Showing total 1,280 results

151. Modeling and Simulation of a Novel Active Three-Phase Multilevel Power Factor Correction Front End – The “Negev” Rectifier.

Author

Barbie, Eli, Rabinovici, Raul, and Kuperman, Alon

Subjects

*CORRECTION factors, *VOLTAGE control, *ELECTRIC current rectifiers, *HIGH voltages, *SIMULATION methods & models, *ELECTRIC potential

Abstract

This paper presents a modification of the Vienna rectifier (VR) to obtain more than three voltage levels at the DC line connection, while preserving the unity power factor at the AC grid side. The proposed unidirectional multilevel there-phase rectifier, called the “Negev rectifier”, has a reduced device count and utilizes a unique novel Time Division Multiplexed based control scheme, which makes the challenging N-level VR expansion possible. The Negev rectifier can serve as a grid interface for supplying dc voltage to multilevel inverters with 4 up to 7 voltage levels, eliminating the burden of inverter-side voltage balancing control. The Negev hardware can be constructed by two complementary topologies, making it suitable for either high current or high voltage applications. [ABSTRACT FROM AUTHOR]

Published

2020

152. A Universal Blocking-Module-Based Average Value Model of Modular Multilevel Converters With Different Types of Submodules.

Author

Meng, Xuekun, Han, Jintao, Bieber, Levi M., Wang, Liwei, Li, Wei, and Belanger, Jean

Subjects

*MULTILEVEL models, *SEMICONDUCTOR switches, *POWER system simulation, *DYNAMIC simulation, *SEMICONDUCTOR devices, *ELECTRIC network topology

Abstract

The large amount of power electronic submodules and semiconductor switching events in the Modular Multilevel Converter (MMC) introduces several challenges for efficient and accurate Electro-Magnetic Transient (EMT) simulation. Research efforts have focused on developing Average Value Models (AVMs) of MMC that enable fast and accurate dynamic simulation of the converter. This paper proposes a universal blocking-module-based AVM, which can simulate the MMC of different submodule types and provide accurate results for the MMC operating in both blocking and de-blocking modes. An analytical approach is included in the model to calculate the semiconductor losses of different submodule types in the MMC. The proposed model is validated against a detailed switching-based model and the state-of-the-art AVMs in a 41-level two-terminal MMC-HVDC system. [ABSTRACT FROM AUTHOR]

Published

2020

153. Combining Detailed Equivalent Model With Switching-Function-Based Average Value Model for Fast and Accurate Simulation of MMCs.

Author

Meng, Xuekun, Han, Jintao, Pfannschmidt, Joel, Wang, Liwei, Li, Wei, Zhang, Fei, and Belanger, Jean

Subjects

*DYNAMIC simulation, *DIRECT currents, *HIGH voltages, *MODULAR design, *ELECTRIC capacity

Abstract

Modeling and simulation play a vital role in the design and testing of modular multilevel converter (MMC) high voltage direct current (HVDC) systems. Detailed equivalent model (DEM) and switching-function-based average value model (SFB-AVM) are two major types of accurate and efficient models to represent the dynamic response of the MMCs. However, the DEM and the SFB-AVM possess unique benefits depending on the purpose of the simulation studies. The DEM provides a detailed representation of submodule (SM) switching events and individual capacitor ripples. The SFB-AVM provides faster simulation speed by using arm equivalent capacitance. Combining both models in a universal arm equivalent circuit gives the users the choice of selecting the most appropriate modeling method during dynamic simulation. This paper proposes a universal modeling framework combining the DEM with the SFB-AVM which allows the DEM and the SFB-AVM smoothly switch from one to the other during dynamic simulation. The proposed SFB-AVM can accurately represent the MMCs with different SM types. The proposed models are validated in offline and real-time simulation studies which demonstrate the improved simulation speeds of the proposed SFB-AVM over the DEM especially for large numbers of SMs. [ABSTRACT FROM AUTHOR]

Published

2020

154. Combined Control of Grid Connected Converters Based on a Flexible Switching Table for Fast Dynamic and Reduced Harmonics.

Author

Jabbarnejad, Alireza, Vaez-Zadeh, Sadegh, and Jahanpour-Dehkordi, Mohammad

Subjects

*VOLTAGE-frequency converters, *ELECTRIC potential measurement, *RELIABILITY in engineering, *IDEAL sources (Electric circuits), *TORQUE control, *REACTIVE power

Abstract

Grid connected voltage source converters are inevitable means now for expanding and supporting power systems. Nevertheless, their harmonic injection and high frequency switching may cause degradation of power quality and detraction of the equipment reliability. Therefore, the converters injected harmonics must observe the corresponding standards, while lower switching frequencies and rapid transient responses are desirable. In this paper, a new combined control method with a flexible switching table is presented for the converters to enhance the power quality and transient response. The method employs a virtual flux in connection with a combined control for the first time. In comparison with the conventional virtual flux direct power control, the proposed method provides better power quality, reduced THD and faster transient response, in addition to less grid parameters dependency. Compared to the conventional combined control method, it determines more accurately the converter voltage vectors, while avoiding grid voltage measurement and cumbersome controller tuning. [ABSTRACT FROM AUTHOR]

Published

2020

155. A Family of Step-Up Series–Parallel Dual Resonant Switched-Capacitor Converters With Wide Regulation Range.

Author

Xie, Wenhao, Li, Shouxiang, Zheng, Yifei, Smedley, Keyue Ma, Wang, Jianze, Ji, Yanchao, and Yu, Jilai

Subjects

*CAPACITOR switching, *PASSIVE components, *ZERO current switching

Abstract

In this paper, a family of new step-up series–parallel dual resonant switched-capacitor converters (SP-DRSCs) is proposed to extend the conversion ratio for high step-up applications. The converters feature a wide gain range, continuously adjustable, and enhanced light-load voltage regulation. All flying capacitors operate in resonance, eliminating high transient current spikes and charge sharing losses. Thus, zero-current-switching (ZCS) turn-on for all transistors and ZCS turn-off for all diodes are achieved. A comprehensive analysis of the operation principle, voltage-gain curves, stable regulation range, and voltage and current stress is given. An analytical method to quantify the passive component volume for the group of step-up dual resonance switched-capacitor converters is presented. Further design considerations to optimize the passive component volume of the proposed SP-DRSC and the effect of bulky bypass capacitors on the volume are discussed. [ABSTRACT FROM AUTHOR]

Published

2020

156. A Fully Soft Switched Point-of-Load Converter for Resource Constraint Drone Applications.

Author

Qu, Yong, Shu, Wei, and Chang, Joseph S.

Subjects

*CASCADE converters, *ZERO current switching, *DC-to-DC converters, *ZERO voltage switching, *TRIBOELECTRICITY, *VOLTAGE control

Abstract

The power efficiency and weight of present point-of-load (POL) dc–dc converters for drone applications are often compromised because they suffer from large switching losses at continuous conduction mode for heavy loads and excessive hardware overheads at discontinuous conduction mode for light loads. This paper presents a boundary conduction mode (BCM) control scheme for POL converters embodying a single operation mode. This is achieved by means of a hysteresis voltage controller to turn on/off the output power stage when necessary. The proposed BCM control scheme achieves high power efficiency (≥91.2%) over a wide load range (5 mA–1 A) by means of fully soft switching. Specifically, a hysteretic current controller is proposed to realize ZCS, and an adaptive dead time controller is proposed to realize ZVS. Further, the proposed BCM control scheme requires a small output inductor (0.82 μH) by means of designing the customizable peak inductor current. To verify the proposed BCM control scheme, we realize a BCM-based POL converter that features an input voltage range of 5–16 V, output voltage range of 2.5–8 V, switching frequency of 1.5 MHz, peak power efficiency of 96.8%, and ≤35 mV output voltage undershoot/overshoot for 1-A load step. When being benchmarked against state-of-the-art counterparts, the proposed design features the lowest voltage undershoot/overshoot, the highest switching frequency, ∼5.7× smaller inductor, and ∼11% higher power efficiency at light loads. [ABSTRACT FROM AUTHOR]

