Showing total 332 results

151. A Discontinuous Current-Source Gate Driver With Gate Voltage Boosting Capability.

Author

Mashhadi, Iman Abdali, Khorasani, Ramin Rahimzadeh, Adib, Ehsan, and Farzanehfard, Hosein

Subjects

*METAL oxide semiconductor field-effect transistor circuits, *VOLTAGE regulators, *IDEAL sources (Electric circuits), *ELECTRIC conductivity, *SWITCHING circuits

Abstract

In this paper, a novel discontinuous current-source driver (CSD) is proposed, in which the power MOSFET gate-source voltage is increased to more than the drive supply voltage. The proposed CSD is able to recover gate energy dissipated in a conventional driver. In comparison to the conventional gate driver, the proposed CSD achieves fast switching speed to reduce switching losses. A wide range of operating duty cycle, low circulating losses, and high Cdv/dt immunity are other features of the proposed CSD. In comparison to previous discontinuous CSDs, the special advantage of the proposed circuit is power MOSFET gate voltage boosting, which leads to reduction of Rds(on) and, thus, the conduction loss. The proposed circuit is appropriate for voltage regulators (VRs) with synchronous rectifier and also it is suitable for two-stage 48-V power pod applications and low-voltage converters. Two-stage VR for laptop computer CPUs is another application of this gate driver circuit to improve light load performance. A prototype of the circuit operating at 1 MHz is implemented, and the experimental waveforms justify the theoretical analysis. [ABSTRACT FROM PUBLISHER]

Published

2017

152. A Family of True Zero Voltage Zero Current Switching (ZVZCS) Nonisolated Bidirectional DC?DC Converter With Wide Soft Switching Range.

Author

Ashique, Ratil H. and Salam, Zainal

Subjects

*DC-to-DC converters, *ZERO voltage switching, *ZERO current switching, *ELECTRIC inductors, *CAPACITORS, *DIODES, DESIGN & construction

Abstract

This paper proposes a true zero voltage zero current switching (ZVZCS) nonisolated bidirectional dc–dc converter with reduced component count. An auxiliary resonant network—which comprises of an inductor, capacitor, diode, and two switches—provides the zero voltage switching transitions of the main switches at turn on and turn off instants. In addition, a pair of auxiliary inductors, which act as inductive snubbers, aids the zero current switching transitions. The proposed configuration is able to provide soft commutation for the main switches for a wide range of input voltage, switching frequency, and load current variations—thus significantly improving the efficiency profile over a wide operating window. Besides, the auxiliary switches are also soft commutated, while the reverse recovery loss induced by the high side diode is eliminated. The ZVZCS soft switching operation is demonstrated by a 150 W prototype converter; it is proven consistent with the waveforms derived from the theoretical analysis. Its performance is evaluated against the standard hard-switched boost, buck, and several other leading soft switching converters published in the recent literature. The maximum full load efficiency at 100 kHz is recorded at 98.2% and 97.5% in the boost and buck modes, respectively. [ABSTRACT FROM PUBLISHER]

Published

2017

153. Boost-Integrated Two-Switch Forward AC?DC LED Driver With High Power Factor and Ripple-Free Output Inductor Current.

Author

Lee, Sin-Woo and Do, Hyun-Lark

Subjects

*LIGHT emitting diode design & construction, *LIGHT emitting diode efficiency, *AC DC transformers, *ELECTRIC power factor correction, *ELECTRIC inductors

Abstract

This paper proposes a boost-integrated two-switch forward ac–dc light-emitting diode (LED) driver with a high power factor and ripple-free output inductor current. In the proposed LED driver, the maximum switch voltages are clamped to the voltage level of the dc-link capacitor without an RCD snubber circuit by adopting a two-switch forward structure, and the magnetizing inductor energy is restored in the dc-link capacitor to prevent the magnetizing inductor from saturating without a tertiary winding. Moreover, the relatively small capacitance can be utilized by the output capacitor, as the output inductor current ripple is significantly reduced by the additional circuit, unlike in the conventional LED driver. Hence, the LC filter at the output stage is simplified. The proposed LED driver has a high power factor and the power efficiency is improved. The theoretical analysis results of the proposed LED driver are verified on an output 24 [V]–1.4 [A] prototype. [ABSTRACT FROM PUBLISHER]

Published

2017

154. Analysis and Design of a Single-Stage Isolated AC?DC LED Driver With a Voltage Doubler Rectifier.

Author

Luo, Quanming, Huang, Jian, He, Qingqing, Ma, Kun, and Zhou, Luowei

Subjects

*LIGHT emitting diode design & construction, *PERFORMANCE of light emitting diodes, *AC DC transformers, *ELECTRIC current rectifiers, *VOLTAGE doublers, *ELECTRIC power factor correction, *COMPARATIVE method

Abstract

In order to reduce the cost and volume of small-medium power ac–dc light-emitting diode (LED) lighting systems, single-stage LED drivers are often used to drive LEDs with constant current. In this paper, a single-stage isolated high-power factor ac–dc LED driver is proposed and analyzed in detail, which is composed of a buck–boost power factor correction unit operating in discontinuous conduction mode and an isolated dc/dc unit with a voltage doubler rectifier, and the two units are integrated together by sharing the same power switch. Very high input power factor is achieved since the PFC unit operates with almost fixed duty ratio during half period of the utility line voltage. Since a voltage doubler rectifier is included in the isolated dc/dc unit, magnetic core size of the transformer and voltage stress of the secondary side diodes are reduced remarkably. First, the operating principle and performance of the LED driver are analyzed. Then, the main parameters are quantitatively calculated out in detail. Finally, a comparative analysis is presented and a 120 W experimental prototype with 1 A output current is built according to the calculated parameters and the experimental results are presented to verify the correctness of the theoretical analysis and parameter design. [ABSTRACT FROM PUBLISHER]

Published

2017

155. High Step-Up DC–DC Converter With Minimum Output Voltage Ripple.

Author

Mashinchi Maheri, Hamed, Babaei, Ebrahim, Sabahi, Mehran, and Hosseini, Seyed Hossein

Subjects

*ELECTRIC inductors, *CAPACITORS, *DIRECT current electric motors, *TOPOLOGY, *HIGH voltages

Abstract

In this paper, a new structure for high step-up dc–dc converters is proposed. In the proposed structure, it is possible to extend the topology by increasing the number of active–passive inductor cells. High voltage gain with lower duty cycle, low-current and -voltage stresses on switches, small inductors, and small size of filter are the main advantages of the proposed structure. The proposed converter is analyzed in different operating modes. In order to design the components’ values of the proposed converter, the equations of output voltage ripple are calculated in each operating mode and a design procedure is proposed based on the aforementioned equations. Moreover, the losses and efficiency of the converter are calculated. In order to validate the correctness of calculations and analyses, the experimental results are given. [ABSTRACT FROM PUBLISHER]

Published

2017

156. Soft-Switching Dual-Flyback DC?DC Converter With Improved Efficiency and Reduced Output Ripple Current.

Author

Yang, Jae-Won and Do, Hyun-Lark

Subjects

*ZERO voltage switching, *ELECTRIC current rectifiers, *ELECTRIC inductance, *CAPACITORS, *SNUBBERS (Electrical engineering)

Abstract

This paper presents a soft-switching dual-flyback dc–dc converter with improved efficiency and reduced output ripple current. Zero-voltage-switching (ZVS) technique and a dual-flyback module for reducing the number of snubber current paths are adopted to improve efficiency. For the ZVS technique, a self-driven synchronous rectifier (SR) is used instead of an output diode. By turning the self-driven SR off after a short delay, a main switch is turned on under the ZVS condition. For reducing the number of snubber current paths, a dual-flyback module and a snubber diode are used. When the main switch is turned off, leakage inductance energy is absorbed by a snubber diode into an input source and a primary dc-bus capacitor. Then, this energy is reprocessed by the dual-flyback dc-dc module to secondary side. Hence, there is only one snubber current path. In addition, the proposed converter features a reduced output ripple current because of the continuous current. Consequently, the proposed converter can achieve high efficiency and reduced output ripple current. To verify the performance of the proposed converter, operating principles, steady-state analyses, and experimental results from a 340 to 24-V, 100-W prototype are presented. [ABSTRACT FROM AUTHOR]

