it plays in the closed-loop systems [25,26]. In an electric drive system without exciting mechanical resonance, the fixed quasi-random carrier frequency PWM technique is proposed to abolish acoustical noise [12].…”

Section: Introductionmentioning

confidence: 99%

“…A random center distribution (RCD) problem is solved by the two-phase double zerovector random center distribution structure. The modulation index of RCD is high and not reduced properly [25][26][27]. A fixed and randomized PWM technique for the fully controlled converter reduces the harmonic intensity, contributing efficiency [28,29].…”

Section: Introductionmentioning

confidence: 99%

Hybrid Multicarrier Random Space Vector PWM for the Mitigation of Acoustic Noise

Madasamy¹,

Verma

Bharatiraja

et al. 2021

Electronics

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The pulse width modulation (PWM) inverter is an obvious choice for any industrial and power sector application. Particularly, industrial drives benefit from the higher DC-link utilization, acoustic noise, and vibration industrial standards. Many PWM techniques have been proposed to meet the drives’ demand for higher DC-link utilization and lower harmonics suppression and noise reductions. Still, random PWM (RPWM) is the best candidate for reducing the acoustic noises. Few RPWM (RPWM) methods have been developed and investigated for the AC drive’s PWM inverter. However, due to the lower randomness of the multiple frequency harmonics spectrum, reducing the drive noise is still challenging. These PWMs dealt with the spreading harmonics, thereby decreasing the harmonic effects on the system. However, these techniques are unsuccessful at maintaining the higher DC-link utilizations. Existing RPWM methods have less randomness and need complex digital circuitry. Therefore, this paper mainly deals with a combined RPWM principle in space vector PWM (SVPWM) to generate random PWM generation using an asymmetric frequency multicarrier called multicarrier random space vector PWM (MCRSVPWM). he SVPWM switching vectors with different frequency carrier are chosen with the aid of a random bi-nary bit generator. The proposed MCRSVPWM generates the pulses with a randomized triangular carrier (1 to 4 kHz), while the conventional RPWM method contains a random pulse position with a fixed frequency triangular carrier. The proposed PWM is capable of eradicating the high-frequency unpleasant acoustic noise more effectually than conventional RPWM with a shorter random frequency range. The simulation study is performed through MATLAB/Simulink for a 2 kW asynchronous induction motor drive. Experimental validation of the proposed MCRSVPWM is tested with a 2 kW six-switch (Power MOSFET–SCH2080KE) inverter power module-fed induction motor drive.

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SVPWM Overmodulation Region II Control Method Based on the Chaos Ant Colony Algorithm

Zhang

Wang

Gao

et al. 2021

J. Electr. Eng. Technol.

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Common-Mode Reduction SVPWM for Three-Phase Motor Fed by Two-Level Voltage Source Inverter

Cited by 8 publications

References 24 publications

Common-Mode Voltage Reduction Algorithm for Photovoltaic Grid-Connected Inverters with Virtual-Vector Model Predictive Control

Common-Mode Voltage Reduction Algorithm for Photovoltaic Grid-Connected Inverters with Virtual-Vector Model Predictive Control

Hybrid Multicarrier Random Space Vector PWM for the Mitigation of Acoustic Noise

SVPWM Overmodulation Region II Control Method Based on the Chaos Ant Colony Algorithm

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