Published

2020

157. An Interleaved Secondary-Side Modulated LLC Resonant Converter for Wide Output Range Applications.

Author

Li, Zhiqing, Xue, Bo, and Wang, Haoyu

Subjects

*PULSE width modulation transformers, *ELECTRIC current rectifiers, *ZERO voltage switching, *SWITCHING systems (Telecommunication), *METAL oxide semiconductor field-effect transistors, *RESONANT power convertors, *PULSE width modulation

Abstract

In this paper, an LLC type converter with two interleaved pulsewidth modulation (PWM) rectifiers is proposed. Compared with the conventional LLC converter, it achieves a wide voltage regulation range independent of load. In the proposed structure, each secondary-side PWM rectifier can operate individually. With the interleaving technique and shared primary-side switching network, the circuit secondary-side current stress is halved and the primary-side current stress is largely reduced. Besides, the filter capacitor requirement is reduced. Therefore, the proposed structure is a good option for medium/high power wide output range applications. The symmetrical LLC resonant tanks always operate at the resonant frequency, which marks the optimal operation point of the LLC resonant tank. Therefore, the conduction loss is effectively mitigated. In the proposed converter, zero-voltage turning-on (ZVS) of the primary-side MOSFETs can be ensured and is independent of the load. Moreover, the turning-off currents of the primary-side MOSFETs are small and are also load independent. This brings the benefits of minimized circulating current and negligible turning-off loss and no MOSFET turning-off voltage spike. The secondary-side auxiliary MOSFETs turn-on with ZVS and rectifying diodes turn-off with limited di/dt. Topological analysis and experimental results of a 1.3 kW/100 kHz prototype generating 230–440 V output from 390-V input are presented. The prototype demonstrates 97.31% peak efficiency and good performance over a wide output range. [ABSTRACT FROM AUTHOR]

Published

2020

158. Multitransformer Primary-Side Regulated Flyback Converter for Supplying Isolated IGBT and MOSFET Drivers.

Author

Kolincio, Maciej, Chrzan, Piotr J., and Musznicki, Piotr

Subjects

*AC DC transformers, *ELECTRIC current rectifiers, *GALVANIC isolation, *METAL oxide semiconductor field-effect transistors, *SWITCHING power supplies, *MAGNETIC coupling

Abstract

This paper presents primary-side voltage regulated multitransformer quasi-resonant flyback converter (MTFC) for supplying isolated power switch drivers. The proposed topology offers distinct advantages over frequently used flyback converter possessing one high frequency transformer with isolated multiple outputs. Particularly, when a large number of separate dc supply units is required, then MTFC enables improved regular distribution of magnetic coupling between the common primary and the multiple secondary transformers’ windings providing a high degree of galvanic and electromagnetic isolation between multiple outputs. Primary side voltage regulation is based on the average output voltage estimation using auxiliary RDC circuit mounted across the primary windings. Operation principles of MTFC are enhanced with analytical study of cross regulation of multiple output voltages at unbalanced load conditions, indicating reduced voltage deviation of multiple outputs by applying the primary-side average voltage regulation. Experimental results of prototype 2-, 3-, and 6-transformer quasi-resonant flyback converters confirmed their cross regulation quality and application potential for independent multiple output supplies. [ABSTRACT FROM AUTHOR]

Published

2020

159. Burst-Mode and Phase-Shift Hybrid Control Method of LLC Converters for Wide Output Range Applications.

Author

Shi, Lin, Liu, Bangyin, and Duan, Shanxu

Subjects

*PULSE frequency modulation, *CASCADE converters, *ZERO voltage switching, *VOLTAGE references, *RESONANT power convertors

Abstract

For an LLC converter, it is difficult to realize the wide output range with conventional pulse frequency modulation control because of the limited operating frequency. This paper proposes a new hybrid control method. The proposed strategy combines the burst-mode control and phase-shift control methods for the LLC converter. The burst-mode control can regulate the output voltage from zero to its maximum value, and the phase-shift control can reduce the increased resonant current during burst-on time. By using this method, the wide output voltage range is realized with the low resonant current during burst-on time and zero-voltage switch (ZVS) for all switches. The reliability and efficiency of the converter can be improved accordingly. The burst duty ratio is regulated by the reference output voltage, and the phase-shift angle is derived when realizing ZVS for lagging-leg switches. Moreover, the resonant parameters and the maximum phase-shift angle are optimized under the constraints of current stress and ZVS condition. This method is easy to be implemented in a low-cost microcontroller because high-frequency real-time calculations are not necessary. A 1.5-kW prototype is built to verify the feasibility and validity of the proposed control method. [ABSTRACT FROM AUTHOR]

Published

2020

160. A Closed-Loop Modulation Scheme for Duty Cycle Compensation of PWM Voltage Distortion at High Switching Frequency Inverter.

Author

Ren, Ren, Zhang, Fanghua, Liu, Bo, Wang, Fei, Chen, Zichang, and Wu, Jianping

Subjects

*PULSE width modulation transformers, *WIDE gap semiconductors, *HIGH voltages, *PULSE width modulation inverters, *SEMICONDUCTOR switches, *WAGES, *OTOACOUSTIC emissions

Abstract

Wide bandgap semiconductors with fast switching speed capability are becoming an enabler to achieve the higher power density design. However, the further increase of switching frequency cannot continuously improve the power quality of ac-side waveforms in dc–ac/ac–dc application. The main reason is the distortion of pulsewidth modulation (PWM) voltage at switching point under high switching frequency. In general, there are two contributors causing PWM voltage distortions in bridge-based topologies. One is the deadtime, which occupies higher ratio in the small duty cycle case under high switching frequency and induces the voltage errors. The other one is the turn-off transient in the small load current or around the zero-crossing point of the ac-side current, because the relatively slow rising slope of the drain–source voltage will affect the right duty cycle. To solve this issue, this paper proposes a closed-loop modulation scheme to compensate the duty cycle distortion of PWM voltage based on one-cycle control or charge control. Compared to the traditional feedforward type of compensation, the proposed scheme does not need online calculation and instantaneous inductor current sampling, and it shows potential to be a general scheme for variety of topologies and modulations. Simulations and experiments are carried out on a 400-kHz single-phase full-bridge inverter with 400-Hz fundamental frequency to demonstrate the performance of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2020

161. LLC Resonant Converter With Damping Split Inductor Improving Light-Load Regulation Ability.

Author

Jing, Hang, Wang, Junhua, Fang, Zhijian, and Xie, Lijun

Subjects

*PROCESS optimization, *VOLTAGE-frequency converters, *VOLTAGE control, *ELECTRIC potential, *TANKS

Abstract

LLC resonant converters are widely used in On-board Power Converter but the pumping voltage of traditional LLC converter is unavoidable under light-load conditions due to the existence of parasitic parameter. In this paper, an LLC resonant converter with damping split inductor is proposed to improve the light-load regulation capability. The original resonant inductor is divided into two parts in series. Then, a simple damping resistor connected on one part in parallel and the other part can be integrated into the transformer. Using damping split inductor, significant regulation improvements could be achieved under light-load conditions with not any change in control strategy and almost zero hardware cost. In addition, based on impedance analysis of the resonant tank, the effects of the proposed method are analyzed including voltage gain, soft switching characteristics, suppression of high frequency interference components, and system power loss. Moreover, the detailed design process and optimization conditions of the damping split inductor parameters are carefully illustrated. Eventually, the experimental results demonstrate the characteristics mentioned above for the 96 W prototype at the expense of a maximum increase in device loss of 0.85 W. [ABSTRACT FROM AUTHOR]

Published

2020

162. Operating Region Extension of a Modular Multilevel Converter Using Model Predictive Control: A Single Phase Analysis.