Published

2017

157. Single-Stage High Power Factor Converters Requiring Low DC-Link Capacitance to Drive Power LEDs.

Author

Palhano da Fonseca, Zito, Perin, Arnaldo Jose, Agostini Junior, Eloi, and Bitencourt Nascimento, Claudinor

Subjects

*CAPACITORS, *LIGHT emitting diodes, *MATHEMATICAL analysis, *TOPOLOGY, *CONVERTERS (Electronics)

Abstract

This paper proposes two nonisolated single-stage high power factor converters requiring low dc-link capacitance for power LEDs systems. Both converters result from the integration of the power factor correction and the LEDs driver stages, and require a relatively low dc-link capacitance value. A high power factor is demonstrated to be an inherent property of the proposed topologies and no input current control is necessary. The LEDs current is regulated by a symmetrical soft-switching half-bridge converter associated with a capacitive output filter. An accurate mathematical analysis valid for the two converters is detailed, yielding the elaboration of a step-by-step design procedure. In order to verify the analyses carried out, experimental results for two 90 W, 50 kHz, and 220 V converters are also presented. [ABSTRACT FROM PUBLISHER]

Published

2017

158. A New Buck Converter With Optimum-Damping and Dynamic-Slope Compensation Techniques.

Author

Chen, Jiann-Jong, Hwang, Yuh-Shyan, Liou, Jian-Fong, Ku, Yi-Tsen, and Yu, Cheng-Chieh

Subjects

*CASCADE converters, *DAMPING (Mechanics), *SUBHARMONIC functions, *CURRENT-mode circuits, *VOLTAGE control, *TRANSIENT responses (Electric circuits)

Abstract

This paper presents a new buck converter with optimum-damping and dynamic-slope compensation techniques. The optimum-damping control is a well-known current control method, and the proposed dynamic-slope generator can achieve frequency compensation to prevent subharmonic oscillation. When the system is disturbed, the proposed dynamic-slope generator can stabilize the circuit in a single cycle. Hence, the dynamic-slope compensation can be used to replace traditional extra slope compensation in the optimum-damping-control circuit. The measured transient time of the load current is 2 μs from 50 to 500 mA, and 3 μs from 500 to 50 mA. The optimum-damping-control techniques can rapidly reach desired output voltage in 2–3 switching cycles. The experimental and simulation results confirm that the proposed approach can achieve the slope compensation and accelerate the transient response. The proposed converter has been fabricated with TSMC 0.18 μm CMOS 1P6M technology. The converter's operating frequency is 1 MHz, the maximum output current is 500 mA, and the peak power efficiency is 89.68% under 300-mA load current. The chip area is only 1.0376 mm × 1.0599 mm (include PADs). [ABSTRACT FROM PUBLISHER]

Published

2017

159. Zero-Sequence Voltage Modulation Strategy for Multiparallel Converters Circulating Current Suppression.

Author

Zhu, Rongwu, Liserre, Marco, Chen, Zhe, and Wu, Xiaojie

Subjects

*ELECTRONIC modulation, *DIRECT current circuits, *ELECTRIC potential measurement, *ELECTRIC inductance, *CONVERTERS (Electronics)

Abstract

A zero-sequence circulating current (ZSCC) is typically generated among the multiparallel converters that share the common dc link and ac side without isolated transformers under the space vector modulation (SVM), due to the injected third-order zero-sequence voltage (ZSV). This paper analyzes SVM techniques, studies the effects of the ZSV on the ZSCC control loop in detail, and then proposes an improved SVM scheme to suppress the impact of the ZSV on the ZSCC. The proposed strategy can effectively realize the ZSCC suppression, even though the parallel converter modules have asymmetrical current references and filter inductances. The simulation and experimental results based on the parallel converters clearly verify the effectiveness of the proposed control. [ABSTRACT FROM PUBLISHER]

Published

2017

160. Circuit-Parameter-Independent Nonlinearity Compensation for Boost Converter Operated in Discontinuous Current Mode.

Author

Le, Hoai Nam, Orikawa, Koji, and Itoh, Jun-Ichi

Subjects

*SWITCHING circuits, *ELECTRIC inductors, *TRANSFER functions, *PROTOTYPES, *FREQUENCIES of oscillating systems, *DC-to-DC converters, *NONLINEAR control theory

Abstract

This paper proposes a current control method for discontinuous current mode (DCM) in order to achieve the same control performance as continuous current mode (CCM) in a boost converter. By utilizing the duty ratio at the previous calculation period to compensate for a DCM nonlinearity, the controller, which is designed for CCM, can also be used in DCM. In the frequency analysis, the cutoff frequency of the proposed DCM current control agrees exactly to the design value, which is 2 kHz, whereas the cutoff frequency of the conventional DCM current control results in high error of 47.5%. In the current step response experiment with a 360-W prototype and the switching frequency of 20 kHz, the experimental DCM current response almost agrees with the conventional CCM current response, which are 380-μs rise time for both CCM and DCM, 9% and 8% overshoot for CCM and DCM, respectively. Furthermore, the computation time of the proposed DCM current control is shorter 35% than the conventional DCM current control. [ABSTRACT FROM AUTHOR]

Published

2017

161. A Novel Structure for Single-Switch Nonisolated Transformerless Buck?Boost DC?DC Converter.

Author

Banaei, Mohammad Reza and Bonab, Hossein Ajdar Faeghi

Subjects

*DIRECT currents, *VOLTAGE-frequency converters, *ELECTRIC potential, *MATHEMATICAL analysis, *ELECTRIC inductors, *FUEL cells

Abstract

A novel transformerless buck–boost dc–dc converter is proposed in this paper. The presented converter voltage gain is higher than that of the conventional boost, buck–boost, CUK, SEPIC, and ZETA converters, and high voltage can be obtained with a suitable duty cycle. In this converter, only one power switch is utilized. The voltage stress across the power switch is low. Hence, the low on-state resistance of the power switch can be selected to decrease conduction loss of the switch and improve efficiency. The presented converter has simple structure, therefore, the control of the proposed converter will be easy. The principle of operation and the mathematical analyses of the proposed converter are explained. The validity of the presented converter is verified by the experimental results. [ABSTRACT FROM PUBLISHER]

Published

2017

162. Hybrid Z-Source Boost DC–DC Converters.

Author

Shen, Hanyun, Zhang, Bo, and Qiu, Dongyuan

Subjects

*CASCADE converters, *DIRECT currents, *PHOTOVOLTAIC cells, *ELECTRIC potential, *HYBRID integrated circuits

Abstract

This paper presents a new family of hybrid Z-source boost dc–dc converters intended for photovoltaic applications, where the high step-up dc–dc converters are demanded to boost the low-source voltages to a predefined grid voltage. Because the boost capabilities of the traditional Z-source networks are limited, the proposed converters are composed of combine traditional Z-source networks in different ways to enhance the boost abilities of the traditional Z-source networks. The new version of the proposed Z-source converters is termed as hybrid Z-source boost dc–dc converters to satisfy the traditional benefits of Z-source networks with stronger voltage boost abilities which can also be applied to dc–ac, ac–ac, and ac–dc power conversions. The performances of the proposed converters are compared with other Z-source networks behaviors. The simulation and experimental results of the proposed converters are validated at different operating conditions. [ABSTRACT FROM PUBLISHER]

Published

2017

163. Improved Power Quality Bridgeless Converter-Based SMPS for Arc Welding.

Author

Narula, Swati, Singh, Bhim, Bhuvaneswari, G., and Pandey, Rahul

Subjects

*CONVERTERS (Electronics), *ELECTRIC welding, *ELECTRIC potential measurement, *ANALOG-to-digital converters, *HARMONIC distortion (Physics)

