A Review of Control Methods on Suppression of 2<i>ω</i> Ripple for Single-Phase Quasi-Z-Source Inverter

Vadi, Seyfettin; Bayındır, Ramazan; Hossain, Eklas

doi:10.1109/access.2020.2976581

Cited by 13 publications

(9 citation statements)

References 95 publications

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“…QZSI devresinin kısa devre çalışabilmesi nedeniyle kondansatör ve bobin değerlerinin seçimi verimi doğrudan etkilemektedir. Literatürde yapılan çalışmalarda; bobindeki akım dalgalanmasının ortalama değerin %10'un altında, kondansatördeki gerilim dalgalanmasının ise ortalama değerin %3'ün altında olduğu kabullerin esas alındığı görülmektedir [11]- [12].…”

Section: Empedans Katındaki Bobin Ve Kondansatör Seçimiunclassified

Design and implementation of a Quasi-Z-Source inverter

Endiz

Akkaya

2022

Pamukkale J Eng Sci

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Section: Empedans Katındaki Bobin Ve Kondansatör Seçimiunclassified

Design and implementation of a Quasi-Z-Source inverter

Endiz

Akkaya

2022

Pamukkale J Eng Sci

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“…Model of single phase QZS inverter and closed-loop control methods of the inverter are examined and compared with PWM methods. These control methods are used to eliminate the ripples at 2ω frequency in the inverters, and the advantages and disadvantages of these methods are presented [71].…”

Section: Quasi Z Source Inverter Topologiesmentioning

confidence: 99%

Review of impedance source power converter for electrical applications

Saravanan

Venkatachalam

Borelessa

et al. 2021

IJAAS

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<p>Power electronic converters have been actively researched and developed over the past decades. There is a growing need for new solutions and topography to increase the reliability and efficiency of alternatives with lower cost, size and weight. Resistor source converter is one of the most important power electronic converters that can be used for AC-DC, AC-AC, DC-DC and DC-DC converters which can be used for various applications such as photovoltaic systems, wind power systems, electricity. Vehicles and fuel cell applications. This article provides a comprehensive overview of Z-source converters and their implementation with new configurations with advanced features, emerging control strategies and applications.</p>

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“…These topologies still have a challenge of accidental short-circuiting of the switches in the same leg(s) of the inverter [61]. The impedancesource inverters (ISIs) [47]- [49] are the good choice in such limitations and operating conditions. However, these topologies require large size impedance-source network to filter low-frequency 2ω−ripple [62]- [64].…”

Section: A Passive Power-decoupling Techniquesmentioning

confidence: 99%

“…Flow chart of classification of 2ω−ripple mitigation techniques Passive power decoupling techniques (a) Isolated Voltage source inverter[36] (b) Grid-tied-Voltage source converter[39] (c) Flyback-type center-tapped inverter[42] (d) Inverter with front-end dual-bridge converter with high-frequency DC-link[43](e) Transformer-less buck and boost inverter topology[44](f) Pulse-link DC-AC converter[45] (g) two-stage DC-DC-AC converter (having a front-end buck or boost or buck-boost DC-DC converter)[46] (h) Z-source inverter (i) quasi-Z source inverter (j) quasi-switched boost inverter (k) Three-level single-phase impedance source inverter(Fig. 5(h-k)[47]-[49]). …”

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confidence: 99%

Control Strategies and Power Decoupling Topologies to Mitigate 2ω-Ripple in Single-Phase Inverters: A Review and Open Challenges

et al. 2020

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This paper provides a comprehensive review of the control approaches and the powerdecoupling topologies to mitigate 2ω-ripple problem in the single-phase inverters, its solutions, and discusses open challenges yet to be addressed. The cause and effects of 2ω-ripple problem and its solution based on the passive and active power-decoupling techniques are discussed. A subcategory of the active power-decoupling technique nominated as the control-oriented compensation technique is reviewed in detail, this technique can achieve the ripple-mitigation at the source through the control but not necessarily adds extra circuit or active filter to the system. The control-oriented compensation techniques can be applied in the two-stage DC-DC-AC converters and the single-stage inverters having a front-end control capability with the H-bridge such as in the quasi-switched-boost inverters. The merits and associated challenges of these techniques are listed and summarized in a tabular form. Finally, a conclusive discussion with open challenges is presented. INDEX TERMS 2ω−ripple, Single-phase Inverter, Control strategies, Power-decoupling schemes.

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A Review of Control Methods on Suppression of 2ω Ripple for Single-Phase Quasi-Z-Source Inverter

Cited by 13 publications

References 95 publications

Design and implementation of a Quasi-Z-Source inverter

Design and implementation of a Quasi-Z-Source inverter

Review of impedance source power converter for electrical applications

Control Strategies and Power Decoupling Topologies to Mitigate 2ω-Ripple in Single-Phase Inverters: A Review and Open Challenges

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