Author

Rodriguez-Bernuz, Joan-Marc and Junyent-Ferre, Adria

Subjects

*PREDICTION models, *REAL-time control, *VOLTAGE-frequency converters, *TRAJECTORIES (Mechanics), *IDEAL sources (Electric circuits)

Abstract

The modular multilevel converter is the state-of-the-art topology for voltage source converter HVDC. Despite its advantages, this converter handles large internal low-frequency energy ripples, and the capacitance that supports these dynamics is a key design parameter that affects the operating region of the converter. Different strategies can be found in the literature to increase the feasible region of operation of the converter. Nevertheless, they are typically open loop in nature and use precalculated control references. This paper presents an alternative based on model predictive control that steers the system through optimal control trajectories that are calculated online. This provides feedback and corrective control action in real time. The predictive controller used for this purpose is presented and a linear time-varying approximation is used to reduce the computational burden of the algorithm. The feasible boundaries of the converter are sought and the final performance of the control algorithm is evaluated through detailed simulations using a switching model of the converter. [ABSTRACT FROM AUTHOR]

Published

2020

163. Robust ZAD Sliding Mode Control for an 8-Phase Step-Down Converter.

Author

Repecho, Victor, Biel, Domingo, and Ramos-Lara, Rafael

Subjects

*SLIDING mode control, *ROBUST control

Abstract

This paper describes the design, robustness analysis, and implementation of a zero average dynamics sliding mode control (ZAD–SMC) for a multiphase step-down converter. The ZAD–SMC operates at fixed switching frequency and allows to implement an interleaving technique providing current-ripple cancellation at the converter output. Moreover, the proposed control structure, which is based on a master–slave strategy, includes an equalization technique guaranteeing current sharing among the phases and avoiding undesirable power unbalance. Additionally, a stability analysis considering unmatched losses in the converter phases shows that the design provides asymptotic stability for the overall load range. The controllers are implemented in an FPGA, and all the expected features, such as fast transient response, robustness, fixed switching frequency, interleaving, and current equalization are sustained by the experimental results obtained from using a 1.5-kW prototype. [ABSTRACT FROM AUTHOR]

Published

2020

164. An Ideal DC Transformer for Active DC Distribution Networks Based on Constant-Transformation-Ratio DABC.

Author

Wang, Xiaoming, Peng, Yonggang, Chai, Junwei, Xia, Yanghong, Wei, Wei, and Yu, Miao

Subjects

*DC transformers, *ENERGY storage, *REACTIVE power, *VOLTAGE control

Abstract

This paper employs a single-phase-shift modulated dual-active-bridge converter (DABC), and establishes a small-signal model, which involves its voltage transformation ratio. Then, through a voltage transformation ratio feedback loop, which is feedforward compensated by the port voltages and currents, closed-loop control of the transformation ratio of the DABC is realized. The proposed controller can make the DABC operate in constant transformation ratio mode, and act as an ideal dc transformer in an active dc distribution network. Based on the bidirectional voltage support capability of the proposed dc transformer, the different buses of an active dc distribution network can mutually provide voltage support for each other. Besides, the proposed dc transformer can realize the normalized decentralized power coordination between the energy storage systems at different buses of the active dc distribution network. The feasibility of the proposed dc transformer is verified by several hardware-in-loop tests. [ABSTRACT FROM AUTHOR]

Published

2020

165. Design of Gray Wolf Optimizer Algorithm-Based Fractional Order PI Controller for Power Factor Correction in SMPS Applications.

Author

C., Komathi and M. G., Umamaheswari

Subjects

*CORRECTION factors, *CASCADE control, *REACTION time, *MATHEMATICAL optimization, *CASCADE converters, *SPACE robotics, *MICROCONTROLLERS

Abstract

This paper proposes the design of gray wolf optimizer (GWO) algorithm-based fractional order proportional integral (FOPI) controller for power factor correction (PFC) using interleaved dc–dc single ended primary inductance converter converter with improved performance characteristics such as speed, accuracy, and stability. The detailed analysis and modeling of the proposed converter are presented. The optimal parameters of FOPI controller are obtained using GWO algorithm to improve the speed of response of the system. FOPI controller provides better performance in terms of robustness and stability since it has one more adjustable parameter than the conventional proportional integral (PI) controller. The cascade control strategy is implemented for the proposed converter with GWO-based FOPI controller as inner current and outer voltage controllers for PFC and load voltage regulation. The performance characteristics of the proposed system are analyzed and compared with conventional and other optimization techniques using MATLAB/Simulink software. A prototype of the proposed converter controlled by TMS320C2000 microcontroller for an output power of 200 W is tested and validated with the simulation results. The proposed system is used for powering devices like robots in critical applications such as military, space craft, etc., where stability, speed, and accuracy are major concerns. [ABSTRACT FROM AUTHOR]

Published

2020

166. A Nine-Level Inverter for Low-Voltage Applications.

Author

Zhang, Yunlei, Wang, Qunjing, Hu, Cungang, Shen, Weixiang, Holmes, Donald Grahame, and Yu, Xinghuo

Subjects

*PULSE width modulation transformers, *CAPACITORS, *VOLTAGE control

Abstract

A novel nine-level inverter topology for low-voltage applications is proposed in this paper. Each phase of the inverter is composed of a T-type three‐level cell and an active neutral point clamp three‐level cell. The operation principles and current conduction paths are analyzed in detail and phase-disposition sinusoidal pulsewidth modulation is used to balance voltages of flying capacitors and neutral point. The mathematical relationship between the capacitance and the desired ripple in the inverter output is established to select the intermediate capacitance value. Compared with other nine-level inverters suitable for low-voltage applications, the proposed inverter has advantages in a number of gate drivers, a number of dc sources, and efficiency. Simulation and experimental results under different settings of modulation index, power factor, output frequency, and load are presented to verify the effectiveness and performances of the proposed inverter. [ABSTRACT FROM AUTHOR]

Published

2020

167. Elimination of the Interaction of the Converters in Switch-Linear Hybrid Envelope Tracking Power Supplies.

Author

Wang, Yazhou, Ruan, Xinbo, Jin, Qian, Xi, Huan, Xiong, Xiaoling, Leng, Yang, and Li, Ying

Subjects

*POWER resources, *ARTIFICIAL satellite tracking, *VOLTAGE control

Abstract

As a combination of the switched-mode converter and linear amplifier, the switch-linear hybrid (SLH) envelope tracking (ET) power supply can achieve high efficiency and high tracking bandwidth simultaneously, and it can be classified into three types, namely, series-form, parallel-form, and series–parallel-form. In the SLH ET power supply, interaction may occur between the converters, and as a result, the controlled variable will deviate from its target. In this paper, the interaction in the series-form SLH ET power supply with different structures is analyzed first from the aspects of control and parasitic capacitances, and the feedforward control scheme and/or filter is adopted to eliminate the interaction. Then, for the parallel-form SLH ET power supply, four current control methods are introduced and compared from the current tracking and disturbance-rejection performances, and the method for suppressing the disturbance is presented. Since series–parallel-form SLH ET power supply contains at least three converters, the interaction is more complex. On the basis of the analysis of the series-form and parallel-form SLH ET power supplies, the interaction between the converters in series–parallel-form SLH ET power supply is analyzed and followed by the corresponding elimination method. Finally, one series-form, and one parallel-form SLH ET power supplies are implemented in the lab, and the experimental results verify the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2020

168. LQR Control of Single-Phase Grid-Tied PUC5 Inverter With LCL Filter.

Author

Arab, Naima, Vahedi, Hani, and Al-Haddad, Kamal

Subjects

*PULSE width modulation transformers, *HARMONIC distortion (Physics), *RENEWABLE energy sources, *VOLTAGE control, *FILTERS & filtration

Abstract

This paper presents the current control design procedure of a single-phase grid-tied five-level packed U-cell inverter (PUC5) with an LCL output filter. The PUC5 inverter is used as an interface of renewable energy sources, such as solar applications. The LCL filter is calculated according to the grid-tied operation and converter ratings. An optimal controller, based on a linear quadratic regulator with integral action, is designed to inject a sinusoidal current with low harmonic distortion at unity power factor. For that design, the PUC5 inverter is modelled in the D–Q frame. The sensorless voltage control is incorporated into the switching technique to balance the PUC5 capacitor voltage and generate a five-level waveform at the output. Experimental tests are performed on a laboratory benchmark to confirm the theoretical design. The results prove the efficiency and accuracy of the adopted control strategy in a steady state and under transients of grid current, grid inductance, ac and dc voltage amplitudes. [ABSTRACT FROM AUTHOR]

Published

2020

169. A Hybrid Boost–Flyback/Flyback Microinverter for Photovoltaic Applications.

Author

Zhang, Feng, Xie, Yunxiang, Hu, Yanshen, Chen, Gang, and Wang, Xuemei

Subjects

*LOW voltage systems, *ELECTRIC network topology, *VOLTAGE control, *ELECTRIC inductance, *ELECTRIC potential, *TOPOLOGY