Abstract

This paper proposes a power-factor-corrected bridgeless (BL) switched-mode power supply (SMPS) for welding applications that possesses output voltage control and current limiting feature even during extreme overloading conditions at the output terminals. Eliminating an input diode bridge rectifier minimizes conduction losses and improves thermal utilization of semiconductor devices. The front-end of the proposed SMPS consists of a BL boost converter operating in a continuous conduction mode to attain unity power factor, while at the rear end a pulse width modulation isolated full bridge dc–dc converter is used to regulate the output voltage. The design and implementation of this BL arc welding power supply (AWPS) is presented showing its fast dynamic response to supply voltage and load variations. The performance of the proposed AWPS is examined in terms of power factor, total harmonic distortion of the supply current, efficiency, and output current limit over a wide range of line/load variations. Test results confirm the effectiveness of the proposed AWPS in maintaining an impeccable power quality at utility interface apart from achieving an excellent output voltage regulation and current limiting capability. [ABSTRACT FROM PUBLISHER]

Published

2017

164. Three-Phase Push–Pull DC–DC Converter: Analysis, Design, and Experimentation.

Author

Larico, Hugo R. E. and Barbi, Ivo

Subjects

*DC-to-DC converters, *PUSH-pull amplifiers, *POWER semiconductors, *ENERGY consumption, *PROTOTYPES, DESIGN & construction

Abstract

This paper presents a voltage-fed three-phase push–pull dc–dc converter. The main characteristics of the proposed converter are: small volume, low weight, reduced number of components, low voltage across the power semiconductors for duty cycles less than 1/3, and input current ripple cancellation when the duty cycle is equal to 1/3. Typical applications include battery chargers, electric vehicles, and renewable energy systems. The paper presents a theoretical analysis, design example, and experimental data for a 650 W, 150-125 VDC input, 75 VDC output, and 42 kHz switching frequency laboratory prototype. The measured performance agreed well with the theoretical predictions. The measured efficiency for 125 VDC input at full load is 95%. [ABSTRACT FROM PUBLISHER]

Published

2012

165. High-Power Multilevel Step-Up DC/DC Converter for Offshore Wind Energy Systems.

Author

Gandomkar, Ali, Parastar, Amir, and Seok, Jul-Ki

Subjects

*CONVERTERS (Electronics), *WIND power, *HIGH voltages, *SIMULATION methods & models, *PROTOTYPES

Abstract

This paper presents a multilevel step-up dc/dc converter for dc-grid-based offshore wind energy conversion applications. The main features of the proposed multilevel converter are as follows: 1) the voltage stress of the power devices can be reduced, making it suitable for high-voltage applications; 2) the boost inductor can be reduced significantly, leading to the outstanding dynamic performance; and 3) high-voltage gain can be obtained and thus is well-suited for high-gain applications. Theoretical analysis was carried out for a four-level step-up converter, based on which, the converter can be extended to any arbitrary number of levels. The proposed four-level converter was verified by a simulation and evaluated by comparing with a conventional multilevel dc/dc converter in terms of the component stress and power device count. The developed topology was implemented on a 2-kW prototype converter to evaluate its feasibility. [ABSTRACT FROM AUTHOR]

Published

2016

166. Analytical and Experimental Comparison of Carrier-Based PWM Methods for the Five-Phase Coupled-Inductor Inverter.

Author

Tan, Cheng, Xiao, Dan, Fletcher, John Edward, and Rahman, Muhammed Fazlur

Subjects

*ELECTRIC inductors, *PULSE width modulation transformers, *ELECTRIC inverters, *TOPOLOGY, *SIMULATION methods & models

Abstract

The five-phase coupled-inductor inverter is a newly proposed option for three-level five-phase inverter drives. This paper comprehensively analyzes the inverter including the coupled-inductor current, current stress on the dc-link capacitors, and a comparison of these performance aspects using three pulse width modulation (PWM) strategies. Mathematical derivations of the inverter currents and the associated current stress reveal that the current stress is not only influenced by the choice of modulation strategy, as in the neutral-point-clamped topology, but also by the value of coupled inductance; furthermore, the choice of the modulation strategy impacts the core loss of the coupled inductors. Three carrier-based PWM methods are considered: sinusoidal PWM (SPWM), and two methods with the common-mode voltage reduction (referred to as CMVR1 and CMVR2) for the five-phase coupled-inductor inverter. CMVR2 is shown to be the best solution if common-mode voltage reduction is required. The analysis demonstrates that SPWM performs better with respect to current stress and inverter losses, therefore is the preferable modulating strategy for the five-phase coupled-inductor inverter if common-mode voltage reduction is not required. The analysis is verified by simulations and experiments. [ABSTRACT FROM AUTHOR]

Published

2016

167. A Single-Switch High Step-Up DC–DC Converter Based on Quadratic Boost.

Author

Saadat, Peyman and Abbaszadeh, Karim

Subjects

*PHOTOVOLTAIC power generation, *DIRECT currents, *RENEWABLE energy sources, *CASCADE converters, *ELECTRIC potential

Abstract

This paper proposes a novel high step-up nonisolated single switch dc–dc converter suitable for regulating dc bus in various microsources especially for photovoltaic (PV) sources. Quadratic boost and switched-capacitor technique are used as primary and secondary circuits, respectively. A coupled inductor is applied to make a connection between them, so a high dc voltage gain is achieved. High efficiency is yield where voltage stress on active switch is alleviated by clamped capacitor; consequently, smaller \rmR\rm{DS(ON)} for power switch is required. On the other hand, input current of the proposed converter is continued, hence stress on the input source is reduced. The operating principles and steady-state analyses are discussed in detail for both continuous and discontinuous conduction modes. Also, the boundary condition is computed. To verify the performance of the proposed converter and theoretical calculations, a 250-W prototype converter is implemented with an input voltage of 24 V and an output voltage of 400 V designed especially for PV sources in continuous conduction mode operation. Finally, simulation results are confirmed by experimental results; maximum efficiency is occurred at 150 W and full-load efficiency is 92.96%. [ABSTRACT FROM AUTHOR]

Published

2016

168. Dynamic Dead-Time Optimization and Phase Skipping Control Techniques for Three-Phase Microinverter Applications.

Author

Tayebi, Seyed Milad, Jourdan, Charles, and Batarseh, Issa

Subjects

*ELECTRIC inverters, *ZERO voltage switching, *PULSE width modulation, *PHOTOVOLTAIC power generation, *HARMONIC distortion (Physics)

Abstract

This paper introduces a combination of two proposed efficiency improvement techniques for a microinverter with current mode control zero-voltage switching output stages. The first technique is dynamic dead-time optimization wherein pulse width modulation dead times are dynamically adjusted as a function of load current. The second method is advanced phase skipping control which maximizes inverter efficiency by controlling power on individual phases depending on the available input power from the photovoltaic source. Neither of the techniques requires any additional circuit components and both can be easily implemented in digital controller firmware. The two techniques were designed and implemented in a 400-W three-phase microinverter prototype. The experimental results validate the theoretical analysis of these techniques and demonstrate that a significant efficiency improvement can be achieved by combining the two proposed control techniques. [ABSTRACT FROM AUTHOR]

Published

2016

169. Isolated High Step-Up DC–DC Converter Based on Quasi-Switched-Boost Network.

Author

Nguyen, Minh-Khai, Lim, Young-Cheol, Choi, Joon-Ho, and Cho, Geum-Bae

Subjects

*DIRECT currents, *CASCADE converters, *ELECTRIC power conversion, *GALVANIC isolation, *PHOTOVOLTAIC power generation, *SOLAR cells, *FUEL cells

Abstract

In this paper, a new isolated high step-up dc–dc converter is proposed based on the quasi-switched-boost network. The proposed converter has the following features: 1) continuous input current; 2) reduced turn ratio of the isolated transformer; 3) increased reliability, as it can operate in either short-circuit mode or open-circuit mode without causing damage to the power converter; and 4) unchanged primary and secondary voltage waveforms of the transformer, although the shoot-through duty cycle is variable. Compared to the quasi-Z-source-based isolated dc–dc converter, the proposed converter uses fewer passive components. The operating principles, analysis, parameter design guideline, and comparison with the quasi-Z-source-based isolated dc–dc converter are presented. A 450 W prototype is built to test the proposed converter. The proposed converter is applicable for distributed power generation applications where a varying low dc input voltage is converted to a high stabilized dc output voltage with a galvanic separation requirement. [ABSTRACT FROM AUTHOR]

Published

2016

170. A Family of DC–DC Converters Deduced From Impedance Source DC–DC Converters for High Step-Up Conversion.

Author

Liu, Hongchen, Li, Fei, and Wheeler, Pat

Subjects

*DIRECT currents, *CASCADE converters, *ELECTRIC impedance, *SEMICONDUCTOR devices, *RAPID prototyping

Abstract

A family of dc–dc converters based on impedance source dc–dc converters is presented. The scheme of the proposed family is that the switch of impedance source dc–dc converters is moved forward. The derived topologies are suitable for high-voltage step-up ratio. Compared to the typical impedance source dc–dc converters, the presented topology dramatically reduces the voltage stresses on the power semiconductor devices. In addition, the passive lossless clamped circuit is introduced into the proposed family to restrict the peak voltage of the main switch. This paper presents an analysis of the converter and results from a prototype converter to validate the topology's performance. [ABSTRACT FROM AUTHOR]

Published

2016

171. A New Family of Multi-Input Converters Based on Three Switches Leg.

Author

Azizi, Mahdi, Mohamadian, Mustafa, and Beiranvand, Reza

Subjects

*CASCADE converters, *ELECTRIC currents, *ELECTRIC circuits, *SWITCHING theory, *ELECTRIC inverters

Abstract

Multiterminal converters eliminate using several single-input-single-output converters and simplify their topologies and reduce their cost. In this paper, a new family of multi-input converters based on three switches leg is introduced. Inputs of the proposed converters are similar and they are topologically interchangeable and have boost or buck operation modes. The proposed converter has one output that operates as an inverter. Here, all operating modes of the proposed converters and their effects on each other are investigated, in details. Also, an appropriate switching technique for the converters is given. A detailed comparison between conventional and proposed two-input converters is also presented. A two-input, one-output prototype converter has been implemented to validate the given analyses and to verify the proposed converter's performance. The experimental results are in good agreement with the theoretical and simulated analyses. [ABSTRACT FROM AUTHOR]

Published

2016

172. A New Single-Phase \boldsymbol\Pi-\textType 5-Level Inverter Using 3-Terminal Switch-Network.

Author

Hu, Yanshen, Xie, Yunxiang, Fu, Dianbo, and Cheng, Li

Subjects

*ELECTRIC inductors, *ELECTRIC inverters, *ELECTRIC potential, *ELECTRIC currents, *PULSE width modulation

Abstract

A new single-phase \uppi-\texttype 5-level inverter using 3-terminal switch-network (3TSN) is proposed in this paper. The topology is considered as a variant of T-type 3-level structure or dual-buck inverter with coupled inductors. This new inverter is suitable for multilevel power inversion with low dc-bus voltage. The merit of the proposed topology is to apply only four active power switches to achieve 5-level operation. Other benefits include double frequency operation of output inductor and equal division of the current that flows through power switches and filter inductor. Hence, it leads to high efficiency and low harmonics. These characteristics allow improvement of losses distribution and volume reduction of output filter inductor. The operation scenario with sinusoidal pulsewidth modulation (SPWM) is described in details. Meanwhile, the magnetic analysis and design are studied and discussed. Finally, a prototype is built to verify the theoretical analysis and demonstrate the benefits of the proposed topology. [ABSTRACT FROM AUTHOR]

Published

2016

173. An Expandable Four-Phase Interleaved High Step-Down Converter With Low Switch Voltage Stress and Automatic Uniform Current Sharing.

Author

Hwu, K. I., Jiang, W. Z., and Wu, P. Y.

Subjects

*ELECTRIC potential, *CASCADE converters, *ELECTRIC current converters, *CAPACITORS, *ELECTRIC capacity, *ENERGY storage

Abstract

In this paper, a novel four-phase interleaved high step-down converter is presented. The proposed converter can provide an extremely high step-down voltage conversion ratio within a moderate duty cycle. There are four main advantages of the proposed converter. First, the blocking capacitors can store energy as usual. Therefore, they are used as voltage sources to reduce the input voltage as well as to reduce the switch voltage stresses. Second, due to the charge balance of the dc blocking capacitors, the converter possesses an automatic uniform current sharing characteristic of the interleaved phases without adopting any extra circuitry. Third, due to the phase shift between the interleaved phases, the architecture provides a low output current ripple. Fourth, the number of phases can be expanded or reduced to any even phases; therefore, the converter has a wide range of applications. Finally, the operating principles and analysis of this architecture are given, and an experimental prototype is also provided to verify the effectiveness of the proposed converter. [ABSTRACT FROM PUBLISHER]

Published

2016

174. Predictive Control Algorithm Including Conduction-Mode Detection for PFC Converter.

Author

Park, Jin-Hyuk, Kim, Dae Joong, and Lee, Kyo-Beum

Subjects

*PREDICTIVE control systems, *CONVERTERS (Electronics), *ELECTRIC power factor, *ELECTRIC conductivity, *ALGORITHMS

Abstract

This paper proposes a predictive control algorithm that includes conduction-mode detection for power factor correction (PFC) converter. In PFC converters, the line current is usually distorted because of the characteristics of the proportional-integral (PI) current controller. To improve the quality of the current, the PI current controller requires additional circuits or algorithms. However, because of the optimal duty cycle determined by estimating the next-state current in both the continuous-conduction mode and the discontinuous-conduction mode, the proposed predictive control method has a fast dynamic response and accuracy compared to the PI current-control method. Moreover, the proposed algorithm can detect the conduction mode without any additional circuitry or mode-detection algorithm using the characteristic of the optimal duty cycle calculated by the predictive control. These advantages of the proposed algorithm improve the quality of the line current for PFC converters. We verify the proposed method by performing experiment using a 1.5-kW PFC converter. [ABSTRACT FROM PUBLISHER]

Published

2016

175. An Improved Single-Phase Direct PWM Inverting Buck–Boost AC–AC Converter.

Author

Khan, Ashraf Ali, Cha, Honnyong, and Ahmed, Hafiz Furqan

Subjects

*AC-AC transformers, *CONVERTERS (Electronics), *ELECTRIC inverters, *PULSE width modulation transformers, *METAL oxide semiconductor field-effect transistors

Abstract

A single-phase inverting buck–boost ac–ac converter is proposed in this paper. The proposed converter has no shoot-through and dead-time problems and, like conventional dc–dc converters, it can be operated with simple pulse width modulation (PWM) control. It offers high frequency and high efficiency operation because high speed mosfet can be used as switching device without the reverse recovery issues and losses of its body diode. The proposed converter features quasi-continuous input and output currents, high input power factor, low total harmonic distortion of input and output currents, and high efficiency. A 460 W laboratory prototype was constructed and tested with interleaved and complementary PWM controls using a resistive and inductive load. Detailed experimental results are provided to show the novelty of the proposed converter. Experimental results confirmed that the proposed converter can obtain 93.8% efficiency at 60 kHz switching frequency. [ABSTRACT FROM PUBLISHER]

Published

2016

176. Efficient ZVS Synchronous Buck Converter with Extended Duty Cycle and Low-Current Ripple.

Author

Marvi, Fahimeh, Adib, Ehsan, and Farzanehfard, Hosein

Subjects

*ROTARY converters, *CAPACITORS, *VOLTAGE regulators, *ELECTRIC inductors, *ELECTRIC circuits