Abstract

For photovoltaic applications, the flyback microinverter with pseudo-dc-link is popular as a simple topology but brings large transformer turns ratio and thus large leakage inductance, which would deteriorate the converter efficiency. To solve this issue, based on the nonisolated pseudo-dc-link structure, this paper proposed a hybrid boost–flyback/flyback (BF/F) microinverter. This new topology is operated at the BF mode for the most segment of a half grid cycle and the F mode for the rest. During the BF mode, high voltage gain with low voltage stress is easily available in minimized transformer turns ratio. Besides, the leakage energy is recycled and the turn-off voltage spike of the main switch is clamped, as a result of a passive snubber inherently contained in this mode. Given that the BF mode is lack of step-down function, the F mode is developed to regulate the output voltage even for values lower than the input voltage. The operation and characteristic of the hybrid BF/F microinverter in boundary conduction mode are analyzed in detail, and the mathematical expression of reference current is derived theoretically to guarantee high power quality. Finally, a 240 W prototype was implemented to validate the theoretical analysis and the benefits of the proposed topology. [ABSTRACT FROM AUTHOR]

Published

2020

170. Symmetrical Three-Vector-Based Model Predictive Control With Deadbeat Solution for IPMSM in Rotating Reference Frame.

Author

Kang, Shin-Won, Soh, Jae-Hwan, and Kim, Rae-Young

Subjects

*TORQUE control, *PREDICTIVE control systems, *PREDICTION models, *VOLTAGE references, *SYNCHRONOUS electric motors, *COST functions, *ERROR functions

Abstract

This paper proposes a model predictive control based on three voltage vectors for an interior permanent-magnet synchronous motor in a rotating reference frame. The proposed method can obtain the reference voltage vector quickly by predicting only one voltage vector during one sampling period using the characteristics of the deadbeat control. In addition, to obtain better steady-state performance, the optimal vector duration ratios can be obtained from the cost function to minimize the error between the predicted reference voltage vector and the synthesis vector by using the switching sequence relationship of a symmetrical three vector, which is different from applying a single voltage vector in the conventional finite-control-set model predictive control (FCS-MPC). To verify the proposed method, the experimental results are compared with the conventional FCS-MPC and two-vector-based MPC. [ABSTRACT FROM AUTHOR]

Published

2020

171. Switching-Sequence Control of a Higher Order Power-Electronic System Driving a Pulsating Load.

Author

Chatterjee, Debanjan and Mazumder, Sudip Kumar

Subjects

*TIME management, *TIME perspective, *LYAPUNOV functions, *VOLTAGE control

Abstract

In a conventional linear-control design of a higher order power-electronic system (PES), the gains of the control laws are typically determined by small-signal analysis of the averaged model of the PES. The closed-loop control of such a PES (driving a pulsating load that periodically shifts the equilibrium) using its small-signal model is often found to be unsatisfactory with regard to the overall stability and performance. To address the challenges in control design for a PES driving such a nonlinear time-varying pulsating load, this paper delineates an optimal switching-sequence-based control (SBC) scheme, which applies stability-bound switching sequence(s) to the PES. A novel method has been formulated to ensure the reachability of the PES dynamics based on its switching sequence in terms of the time horizon of the switching sequence and the allocation of this time among the switching states of the same switching sequence. This is ascertained by modeling the PES and the pulsating load as a nonlinear map and then using this map and multiple Lyapunov functions determined by solving a set of linear-matrix inequalities corresponding to each of the switching states of a given switching sequence. It has been further shown that the knowledge of the stability bounds of a reachable switching sequence helps in reducing the online computation time for optimal SBC associated with solving the optimization problem by reducing the overall search space. Finally, to validate the optimal SBC, an experimental GaN-FET-based 100-kHz  Ćuk-PES has been fabricated and tested on a pulsating load. The overall SBC is implemented on a low-cost TMS320F28335 DSP, which also implements an observer to preclude the need for plurality of sensors for the higher order Ćuk-PES. The overall performance of the SBC is found to be satisfactory under varied dynamical conditions. [ABSTRACT FROM AUTHOR]

Published

2020

172. Two-Phase Interleaved Boost PFC Converter With Coupled Inductor Under Single-Phase Operation.

Author

Yang, Fei, Li, Chunhui, Cao, Yong, and Yao, Kai

Subjects

*DC-to-DC converters, *POWER density, *VOLTAGE control

Abstract

When the interleaved boost power-factor correction (PFC) converter operates in a light load (<15% of nominal load), the phase-shedding control is commonly used to increase the converter's efficiency. If the inductors are coupled for high power density applications, because of the strong mutual effects of the coupled inductor, the switching of the operation phase may lead to a current flowing in the non-operation phase. In this paper, a two-phase interleaved boost PFC converter with a coupled inductor in the single-phase operation was analyzed. The operation modes of the converter in a switching cycle and a half line cycle were presented, and the modes’ variation with the load changes, as well as the power distribution, was provided. A 1-kW prototype was built to verify the analysis, and it was shown that the non-operation phase also delivers some power, which may worsen the converter's efficiency and distort the average input current waveform. [ABSTRACT FROM AUTHOR]

Published

2020

173. Analysis and Design of LLC Converter Considering Output Voltage Regulation Under No-Load Condition.

Author

Kim, Jong-Woo, Park, Moo-Hyun, Lee, Byoung-Hee, and Lai, Jih-Sheng

Subjects

*ELECTRICAL conductivity transitions, *ELECTRIC potential, *GOVERNMENT regulation, *RESONANT power convertors, *ELECTRIC current converters, *VOLTAGE control, *CASCADE converters

Abstract

In the no-load condition, LLC converter usually fails to regulate its output voltage although it operates at a high switching frequency. Till now, it is hard to obtain the exact relationship between design parameters and the maximum switching frequency for no-load regulation capability. In this paper, a specific criterion for no-load regulation of LLC converter is provided, without using active components or other modulation schemes. By analyzing the macroscopic switching period and microscopic switching transition in the no-load condition, it is shown that not only the peaking resonant current during the switching transition, but also the resonant tank design affect the no-load regulation of the LLC converter, which affects the no-load regulation capability. Furthermore, the relationship among design parameters is analyzed and the design guideline is also provided to achieve no-load regulation at the specified maximum switching frequency. To verify the effectiveness of the proposed design, 400 V input and 50 V/200 W output prototype is built and tested. [ABSTRACT FROM AUTHOR]

Published

2020

174. Ultra-Wide Output Voltage Range Power Supply Based on Modular Switched-Converter Principle.

Author

Lu, Yangjun, Wu, Hongfei, Tu, Bo, Li, Mengxi, Xia, Yuzheng, and Xing, Yan

Subjects

*POWER resources, *CASCADE converters, *ELECTRIC potential, *DC-to-DC converters, *BALANCE of power, *VOLTAGE control

Abstract

A systematic method for developing ultra-wide output voltage range power supply based on modular switched-converter principle is proposed in this paper. The basic symmetric switched-converter (SSC) module is composed of two dc–dc modules, two diodes, and one active switch. Multi-stage SSC modules are generated by symmetric cascaded connection method. By controlling the active switches in multi-stage SSC modules, the connections of all the dc–dc modules’ output ports can be changed flexibly among series, parallel, and partial–parallel–partial-series connections. Then segmented regulation can be realized and system output voltage range can be widely extended. Meanwhile, the voltage range of each dc–dc module can be narrowed and the voltage/current stress can be reduced to simplify the design, increase device utilization ratio, and improve overall efficiency. A full-bridge isolated buck–boost converter with a semiactive rectifier, which features soft-switching and wide voltage adjustment range, is adopted as the dc–dc module to realize the proposed system. Input current sharing control strategy is adopted to ensure proper power balancing in all possible operating modes. The stability of the proposed system is also explored. Simulation and experimental results are provided to verify the effectiveness and advantages of the proposed system configuration, the switched-converter principle, and the control strategies. [ABSTRACT FROM AUTHOR]

Published

2020

175. A Coordinated Strategy of Low-Speed and Start-Up Operation for Medium-Voltage Variable-Speed Drives With a Modular Multilevel Converter.

Author

Zhao, Fangzhou, Xiao, Guochun, Zhu, Tianhua, Zheng, Xu, Wu, Zhiqian, and Zhao, Tong

Subjects

*MOTOR drives (Electric motors), *HIGH voltages, *CAPACITORS, *VOLTAGE control

Abstract

The low-frequency fluctuation over the capacitor voltages seriously limits the development of medium-voltage variable-speed drives with a modular multilevel converter (MMC). Therefore, this paper presents an effective strategy of the low-speed and start-up operation for an MMC-based motor drive. The proposed strategy properly coordinates the improved injection and the reduced average capacitor voltage with high applicability. The specific interactions between the control parameters and the system metrics are analyzed to give the detailed steps of the parameters designing. Hence, based on the derivations, the proposed method enables the low-frequency operation under the nominal load torque with decreased injected components and reduced peak capacitor voltages. What is more, two start-up strategies that, respectively, aim at different objectives for the coordinated strategy are proposed, indicating satisfying control performances for the practical applications. The injected common-mode voltage and circulating current in the proposed method are designed to have a great reduction. Thus, the unfavorable risks for the motor are evidently decreased for better stability. The reduced peak current also lessens the high stress on switching devices with desirable reliability. The simulation and experiment results of an MMC-based motor drive prototype prove the effectiveness and superiority of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2020

176. Noninverting Buck–Boost DC–DC Converter Using a Duobinary-Encoded Single-Bit Delta-Sigma Modulator.

Author

Cho, Young-Kyun and Lee, Kwang Chun

Subjects

*DC-to-DC converters, *DELTA-sigma modulation, *HIGHER order transitions, *VOLTAGE control

Abstract

This paper presents a delta-sigma modulation (DSM) control scheme for noninverting buck–boost (NIBB) converter that features a duobinary encoding for four power switch controls. The proposed scheme converts the single-bit output of the modulator into a 1.5-b signal to enable a three-phase operation comprising the charging, bypassing, and discharging phases. This control method reduces both switching and conduction losses by changing only two switches in each period, thus, achieving high conversion efficiency. A smooth mode transition is provided by the DSM controller, which automatically and continuously determines the operating mode of the converter. Thus, the dead zone can be effectively released with improved transient responses. Furthermore, the spurious tones in the output are effectively eliminated by the robust noise shaping capability of the modulator. The proposed DSM-based NIBB converter was implemented on a 180-nm CMOS. It regulated the output in the range of 2.0–4.6 V with input voltage of 2.5–5.0 V, and the maximal load current was 500 mA. The converter showed a peak efficiency of 94.8% at 90-mA load and the output voltage ripples were maintained under 18 mV. A low noise floor with the first spurious peak located –92 dBc below the signal was achieved across all mode operations. In addition, the converter occupied a small chip area of 1.51 mm2. [ABSTRACT FROM AUTHOR]

Published

2020

177. Predictive Delta Sigma Modulation for Three-Phase to Three-Phase Matrix Converters.

Author

Mir, Tabish Nazir, Singh, Bhim, and Bhat, Abdul Hamid

Subjects

*DELTA-sigma modulation, *MATRIX converters, *IDEAL sources (Electric circuits), *VOLTAGE-frequency converters, *VECTOR spaces

Abstract

As research in matrix converters (MCs) has progressed over time, space vector modulation has emerged as the most popular technique for their modulation. Lately, model predictive control (MPC) has also been explored for the modulation and control of MCs, primarily gaining popularity due to the ease in realization of multiple objectives, as desired in MCs. However, multi-objective MPC employs assignment of weights to each control objective, wherein weight tuning is either empirical in nature or computationally cumbersome. This paper proposes a new modulation technique for MCs, inspired from delta sigma modulation for voltage source converters, that can be used for load voltage and source current control of MCs. Since source currents are samples of the load current envelope, it is required that this envelope be known for the control of source current. To eliminate load current sensors, predictive model of the load is used in envelope estimation. Further, independent switching schemes are generated for each objective, and an error minimization approach is used in integrating the two schemes into a final state selection, hence eliminating weighing factors. Unlike MPC, error predictions for all states of MCs, are not needed, hence facilitating easier implementation without significant processor burden, besides ensuring the quality of response. [ABSTRACT FROM AUTHOR]

Published

2020

178. Three-Phase Four-Switch Converter for SPMS Generators Based on Model Predictive Current Control for Wave Energy Applications.

Author

Zarei, Mohammad Ebrahim, Ramirez, Dionisio, Nicolas, Carlos Veganzones, and Arribas, Jaime Rodriguez

Subjects

*WAVE energy, *MAXIMUM power point trackers, *INSULATED gate bipolar transistors, *PERMANENT magnet generators, *PREDICTION models, *ENERGY harvesting, *VOLTAGE control

Abstract

This paper presents a model predictive current control (MPCC) for three-phase four-switch converters (TPFSC) connected to surface permanent magnet synchronous generators (SPMSGs) in oscillating water column (OWC) wave energy plants, that brings some benefits over the existing control methods used in this type of plants. The proposed MPCC for TPFSC follows the current references with great accuracy, whereas the switching frequency of the insulated-gate bipolar transistor (IGBTs) is fixed and low. This method minimizes the current reference tracking error, and its fast response makes it suitable for the power take-off systems present in wave energy converters. Furthermore, the system features a fast capacitor voltage offset suppression control. The dynamic performance and the voltage offset control of the proposed strategy for TPFSC feeding a SPMSG is evaluated in the Simulink environment. Later, experimental studies are carried out on an 8.7 kW laboratory SPMSG prototype. Finally, the capability of the proposed method to harvest the maximum energy from irregular waves is assessed using an OWC power plant emulator. [ABSTRACT FROM AUTHOR]

Published

2020

179. An Enhanced Model Predictive Control Using Virtual Space Vectors for Grid-Connected Three-Level Neutral-Point Clamped Inverters.

Author

Alhosaini, Waleed, Wu, Yuheng, and Zhao, Yue

Subjects

*VECTOR spaces, *ELECTRIC inverters, *PREDICTION models, *RENEWABLE energy sources, *IDEAL sources (Electric circuits), *COST functions

Abstract

Reliability of power systems can be improved by the use of voltage source inverters (VSIs) with fast dynamic control, which can handle uncertainties induced by renewable energy resources and nonlinear loads. To ensure fast-dynamic response and simplified controller design, various model predictive control (MPC) methods are investigated in this paper. In the conventional MPC design for three-level VSIs, the cost function requires an additional term to ensure the balance of the neutral-point voltage (NP-V), which however can considerably impact the main goal of the MPC. To address this issue, an enhanced MPC using virtual space vectors is proposed, which allows the use of a significantly reduced weighting factor for the term in the cost function for NP-V balancing, while retaining fast-dynamic response. Additionally, the proposed MPC leads to reduced harmonic distortion in the VSI output voltage and current. Both simulation and controller hardware-in-the-loop studies are performed to demonstrate the effectiveness of the proposed enhanced MPC in an operating microgrid under both steady-state and fast-transient conditions. [ABSTRACT FROM AUTHOR]

Published

2019

180. Analysis of the Neutral-Point Voltage Self-Balance Mechanism in the Three-Level Full-Bridge DC−DC Converter by Introduction of Flying Capacitors.

Author

Liu, Peng and Duan, Shanxu

Subjects

*CAPACITORS, *CAPACITOR switching, *ELECTRIC potential, *POWER resources, *VOLTAGE control

Abstract

The three-level full-bridge (TLFB) dc−dc converter has been widely used in high-voltage, high-power applications. In the experimental test, the neutral-point voltage deviation appears; moreover, it has also been found out that if the flying capacitors are introduced, the input capacitor voltages could realize self-balance even if no active balancing solutions are adopted. In the previous publications, the role of flying capacitors is generally considered to extend the range of soft switching; however, the self-balance ability has not been mentioned or investigated in any publications thus far. In order to fill this gap, this paper provides the detailed mode operation analysis of the TLFB converter and reveals the cause of the imbalance. In addition, the mechanism of the self-balance ability provided by the flying capacitors is explained in detail, which gives a deep insight into the converter. At last, the influence factor of the voltage error in steady state has been analyzed, and the specific expression of the voltage error is also derived. The feasibility of the theoretical analysis is verified by the simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

181. Predictive Control With Discrete Space-Vector Modulation of Vienna Rectifier for Driving PMSG of Wind Turbine Systems.