Abstract

In this paper, an efficient zero-voltage-switching (ZVS) synchronous buck converter with extended duty cycle and low-current ripple is proposed for voltage regulator module (VRM) applications. By combining series capacitor and coupled inductors, operating duty cycle is extended considerably. Also, soft switching condition for all switches is provided without any auxiliary circuit and as a result, overall efficiency is improved. In addition, by complementary operation of the main switches of the interleaved modules, the resulting output current ripple is reduced. The converter operating modes are discussed and experimental results are presented to verify the theoretical analysis. [ABSTRACT FROM PUBLISHER]

Published

2016

177. Direct Model-Predictive Control With Variable Commutation Instant: Application to a Parallel Multicell Converter.

Author

Llor, Ana M. and Solano, Eduard

Subjects

*CAPACITORS, *CONVERTERS (Electronics), *ELECTRIC transformers, *PREDICTIVE control systems, *ELECTRIC potential

Abstract

This paper presents a new formulation of a finite control set model-predictive control (FCS-MPC) algorithm, allowing to determine the best commutation instant in order to optimize the converter current tracking. This algorithm, mixing properties of FCS-MPC method and time resolution related to pulse width modulation schemes, is illustrated in a parallel flying capacitor converter. The parallel association of classical commutation cells is a good solution for increasing the output current driven by the converters, while the standard semiconductor technology is used. The control strategy used with this type of connection must be able to ensure not only a good distribution of the output current among the different legs, but also the balancing of the floating capacitor voltages. [ABSTRACT FROM PUBLISHER]

Published

2016

178. Dual-Converter-Fed Open-End Transformer Topology With Parallel Converters and Integrated Magnetics.

Author

Gohil, Ghanshyamsinh, Bede, Lorand, Teodorescu, Remus, Kerekes, Tamas, and Blaabjerg, Frede

Subjects

*ELECTRIC inductors, *ELECTRIC current converters, *MAGNETICS, *ELECTRIC transformers, *ELECTRIC currents

Abstract

A converter system for high-power applications, connected to a medium-voltage network using a step-up transformer, is presented in this paper. The converter-side winding of the transformer is configured as an open-end, and both the ends of the windings are fed from two different converter groups. Each converter group comprises of two parallel voltage-source converters (VSCs), whose carrier signals are interleaved to improve the harmonic quality of the resultant switched output voltage of that converter group. However, an additional inductive component is required to suppress the circulating current that flows between the parallel-interleaved VSCs. An integrated inductor is proposed, which suppresses the circulating current in both the converter groups. In addition, the functionality of the line filter inductor is also integrated. Flux in various parts of the integrated inductor is analyzed, and a design procedure is also described. The volume and the losses of the proposed solution are compared with that of the state-of-the-art solution. The control of the proposed converter system is also discussed. The analysis has been verified by the simulation and experimental results. [ABSTRACT FROM PUBLISHER]

Published

2016

179. Topology Derivation and Generalized Analysis of Zero-Voltage-Switching Synchronous DC–DC Converters With Coupled Inductors.

Author

Chen, Guipeng, Deng, Yan, Tao, Yong, He, Xiangning, Wang, Yousheng, and Hu, Yihua

Subjects

*DC-to-DC converters, *ZERO voltage switching, *ELECTRIC inductors, *ELECTRIC switchgear, *ZERO current switching

Abstract

In conventional dc–dc converters with synchronous rectifiers, hard-switching operation of the main switch and reverse-recovery problem of the synchronous switch result in degraded performance. In order to avoid these two undesired shortcomings, employing a coupled inductor is a simple yet effective solution. Apart from the improved soft-switching characteristic, low component count is also achieved since only a coupled winding and a series auxiliary diode are added. In this paper, a general zero-voltage-switching (ZVS) topology with a coupled inductor is proposed and based on which, a family of ZVS synchronous buck, boost, and buck–boost converters is readily obtained. For each fundamental dc–dc converter, several viable ZVS topologies evolve, among which an optimum topology can be chosen according to the different requirement in practical engineering applications. To help the topology selection, generalized analysis and individual comparison are also undertaken. In addition, design consideration is illustrated and experiment results are provided to validate converter effectiveness. Furthermore, thanks to its generality, the topology derivation and generalized analysis can be easily extended to various synchronous dc–dc converters. [ABSTRACT FROM PUBLISHER]

Published

2016

180. Boundaries of Subharmonic Oscillations Associated With Filtering Effects of Controllers and Current Sensors in Switched Converters Under CMC.

Author

El Aroudi, Abdelali, Calvente, Javier, Giral, Roberto, Al-Numay, Mohammed S., and Martinez-Salamero, Luis

Subjects

*OSCILLATIONS, *DETECTORS, *CONVERTERS (Electronics), *ELECTRONIC switch-mode DC-to-DC converters, *COMPUTER simulation

Abstract

Subharmonic oscillation is widely studied in switching converters under current mode control (CMC). Its boundary of occurrence in the design parameter space is well known in the case of an infinite-bandwidth current sensor. However, in a practical implementation, either a limited-bandwidth current sensor or an additional filter is used. This could have an effect on the system dynamics particularly for relatively high switching frequencies. This paper discusses the effect of the additional dynamics due to the finite-bandwidth current sensor or the additional filter on the stability and subharmonic oscillation boundaries in switching converters under CMC. It is shown that a simplified model, taking into account the dynamics of the inductor current and the sensor/filter, is enough to obtain accurate results concerning the prediction of the occurrence of subharmonic instabilities in switched converters. Design-oriented equations describing the occurrence of subharmonic oscillations are used to show some problems related to the additional dynamics on the ramp compensator design in a single-switch dc–dc converter working in continuous conduction mode. Some proposed solutions are also discussed. Numerical simulations and experimental measurements corroborate the theoretical predictions. [ABSTRACT FROM PUBLISHER]

Published

2016

181. General Derivation Law of Nonisolated High-Step-Up Interleaved Converters With Built-In Transformer.

Author

Li, Wuhua, Li, Weichen, He, Xiangning, Xu, David, and Wu, Bin

Subjects

*ELECTRIC switchgear, *CLAMPS (Engineering), *CAPACITORS, *ELECTRIC transformers, *ENERGY transfer, *CASCADE converters, *ELECTRIC inductance, *ELECTRIC generators, *ELECTRIC windings

Abstract

First, the limitations of the conventional interleaved boost converters in high-step-up and high-output-voltage applications are addressed in this paper. Then, a general derivation law of the nonisolated converters from their isolated counterparts is proposed and studied to give a universal solution for high-performance topology deduction. By employing the direct energy transfer concept, a family of nonisolated high-step-up interleaved boost converters is originated to make the turns ratio of a built-in transformer as another design freedom for the voltage gain extension. The derived converters have the advantages of large voltage conversion ratio, low power switch voltage stress, small input current ripple, and zero-voltage-switching soft-switching performance. The steady-state operation of the derived converter is analyzed, and the circuit performance is summarized to explore its advantages in the high-step-up, high-output-voltage, and large-current conversion systems. Finally, a 1-kW prototype with 40-V input and 380-V output voltages is implemented and tested to show the effectiveness of the derived converters. One of the main contributions of this paper is that a clear picture is made on the universal derivation law to generate high-step-up and high-performance dc/dc converters. [ABSTRACT FROM PUBLISHER]

Published

2011

182. Cascade Three-Level AC/AC Direct Converter.

Author

Li, Lei and Tang, Dongcai

Subjects

*CASCADE converters, *SWITCHING circuits, *ELECTRIC controllers, *CAPACITORS, *ELECTRIC inductors, *FEEDBACK control systems, *ELECTRIC distortion, *PROTOTYPES

Abstract

This paper proposes a novel family of cascade three-level (TL) ac–ac direct converters based on ac switch cells, which transfer unsteady high ac voltage with distortion into regulated sinusoidal voltage with low total harmonic distortion (THD). The topological family includes buck TL–boost, buck–boost TL, and buck TL–boost TL modes. In order to achieve a reliable TL ac–ac conversion, a double transient voltage feedback control strategy of the output voltage and the voltage across the flying capacitor is introduced in this paper. A 500-VA 220-V \pm10% 50-Hz ac/220-V 50-Hz ac prototype is presented with the experimental results to prove that the converters have four improved advantages simultaneously, including lower voltage across power switches, bidirectional power flow, low THD of output voltage, and higher input power factor. [ABSTRACT FROM AUTHOR]