Author

Lee, June-Seok, Lee, Kyo-Beum, and Blaabjerg, Frede

Subjects

*TORQUE control, *ELECTRIC current rectifiers, *WIND turbines, *PERMANENT magnet generators, *LOW voltage systems, *VECTOR control, *TORQUE

Abstract

This paper proposes the predictive control with the discrete space-vector modulation (DSVM) for Vienna rectifier connecting to the permanent magnet synchronous generator (PMSG) of the wind turbine system (WTS). Since Vienna rectifier has the special operation principle, Vienna rectifier generates only the feasible eight voltage vectors, which can be a candidate vector for the predictive control, depending on the sign of the input currents. In the proposed predictive control, the feasible voltage vectors are extended from 8 to 19 consisting the 8 original voltage vectors and 11 virtual voltage vectors by using the DSVM for improving the current quality related to the torque ripple, vibration, and noise, and the neutral-point voltage balance with low voltage ripple is guaranteed by using the offset value calculated based on the model of two dc-link capacitors in Vienna rectifier. The scheme for reducing calculation burden is applied in selecting the candidate vector. In addition, the limited operation range for the maximum torque per ampere control of PMSG connected to Vienna rectifier is analyzed. The performance of the proposed predictive control with DSVM for Vienna rectifier with PMSGs is verified in simulation and experiment. [ABSTRACT FROM AUTHOR]

Published

2019

182. Capacitor Voltage Balancing and Stabilization for 4-Level Hybrid-Clamped Converter Using Selected Switching States.

Author

Pan, Jianyu, Na, Risha, Yang, Yong, Cai, Haiwei, and Xu, Longya

Subjects

*CAPACITOR switching, *CAPACITORS, *ELECTRIC potential, *VOLTAGE control

Abstract

Without active control, the voltage fluctuations of the dc-link and flying capacitors in a 4-level hybrid-clamped converter (4L-HCC) become excessively large in low-frequency operation. This paper studies the switching state redundancy inherent in a 4L-HCC and proposes a new capacitor voltage balancing and stabilizing method to minimize the dc-link and flying capacitor voltage fluctuations. A straightforward algorithm is developed based on a logic table to select the suitable switching states. Verified by simulation and experimental testing results, the new method and algorithm virtually eliminate all the big voltage fluctuations of capacitors at low and zero frequencies, greatly enhancing the robustness and reliability of a 4L-HCC. The capacitor size can be reduced by more than 80% compared with the conventional method. [ABSTRACT FROM AUTHOR]

Published

2019

183. Current Control of Grid-Tied LCL-VSI With a Sliding Mode Controller in a Multiloop Approach.

Author

Martins, Leandro Tome, Stefanello, Marcio, Pinheiro, Humberto, and Vieira, Rodrigo Padilha

Subjects

*STATE feedback (Feedback control systems), *IDEAL sources (Electric circuits), *SLIDING mode control, *SYSTEM dynamics

Abstract

Despite several studies and approaches, the design of current controllers for grid-connected converters via LCL filters is still a challenging task. This is mainly due to the parametric uncertainties and the grid background voltage distortions to which the system is submitted. In order to overcome these inherent system challenges, this paper proposes a multiloop control framework that simplifies the system dynamics of the overall circuit by splitting it in two equivalent sub-circuits. An inner loop is implemented as a fast sliding mode controller that controls the filter capacitor voltage in a fast and robust way. As a result, the plant, viewed by the outer loop, yields a voltage-controlled voltage source connected to the grid through an L filter. Thus, multiple resonant controllers are included in the state-space representation of this simplified system, allowing the design of a state-feedback controller in the outer loop for asymptotic tracking of the grid current with disturbance rejection of the grid background voltage. Here, a discrete linear quadratic regulator algorithm is used for designing the state-feedback gains. A simple design procedure is presented, as well as simulations and experimental results, to show the good performance of the proposed control scheme even under significant uncertainties and disturbances of the system. [ABSTRACT FROM AUTHOR]

Published

2019

184. An Improved Open-Switch Fault Diagnosis Technique of a PWM Voltage Source Rectifier Based on Current Distortion.

Author

Shi, Tiancheng, He, Yigang, Wang, Tao, Tong, Jin, Li, Bing, and Deng, Fangming

Subjects

*FAULT diagnosis, *IDEAL sources (Electric circuits), *POWER semiconductors, *PULSE width modulation inverters, *PULSE width modulation, *ELECTRIC current rectifiers

Abstract

Numerous studies show that power semiconductors are significant contributors to the overall failure rate of pulsewidth modulation (PWM) voltage source rectifier (VSR) systems. Aimed at this problem, this paper presents an improved diagnosis system for open-circuit faults of a three-phase PWM VSR based on ac current distortion characteristics, which consists of a diagnosis module, a register module, and a decision module. The diagnostic module employs a hysteresis comparator to judge the change trend of the currents, and thereby diagnoses the single open-circuit (OC) faults. The register module is employed to achieve multi-switch OC fault diagnosis, and the decision module is used to output the final result. The proposed method extends the previous work to multi-switch OC fault conditions as well as improves the diagnosis accuracy. The experimental results show that the proposed method can correctly achieve fault diagnosis, including 6 kinds of single-switch faults and 15 kinds of different double-switch faults. Additionally, the proposed method also shows superior anti-interference performance and high robustness under abrupt load transient conditions, different power factor conditions, unbalanced and/or distorted grid voltage conditions, and different ac filter structure conditions. Furthermore, the average diagnostic time of this method is only 3.68 ms. [ABSTRACT FROM AUTHOR]

Published

2019

185. Sliding Mode Control Scheme for a CLLC Resonant Converter.

Author

Zou, Shenli, Mallik, Ayan, Lu, Jiangheng, and Khaligh, Alireza

Subjects

*SLIDING mode control, *ROTARY converters, *DYNAMICAL systems, *ELECTRIC vehicles, *PLUG-in hybrid electric vehicles

Abstract

In this paper, a comprehensive sliding mode control (SMC) loop design for a CLLC resonant converter is proposed. The major objectives of the proposed SMC are to improve the converter dynamics and to achieve a tight output voltage regulation with respect to any parameter variations and external disturbances. The sliding surface coefficients are selected to ensure both large- and small-signal stability for the robustness of the converter under different operating conditions. Furthermore, system dynamic performances considering the error dynamics and overshoots are investigated. To validate the proposed algorithm, a hardware prototype of a bi-directional CLLC resonant converter for plug-in electric vehicle applications is developed and tested up to 1 kW, and the effectiveness of the proposed control solution is verified by the load transients and start-up tests. At a 100% step-change in load power, the SMC achieves 1 ms settling time, which is approximately 0.9 ms faster than the conventional proportional integral control strategy. [ABSTRACT FROM AUTHOR]

Published

2019

186. A Minimum Switch Five-Level Unidirectional Rectifier Without Any Voltage Balancing and Pre-Charging Circuitry.

Author

Mukherjee, Debranjan and Kastha, Debaprasad

Subjects

*ELECTRIC current rectifiers, *ELECTRIC potential, *SEMICONDUCTOR devices, *ELECTRICAL conductivity transitions, *SEMICONDUCTOR diodes, *VOLTAGE control, *THRESHOLD voltage

Abstract

This paper proposes a three-phase, five-level, non-regenerative pulsewidth modulated rectifier using only two active switches (minimum required) per phase, which drastically reduces gate driver requirement and hardware complexity. It draws sinusoidal input current at close to unity power factor. All the semiconductor devices are rated at only one fourth of the dc-link voltage, and none of them requires any transient voltage balancing snubber. A total of 8 out of the 14 diodes per phase undergo soft switching transition under all operating conditions, which increases its efficiency. No extra hardware circuitry for balancing the flying capacitors (FCs) or the dc-link mid-point voltage are required, which further reduces hardware complexity and increases the conversion efficiency. The proposed topology does not need any sophisticated startup procedure for charging the FCs either, which solves the problem of semiconductor overvoltage during starting. A 3-kW laboratory prototype is built to experimentally verify the proposed topology. The maximum efficiency obtained from the prototype is 98.7%, and it is always more than 96% for the load range from 15% to its rated. [ABSTRACT FROM AUTHOR]