Published

2011

183. Operational Modes and Output-Voltage-Ripple Analysis and Design Considerations of Buck–Boost DC–DC Converters.

Author

Babaei, Ebrahim, Seyed Mahmoodieh, Mir Esmaeel, and Mashinchi Mahery, Hamed

Subjects

*DC-to-DC converters, *EXPERIMENTAL design, *ELECTRIC inductors, *CAPACITORS, *INTEGRATED circuits, *SWITCHING circuits, *SIMULATION methods & models

Abstract

This paper investigates the buck–boost dc–dc converter and the energy transmission techniques in this kind of converter. In this paper, the critical inductance between the continuous conduction and discontinuous conduction modes are determined. In addition, the critical inductance equation between the complete inductor supply mode and incomplete inductor supply mode are calculated. The energy transmission technique and the output voltage ripple (OVR) of a buck–boost converter are analyzed in a specific range of the load and input voltage. The relations between the maximum OVR (MOVR) and the converter component parameters are deduced, and the minimum inductance value is calculated to ensure the MOVR minimization. Experimental and simulation results are used to prove the validity of the presented theoretical subjects. [ABSTRACT FROM AUTHOR]

Published

2011

184. Design and Implementation of a Direct AC–DC Boost Converter for Low-Voltage Energy Harvesting.

Author

Dayal, Rohan, Dwari, Suman, and Parsa, Leila

Subjects

*ELECTRIC current converters, *ENERGY harvesting, *LOW voltage systems, *ELECTRIC current rectifiers, *ELECTRIC power consumption, *CAPACITORS, *ELECTRIC switchgear, *INTEGRATED circuits, *MATHEMATICAL models, *ELECTRIC inductors

Abstract

In this paper, a direct ac–dc power electronic converter topology is proposed for efficient and optimum energy harvesting from low-voltage microgenerators. The converter utilizes the bidirectional current-conduction capability of MOSFETs to avoid the use of a front-end bridge rectifier. It is operated in discontinuous conduction mode and offers a resistive load to the microgenerator. Detailed analysis and modeling of the converter is presented. In such low-power applications, the power consumption of gate drive and control circuits should be minimal. In this paper, they are specifically designed to consume very low power. A suitable startup circuit and auxiliary dc supply circuit is proposed for the implementation of the converter. A low-voltage microgenerator is used to verify the performance and operation of the converter and the gate drive circuits. [ABSTRACT FROM AUTHOR]

Published

2011

185. High Step-Up Trans-Inverse (Tx−1) DC–DC Converter for the Distributed Generation System.

Author

Siwakoti, Yam P., Blaabjerg, Frede, and Chiang Loh, Poh

Subjects

*DC-to-DC converters, *ELECTRIC potential, *MAGNETICS, *CASCADE converters, *RENEWABLE energy sources, *ELECTRIC circuits

Abstract

This paper introduces a new magnetically coupled single-switch nonisolated dc–dc converter with a high-voltage gain. The topology utilizes magnetic coupling for boosting its output voltage, but unlike other converters with coupled magnetics, its voltage gain is increased by reducing its magnetic turns ratio. The name “Trans-inverse (Tx−1)” is thus used for representing this inverse operating principle of the converter. The converter draws a continuous current from the source and is, hence, suitable for many types of renewable sources. Its leakage energy from the coupled magnetics has further been recycled and transferred to the load by an integrated regenerative snubber circuit. Its inclusion of dc-current-blocking capacitors has also helped to prevent core saturation, which, together with other performance features, has been verified experimentally. [ABSTRACT FROM PUBLISHER]

Published

2016

186. A Novel Control for a Cascaded Buck–Boost PFC Converter Operating in Discontinuous Capacitor Voltage Mode.

Author

Badawy, Mohamed O., Sozer, Yilmaz, and De Abreu-Garcia, J. Alexis

Subjects

*AC DC transformers, *CASCADE converters, *ELECTRIC potential, *FEEDBACK control systems, *SMART power grids

Abstract

This paper presents a new dual-switch control structure for an ac/dc noninverting cascaded buck–boost power factor correction converter. The proposed converter operates at a discontinuous capacitor voltage mode providing an inherent high-power factor and a zero voltage turn-off switching. Additionally, the proposed control structure enables for a nondistorted sinusoidal current for a wide range of output voltage levels. Unlike the conventional methods, a mode detector is not required and consequently there is no hard transition between buck and boost modes. Although both converter switches are controlled, only one feedback control loop is required to obtain the desired power flow at a unity power factor. The principle of operation, theoretical analysis, simulation, and experimental results of a 1.6-kW prototype grid-connected converter are presented. The results confirmed the validity of the proposed system under various operating conditions. [ABSTRACT FROM PUBLISHER]

Published

2016

187. A PWM Plus Phase-Shift Controlled Interleaved Isolated Boost Converter Based on Semiactive Quadrupler Rectifier for High Step-Up Applications.

Author

Lu, Yangjun, Xing, Yan, and Wu, Hongfei

Subjects

*ELECTRIC current rectifiers, *ELECTRIC circuits, *ELECTRIC potential, *CASCADE converters, *PULSE width modulation transformers

Abstract

Semiactive quadrupler rectifiers (SAQRs) are proposed in this paper to serve as the secondary rectification circuits, which make the secondary-side voltages to be controllable and help reduce current stress and conduction losses. An interleaved isolated boost converter is developed based on the proposed SAQRs. By utilizing the pulse-width modulation (PWM) plus phase-shift (PPS) control strategy, the primary- and secondary-side voltages are well matched to reduce the current values and circulating conduction losses. With the proposed SAQRs, the voltage gain is extended and the voltage stresses on power devices and passive components used in rectification circuits are reduced to the half of the high output voltage. Hence, the efficiency is improved by using a transformer with a smaller turns ratio and reduced parasitic parameters, and by employing low-voltage rating devices with better switching and conduction performance. With optimal design, lower voltage, and current stresses on the primary-side switches, minimized input current ripple can be realized. Moreover, the zero-voltage turn on switching of the active switches and the zero-current turn off switching of the diodes can be achieved over a wide load and voltage range by the proposed SAQR-based converter and the control strategy. Meanwhile, the higher voltage gain, the lower voltage, and the current stresses on power devices can be obtained with the proposed SAQR-based converter compared with passive quadrupler rectifier-based converter. The feasibility and effectiveness of the proposed SAQRs and the derived converter are verified by a 380-V output prototype. [ABSTRACT FROM PUBLISHER]

Published

2016

188. Model Predictive Voltage Control for Single-Inductor Multiple-Output DC–DC Converter With Reduced Cross Regulation.

Author

Wang, Benfei, Kanamarlapudi, Venkata Ravi Kishore, Xian, Liang, Peng, Xiaoyang, Tan, Kuan Tak, and So, Ping Lam

Subjects

*PREDICTIVE control systems, *CASCADE converters, *ALGORITHMS, *ELECTRIC inductors, *CONDUCTION electrons

Abstract

This paper presents a model predictive voltage control (MPVC) method for the single-inductor multiple-output (SIMO) dc–dc converter. The proposed MPVC method is able to solve the cross-regulation problem, which is a critical issue in SIMO dc–dc converters. The design of the proposed method including augmented state-space model, cost function, enumerated algorithm, and constraints for the SIMO dc–dc converter is discussed. Simulation for the influences of predict horizon NP, control horizon NC, and Lagrange multiplier $\lambda$ on the voltage ripple is conducted to guide the control parameters’ setting for hardware implementation. Steady-state operation and dynamic performance of the proposed MPVC method are conducted in simulation and experiment based on the single-inductor dual-output (SIDO) buck converter to verify the proposed MPVC method. In addition, the comparison between the proposed method and state-of-art methods for the SIMO dc–dc converters is presented. Simulation and experimental results demonstrate that the MPVC method guarantees low cross regulation for the SIMO dc–dc converter in continuous-conduction mode (CCM) and has a fast response speed to variations in load and reference. [ABSTRACT FROM PUBLISHER]