Published

2019

187. Voltage Autobalance Characteristic Analysis and Clamp Circuits Design of Hybrid-Clamped Three-Level LLC Converter.

Author

Shi, Lin, Liu, Bangyin, Duan, Shanxu, He, Jian, Cai, Tao, Sun, Jieyi, and Sheng, Wanxing

Subjects

*CLAMPING circuits, *PULSE width modulation transformers, *ELECTRIC potential, *CAPACITORS, *VOLTAGE control, *DIODES

Abstract

The operating principle of the clamp circuits like clamping diodes and flying capacitor in three-level LLC converter is different from other three-level converters, because the mean value of the resonant tank current is always zero and pulse-frequency modulation control is generally used instead of pulsewidth modulation control. And the converter with only the clamping diodes or flying capacitor is difficult to realize voltage balance. In this paper, the characteristics of the three-level LLC converter with single clamp circuit are first analyzed. Then, the operation principle of the hybrid-clamped circuit under the unbalanced voltages on input capacitors is described with the mode analysis, based on which the mechanism for voltage autobalance is elaborated and the effects of two clamp circuits are derived. Then, the design of the clamping diodes and the flying capacitor is also involved. Finally, a three-level LLC converter prototype is built and the experimental results verify the validity of the theoretical analysis and design. [ABSTRACT FROM AUTHOR]

Published

2019

188. Generalized Model Predictive Control Method for Single-Phase N-Level Flying Capacitor Multilevel Rectifiers for Solid State Transformer.

Author

Kim, Si-Hwan, Kim, Rae-Young, and Kim, Sang-Il

Subjects

*CAPACITORS, *PREDICTIVE control systems, *FLIGHT, *PREDICTION models, *VOLTAGE control, *COST functions

Abstract

This paper introduces a generalized control method based on the finite control set-model predictive control for a single-phase N-level flying capacitor multilevel rectifier used for solid state transformers. Unlike the conventional finite control set-model predictive control, the proposed method does not use the switching function to calculate the predicted value of the grid current. The proposed method also predicts the dc-link voltage without switching function so that it enables each leg voltages to be controlled stably and independently. Therefore, the number of states to be considered is significantly reduced, in addition to the computational time; and the level expansion of the flying capacitor multilevel rectifier is facilitated. In addition, since the cost function for controlling the grid current and that for controlling the voltage of the flying capacitor is separated, weighting factors are not required. The validity of the proposed method was verified by a simulation of a single-phase 11-level flying capacitor multilevel rectifier using Powersim software, and an experiment on a single-phase 5-level flying capacitor multilevel rectifier prototype. [ABSTRACT FROM AUTHOR]

Published

2019

189. Power Flow Management in MTdc Grids Using Series Current Flow Controllers.

Author

Balasubramaniam, Senthooran, Ugalde-Loo, Carlos E., Liang, Jun, and Joseph, Tibin

Subjects

*VOLTAGE control, *VOLTAGE-frequency converters, *IDEAL sources (Electric circuits), *ELECTRIC potential

Abstract

Power flow control in multiterminal HVdc (MTdc) grids is essential to restrict operation within permissible limits. A current flow controller (CFC) can achieve this. In this paper, the modeling, control, and simulation of resistive, RC-circuit-based, and capacitive CFCs is carried out. CFC prototypes have been developed and an MTdc grid test-rig has been employed for experimental validation. Results show that all devices achieve an effective power flow management. The impact of CFC deployment in future MTdc grids is assessed on droop-controlled converters. A voltage compensation-based method is proposed to minimize power deviations during unscheduled line current control. A protection scheme has been assessed under faults. [ABSTRACT FROM AUTHOR]

Published

2019

190. Right-Half-Plane Zero Elimination of Boost Converter Using Magnetic Coupling With Forward Energy Transfer.

Author

Poorali, Behzad and Adib, Ehsan

Subjects

*MAGNETIC coupling, *ENERGY transfer, *VOLTAGE control, *TRANSFER functions, *FREQUENCY response, *MAGNETIC control

Abstract

Control-to-output transfer function of the classical boost converter in continuous conduction mode contains a right-half-plane (RHP) zero that limits its frequency response. In this paper, to eliminate this zero and enhance the dynamic performance, a forward path for energy transfer to output within the on interval of the power switch is provided using the magnetic coupling. This approach simply eliminates the RHP zero by introducing an inductor coupled to the boost inductor, a diode, and a capacitor into the classical boost topology. In addition, the provided forward path enhances the voltage gain, which makes it possible to achieve a smaller operating duty cycle and reduced voltage stress for the power switch in applications with large voltage conversion ratios. Using this approach does not complicate the control structure, and a traditional single-loop voltage control scheme can be used to regulate the output voltage. The proposed approach is analytically examined by obtaining the averaged state-space model of the resulting converter, and a criterion to eliminate the RHP zero is presented. Experimental results from an implemented laboratory prototype for 48- to 200-V voltage conversion and 100-W nominal power are provided. [ABSTRACT FROM AUTHOR]

Published

2019

191. An Extended DPWM Strategy With Unconditional Balanced Neutral Point Voltage for Neutral Point Clamped Three-Level Converter.

Author

Chen, Kewei, Jiang, Weidong, and Wang, Peixia

Subjects

*PULSE width modulation transformers, *VOLTAGE control, *ELECTRIC potential, *VECTOR spaces, *PULSE width modulation

Abstract

According to different clamping methods, nine modes (C_MODE1-9) of the traditional discontinuous pulsewidth modulation (DPWM) for neutral-point-clamped three-level converter have been revealed. Since traditional DPWM cannot balance neutral point (NP) voltage under the full range of modulation index (MI) and power factor (PF), two extended modes (E _MODEs) are proposed in this paper, which can balance NP voltage. The proposed extended discontinuous pulsewidth modulation (EDPWM) is characterized by using C_MODEs and E_MODEs alternately.Therefore, EDPWM can balance NP voltage under the full range of MI and PF. Since the switching numbers under C_MODE and E_MODE in one switching cycle are two and three, respectively, the switching loss under EDPWM is lower than that under other pulsewidth modulation (PWM) strategies. The performance of EDPWM is analyzed and compared with traditional DPWM, space vector PWM (SVPWM) and virtual SVPWM (VSVPWM) in terms of switching loss, waveform quality, and the ability of NP voltage control. Finally, the feasibility and superiority of the proposed method are verified by experiments. [ABSTRACT FROM AUTHOR]

Published

2019

192. Voltage-Boosted Current-Mode Wireless Power Receiver for Directly Charging a Low-Voltage Battery in Implantable Medical Systems.

Author

Lee, Sang-Han, Bang, Jun-Suk, Yoon, Kye-Seok, Gwon, Hui-Dong, Kim, Sang-Won, Cho, In-Kui, Hong, Sung-Wan, and Cho, Gyu-Hyeong

Subjects

*ELECTRIC batteries, *MEDICAL supplies, *WIRELESS power transmission, *VOLTAGE regulators, *VOLTAGE-frequency converters

Abstract

In this paper, a resonant current-mode receiver is studied to charge low-voltage batteries wirelessly for supplying medical implantable systems. To increase efficiency, the root-mean-square (rms) current in the LC tank of the receiver (RX) is reduced by using a voltage-boosted current-mode (VBCM) receiver. This receiver combines the conventional current-mode receiver with a switched-capacitor converter to boost the voltage instantaneously at the switching node ($V_{X}$) of coil. Owing to the suggested technique, the receiver directly charges a low-voltage battery while maintaining a small rms current without using a complex voltage regulator. The receiver achieves an efficiency as high as 84.7% with a 1.1 V battery while operating at the resonant frequency ($f_{{\text{reso}}}$) of 6.78 MHz. The power delivered to the output ($P_{O}$) is in the range from 1.5 to 50 mW. The VBCM receiver was fabricated by 180 nm CMOS technology with a total active area of 0.22 mm2. [ABSTRACT FROM AUTHOR]

Published

2019

193. Topology and Modulation Scheme for Three-Phase Three-Level Modified Z-Source Neutral-Point-Clamped Inverter.

Author

Ho, Anh-Vu and Chun, Tae-Won

Subjects

*TOPOLOGY, *VOLTAGE control

Abstract

This paper presents the topology and modulation technique of a three-phase three-level modified Z-source neutral-point-clamped (MZS-NPC) inverter, which combines a modified Z-source impedance network and a three-phase three-level NPC inverter. The boost factor of the proposed MZS-NPC inverter is twice as high as the three existing representative topologies combing an impedance network with a three-level NPC inverter. A modulation scheme for the proposed topology, based on a maximum boost control method, is designed to achieve the maximum voltage gain with simple implementation and to balance the dc-link neutral-point voltage. A closed-loop control of the ac load voltage in the fuel-cell or photovoltaic applications based on the proposed inverter is realized, in order to supply a desired voltage to the critical load in islanding mode of a microgrid. The boosting ability and operation validity of the proposed topology and modulation technique are demonstrated with simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

194. Near-Unity Power Factor, Voltage Step-Up/Down Conversion Pulse-Width Modulated Switching Rectification for Wireless Power Transfer Receiver.