Published

2016

189. Variable Duty Cycle Control for Quadratic Boost PFC Converter.

Author

Chen, Zhengge, Yang, Ping, Zhou, Guohua, Xu, Jianping, and Chen, Zhangyong

Subjects

*POWER factor measurement, *ELECTRIC potential, *AC DC transformers, *POWER resources, *ELECTRIC circuits

Abstract

Compared with constant duty cycle-controlled discontinuous conduction mode (DCM) boost power factor (PF) correction (PFC) converter, constant duty cycle-controlled quadratic DCM–DCM boost PFC converter features with much lower second-order line frequency output voltage ripple, and however, it suffers from low PF. To increase PF of quadratic DCM–DCM boost PFC converter, a variable duty cycle control technique for quadratic DCM–DCM boost PFC converter is presented in this paper. An approximation equivalent for the variable duty cycle is employed to simplify the implementation circuit. The corresponding expressions of PF and output voltage ripple are analyzed. For input voltage range of 100–240 Vac, quadratic DCM–DCM boost PFC converter with variable duty cycle control benefits with very high PF, and tradeoff between PF and output voltage ripple of this converter is analyzed. Experimental results from 100-W prototypes are given to verify the theoretical analysis. [ABSTRACT FROM PUBLISHER]

Published

2016

190. Steady-State and Small-Signal Analysis of High-Voltage Gain Half-Bridge Switched Boost Inverter.

Author

Babaei, Ebrahim, Shokati Asl, Elias, and Hasan Babayi, Mohsen

Subjects

*ELECTRIC inverters, *CAPACITORS, *SHORT circuits, *ELECTRIC potential, *ELECTRIC inductors

Abstract

In this paper, a new topology for half-bridge switched boost inverter (HB-SBI) is proposed. The proposed half-bridge inverter uses more active elements rather than capacitors and inductors in comparison with the conventional half-bridge Z-source inverter with two Z-networks, which results in reduction of weight, size, and cost. Moreover, the proposed inverter has the capability of eliminating inverter leg short-circuit issues and is able to further increase the output voltage level in comparison with its conventional types. Generating zero-level output voltage is also another advantage of this topology. Based on theoretical calculations, the steady-state and small-signal analysis of the proposed topology in different operating modes are performed and the ripple of inductors’ current and capacitors’ voltage are also calculated. A comprehensive comparison is also made between the proposed inverter and the conventional types. Finally, the experimental results are provided to reconfirm the performance of the proposed inverter. [ABSTRACT FROM PUBLISHER]

Published

2016

191. Interleaved Operation of Three-Level Neutral Point Clamped Converter Legs and Reduction of Circulating Currents Under SHE-PWM.

Author

Konstantinou, Georgios, Pou, Josep, Capella, Gabriel J., Song, Kejian, Ceballos, Salvador, and Agelidis, Vassilios G.

Subjects

*CODING theory, *IDEAL sources (Electric circuits), *CASCADE converters, *SEMICONDUCTOR research, *SWITCHING circuits

Abstract

Interleaving of voltage-source converter (VSC) legs enables higher output currents per phase, effectively increasing the power rating without increasing semiconductor ratings. However, the interleaved operation results in circulating currents between each phase converter legs as well as a zero-sequence circulating current (ZSCC), which become quite prominent when the converters operate with low switching frequencies. This paper demonstrates the interleaved operation of three-level converters under selective harmonic elimination pulsewidth modulation (SHE-PWM). A controller for the circulating current within the legs of each phase is also proposed. The controller is used in combination with optimally selected SHE-PWM patterns to generate the maximum number of voltage levels and minimize the peak value of the circulating current. Simulation and experimental results show the interleaved operation and the effect of SHE-PWM pattern selection in the overall system. [ABSTRACT FROM PUBLISHER]

Published

2016

192. A Common Grounded Z-Source DC–DC Converter With High Voltage Gain.

Author

Shen, Hanyun, Zhang, Bo, Qiu, Dongyuan, and Zhou, Liping

Subjects

*DC-to-DC converters, *ELECTRIC potential, *PHOTOVOLTAIC power generation, *SWITCHING circuits, *SWITCHING diodes

Abstract

In this paper, a common grounded Z-source dc–dc converter with high voltage gain is proposed for photovoltaic (PV) applications, which require a relatively high output–input voltage conversion ratio. Compared with the traditional Z-source dc–dc converter, the proposed converter, which employs a conventional Z-source network, can obtain higher voltage gain and provide the common ground for the input and output without any additional components, which results in low cost and small size. Moreover, the proposed converter features low voltage stresses of the switch and diodes. Therefore, the efficiency and reliability of the proposed converter can be improved. The operating principle, parameters design, and comparison with other converters are analyzed. Simulation and experimental results are given to verify the aforementioned characteristics and theoretical analysis of the proposed converter. [ABSTRACT FROM PUBLISHER]

Published

2016

193. Design and Analysis of a High-Efficiency DC–DC Converter With Soft Switching Capability for Renewable Energy Applications Requiring High Voltage Gain.

Author

Das, Moumita and Agarwal, Vivek

Subjects

*DC-to-DC converters, *ELECTRIC inductors, *CAPACITORS, *STRAY currents, *MAGNETIC fields, *CLAMPING circuits, *SWITCHING circuits

Abstract

Renewable sources like solar photovoltaic (PV) and fuel cell stack are preferred to be operated at low voltages. For applications such as grid-tied systems, this necessitates high voltage boosting resulting in efficiency reduction. To handle this issue, this paper proposes a novel high voltage gain, high-efficiency dc–dc converter based on coupled inductor, intermediate capacitor, and leakage energy recovery scheme. The input energy acquired from the source is first stored in the magnetic field of coupled inductor and intermediate capacitor in a lossless manner. In subsequent stages, it is passed on to the output section for load consumption. A passive clamp network around the primary inductor ensures the recovery of energy trapped in the leakage inductance, leading to drastic improvement in the voltage gain and efficiency of the system. Exorbitant duty cycle values are not required for high voltage gain, which prevents problems such as diode reverse recovery. Presence of a passive clamp network causes reduced voltage stress on the switch. This enables the use of low voltage rating switch (with low “on-state” resistance), improving the overall efficiency of the system. Analytical details of the proposed converter and its hardware results are included. [ABSTRACT FROM PUBLISHER]

Published

2016

194. Design of a Modular, High Step-Up Ratio DC–DC Converter for HVDC Applications Integrating Offshore Wind Power.

Author

Hu, Yihua, Zeng, Rong, Cao, Wenping, Zhang, Jiangfeng, and Finney, Stephen J.

Subjects

*HIGH voltages, *DIRECT currents, *DC-to-DC converters, *FAULT tolerance (Engineering), *ELECTRIC power transmission

Abstract

High-power and high-voltage gain dc–dc converters are key to high-voltage direct current (HVDC) power transmission for offshore wind power. This paper presents an isolated ultra-high step-up dc–dc converter in matrix transformer configuration. A flyback-forward converter is adopted as the power cell and the secondary side matrix connection is introduced to increase the power level and to improve fault tolerance. Because of the modular structure of the converter, the stress on the switching devices is decreased and so is the transformer size. The proposed topology can be operated in column interleaved modes, row interleaved modes, and hybrid working modes in order to deal with the varying energy from the wind farm. Furthermore, fault-tolerant operation is also realized in several fault scenarios. A 400-W dc–dc converter with four cells is developed and experimentally tested to validate the proposed technique, which can be applied to high-power high-voltage dc power transmission. [ABSTRACT FROM AUTHOR]

Published

2016

195. A New Family of Zero-Voltage-Transition Nonisolated Bidirectional Converters With Simple Auxiliary Circuit.

Author

Mohammadi, Mohammad Reza and Farzanehfard, Hosein

Subjects

*CONVERTERS (Electronics), *ZERO voltage switching, *ZERO current switching, *RECTIFICATION (Electricity), *ELECTRIC current rectifiers

Abstract

In this paper, a new family of zero-voltage-transition (ZVT) bidirectional converters are introduced. In the proposed converters, soft-switching condition for all semiconductor elements is provided regardless of the power flow direction and without any extra voltage and current stress on the main switches. The auxiliary circuit is composed of a coupled inductor with the converter main inductor and two auxiliary switches. The auxiliary switches benefit from significantly reduced voltage stress and without requiring floating gate drive circuit. Also, by applying the synchronous rectification to the auxiliary switches body diodes, conduction losses of the auxiliary circuit are reduced. In the auxiliary circuit, the leakage inductor is used as the resonant inductor and all the magnetic components are implemented on a single core which has resulted in significant reduction of the converter volume. In the proposed converters, the reverse recovery losses of the converter-rectifying diodes are completely eliminated and hence, using the low-speed body diode of the power switch as the converter-rectifying diode is feasible. The theoretical analysis for a bidirectional buck and boost converter is presented in detail and the validity of the theoretical analysis is justified using the experimental results of a 250-W prototype converter. [ABSTRACT FROM PUBLISHER]

Published

2016

196. Decoupled Current-Balancing Control With Single-Sensor Sampling-Current Strategy For Two-Phase Interleaved Boost-Type Converters.

Author

Chen, Hung-Chi, Lu, Che-Yu, and Huang, Li-Ming

Subjects

*CURRENT balances (Electric meters), *CASCADE converters, *VOLTAGE control, *DIODES, *FIELD programmable gate arrays, *EQUIPMENT & supplies

Abstract

For interleaved boost-type converters, both functions of voltage regulation and current balance are important. In this paper, the decoupled current-balancing control (DCBC) with two parallel loops is proposed. At first, the small-signal transfer functions of the voltage-regulation loop and the current balancing loop to the controller output are derived. The results show that the voltage-regulation loop and the proposed current-balancing loop are nominally decoupled. That is, two PI-type controllers can be designed independently and included to implement the proposed DCBC. Additionally, the single-sensor sampling-current strategy is proposed to obtain two average inductor currents by sensing only the sum of diode currents. All the controllers are implemented in field-programmable gate array (FPGA). The provided simulation and experimental results demonstrate the proposed DCBC. [ABSTRACT FROM PUBLISHER]

Published

2016

197. An Integrated Inductor for Eliminating Circulating Current of Parallel Three-Level DC–DC Converter-Based EV Fast Charger.

Author

Tan, Longcheng, Zhu, Ning, and Wu, Bin

Subjects

*DC-to-DC converters, *DIRECT currents, *POWER electronics, *ELECTRIC inductors, *ELECTRIC potential measurement

Abstract

The parallel three-level dc–dc converter has some merits over the conventional two-level buck converter when employed for fast chargers in a bipolar-dc-bus charging station. It can be directly connected to the bipolar dc bus, and can operate with the total neutral-point current eliminated under the 180°-interleaved mode, which guarantees balanced power consumption and helps decrease dc-bus voltage fluctuation. However, this incurs circulating currents, leading to increased losses and additional current stress to switching devices. To solve this issue, an integrated inductor is proposed in this paper. The inductor has an integrated magnetic core with both output and circulating windings placed on it, producing inductances to filter output currents and to attenuate circulating currents respectively. The circulating inductance can be flexibly adjusted to be much higher than the output inductance, so that the circulating currents can be well attenuated. The output and circulating inductances, along with the ratio between them, are deduced in detail. The current ripples are analyzed and compared under two operation modes with separate and integrated inductors, respectively. The weight, losses, and volume have also been compared between separate and integrated inductors. Both simulation and experimental results are presented to verify the effectiveness of the proposed integrated inductor. [ABSTRACT FROM PUBLISHER]

Published

2016

198. A Peak-Capacitor-Current Pulse-Train-Controlled Buck Converter With Fast Transient Response and a Wide Load Range.

Author

Sha, Jin, Xu, Duo, Chen, Yiming, Xu, Jianping, and Williams, Barry W.

Subjects

*DC-to-DC converters, *PULSE width modulation, *ITERATIVE methods (Mathematics), *ELECTRIC currents, *SIMULATION methods & models

Abstract

It is known that the ripple-based control of a switching dc–dc converter benefits from a faster transient response than a conventional pulse width modulation (PWM) control switching dc–dc converter. However, ripple-based control switching dc–dc converters may suffer from fast-scale oscillation. In order to achieve fast transient response and ensure the stable operation of a switching dc–dc converter over a wide load range, based on a conventional pulse train (PT) control technique, a peak capacitor current PT (PCC-PT) control technique is proposed in this paper. With a buck converter as an example, the operating modes, steady-state performance, and transient respond performance of a PCC-PT controlled buck converter are presented and assessed. To eliminate fast-scale oscillation, circuit and control parameter design considerations are given. An accurate discrete iteration model of a PCC-PT controlled buck converter is established, based on which the effects of circuit parameters on the stability of the converter operating in a discontinuous current mode (DCM), mixed DCM-continuous conduction mode (CCM), and CCM are studied. Simulation and experimental results are presented to verify the analysis results. [ABSTRACT FROM PUBLISHER]

Published

2016

199. High-Efficiency Class- \mboxE^-1 and Class-F/E Power Amplifiers at Any Duty Ratio.

Author

Sheikhi, Akram, Hayati, Mohsen, and Grebennikov, Andrei

Subjects

*POWER amplifiers, *ZERO current switching, *ELECTRIC potential, *ELECTRIC power production, *TECHNICAL specifications, DESIGN & construction

Abstract

In this paper, the Class-Fn/E power amplifier (PA) and the inverse Class-E (Class- \mboxE^-1) PA under zero-current switching and zero-current-derivative switching conditions at any duty ratio are analyzed. The maximum switch voltage and current, output power capability, and element values as functions of the duty ratio are obtained for both classes. The main objective of the analysis is to choose the proper duty ratio to maximize the output power capabilities at optimum conditions. The element values are dependent upon the duty ratio and require a careful selection of the duty ratio to reach desired specification. The effect of the duty ratio D=0.3-0.7 on the performance of the Class- \mboxE^-1 and Class-F3/E PAs is demonstrated. The duty ratio is used not only as the design specification but also as the adjusting parameter for achieving a certain condition. The measured maximum drain efficiency of 88% and 87% are obtained at 4 MHz at 30-dBm input power for the Class-F3/E and Class- \mboxE^-1 PAs, respectively. The results show that lower peak switch voltage and current are obtained in the Class-F3/E PA in comparison with Class- \mboxE^-1 for the same conditions. [ABSTRACT FROM PUBLISHER]

Published

2016

200. High Step-Up DC–AC Inverter Suitable for AC Module Applications.

Author

Arshadi, Sayed Abbas, Poorali, Behzad, Adib, Ehsan, and Farzanehfard, Hosein

Subjects

*ELECTRIC inverters, *DC-AC converters, *ELECTRIC power distribution grids, *PHOTOVOLTAIC power systems, *PERFORMANCE evaluation

Abstract

In this paper, a novel grid-connected high step-up inverter is proposed. The topology is composed of two stages. The first stage is a single-switch high step-up dc–dc converter with bipolar outputs, and the second stage is a conventional half-bridge dc–ac grid-connected inverter. Negative grounding of the photovoltaic (PV) module has resulted in elimination of unwanted ground leakage currents in the PV system. Simple structure, employing few semiconductor switches, simple control, and high efficiency are the features of the proposed topology. Theoretical analysis and principal operation of the circuit are discussed. An experimental prototype is implemented to verify the performance of the proposed inverter. The experimental results confirm the aforementioned features and the theoretical analysis of the converter operation. [ABSTRACT FROM PUBLISHER]

Published

2016