Author

Fan, Philex Ming-Yan and bin Mohd Daut, Mohamad Hazwan

Subjects

*WIRELESS power transmission, *ELECTRIC current rectifiers, *AC DC transformers, *ELECTRIC potential, *VOLTAGE control, *ENERGY transfer, *PULSE width modulation, *THERMOELECTRIC power

Abstract

The pulse-width modulated (PWM) switching rectification that can achieve a high power factor (PF) for increasing the energy transfer efficiency between an LC resonator and a rectifier and voltage step-up and -down conversion is proposed for a wireless power transfer (WPT) receiver. The proposed method can emulate the switching rectifier as a resistive load by using an inductor and integrated phase synchronizers. Additionally, similar to a switched-inductor converter that controls the duty cycle ratio (D), the proposed PWM rectifier can control the output voltage VOUT when the input is a rectified, wirelessly coupled voltage instead of a constant voltage. Thus, unlike a conventional PWM switching rectifier for ac mains, an additional voltage conditioning circuit would not be needed after the proposed rectifier for WPT. The proposed PWM switching rectification is implemented in the AMS 0.18 μm 1.8 V/5 V CMOS process. PF = 1 is measured, indicating the most efficient energy transfer, compared to only 0.55–0.65 in a peak detection rectifier. Additionally, 88.2% of peak power conversion efficiency of the switching rectifier is achieved, and the maximum output power is 80.3 mW at 500 kHz of the WPT frequency. Moreover, the measured voltage conversion ratios ranging between 0.73× and 2× are demonstrated in this paper. [ABSTRACT FROM AUTHOR]

Published

2019

195. A New Five-Level T-Type Nested Neutral Point Clamped (T-NNPC) Converter.

Author

Bahrami, Ahoora and Narimani, Mehdi

Subjects

*COST functions, *CAPACITOR switching, *FLY control, *VOLTAGE control, *CAPACITORS, *PREDICTION models, *CONVERTERS (Electronics), *ELECTRIC network topology, *DEVIATION (Statistics)

Abstract

This paper presents a new five-level T-type nested neutral point clamped (T-NNPC) converter. The proposed five-level T-NNPC topology is very attractive for medium-voltage applications as it can work in a wide range of voltages without the need of devices in series, and fewer components compared to the other five-level topologies. A model predictive control (MPC) strategy is also developed for the proposed converter to control the output currents at different output frequencies, and control flying capacitor voltages. A discrete-time model of the converter is developed and the control objectives that are the output currents and flying capacitor voltages are defined regarding switching states. A cost function is defined to minimize the deviation of the predicted values of the control objectives from their desired values. During each sampling time, the best switching state is selected and applied to the converter. The performance of the proposed five-level T-NNPC and the developed MPC strategy is studied in the MATLAB/Simulink environment, and the feasibility of the converter is evaluated experimentally. [ABSTRACT FROM AUTHOR]

Published

2019

196. Highly Efficient Bridgeless Dual-Mode Resonant Single Power-Conversion AC–DC Converter.

Author

Kim, Sooa, Kwon, Bong-Hwan, and Kim, Minsung

Subjects

*ZERO current switching, *ELECTRIC current rectifiers, *AC DC transformers, *SWITCHING circuits, *VOLTAGE control, *DIODES, *RESISTOR-inductor-capacitor circuits

Abstract

This paper presents a bridgeless dual-mode single power-conversion ac–dc converter that can achieve a high conversion efficiency. By adopting a bidirectional switch, we remove a full-bridge diode rectifier from the grid side of the proposed converter, and thereby, reduce the number of components and the primary-side conduction loss. To adapt the converter to 1-kW power applications with a bidirectional switch, we used a series-resonant circuit in the output voltage doubler on the secondary side. The series-resonant circuit also provides zero-current switching turn-off at the output diode, and thereby, reduces the reverse-recovery loss. To attain medium–high power capability with an appropriate transformer, the proposed converter operates in both discontinuous conduction mode and continuous conduction mode. The operation principle of the converter is presented and analyzed. By using the dual-mode control algorithm, the proposed converter achieves a high power factor of 0.994 and maximum efficiency of 97.3 $\%$. Experimental results for a prototype 1-kW ac–dc converter verify these characteristics. [ABSTRACT FROM AUTHOR]

Published

2019

197. A Hybrid 7-Level Inverter Using Low-Voltage Devices and Operation With Single DC-Link.

Author

Yadav, Apurv Kumar, Gopakumar, K., R, Krishna Raj, Umanand, Loganathan, Bhattacharya, Subhashish, and Jarzyna, Wojciech

Subjects

*PULSE width modulation transformers, *INDUCTION motors, *INDUCTION machinery, *SEMICONDUCTOR devices, *VOLTAGE control, *POWER resources, *CAPACITORS

Abstract

This paper proposes a new 7-level inverter topology for induction motor drives. It is a hybrid topology formed by cascading a 5-level active neutral-point-clamped inverter with a 3-level T-type converter. It is obtained using low-voltage semiconductor devices with voltage blocking capability of Vdc/3 and Vdc/6. The topology uses three floating capacitors per phase, which are balanced within a pulsewidth modulation (PWM) switching duration using switching-state redundancies for each pole-voltage level. Topology forms two stacks at the front-end, which requires individual symmetrical dc source. The analysis of switching loss and conduction loss is performed and compared with some of the existing 7-level multi-level inverters reported in various literatures to show the advantages of the proposed topology. Furthermore, the single dc source operation with two stacked capacitors and closed-loop control of neutral-point voltage using symmetrical six-phase induction motor is proposed. The voltage-control algorithms for floating capacitors and dc-link stacked capacitors are proposed, which are independent of load power factor and modulation index. Open-loop V/f and closed-loop rotor field oriented control are performed, and various results at steady and transient states are presented to validate the aforementioned claims. [ABSTRACT FROM AUTHOR]

Published

2019

198. A Power Quality Improved EV Charger With Bridgeless Cuk Converter.

Author

Kushwaha, Radha and Singh, Bhim

Subjects

*BATTERY chargers, *ELECTRIC power, *SEMICONDUCTOR diodes, *ELECTRIC vehicles, *VOLTAGE control

Abstract

An improved bridgeless (BL) Cuk converter-based electric vehicle (EV) battery charger with high power factor and increased efficiency is designed and developed in this paper. It provides low cost and high-power-density-based charging solution for the EV. This charger incorporates less number of devices operating over one switching cycle, which reduces the additional conduction loss incurred by a diode bridge rectifier of the conventional charger. Hence, it improves the charger's efficiency. The added advantage of the proposed topology is that the unwanted capacitive coupling loop is removed, as well as the unwanted conduction through the body diode of the inactive switch in the previously developed BL Cuk converter is avoided. This significantly improves the charger's efficiency. For the constant current and constant voltage charging, the commands are synchronized by a flyback converter. The proposed charger draws a sinusoidal current from ac mains and the total harmonic distortion in the supply current is reduced to the limits specified by the IEC 61000-3-2 guidelines. The improved efficiency and power quality indices of the proposed charger are investigated to demonstrate its satisfactory charging operation at all operating conditions. [ABSTRACT FROM AUTHOR]

Published

2019

199. A Soft-Switching Step-Down PFC Converter with High Power Factor Using Auxiliary Flyback Circuit.

Author

Hosseinabadi, Farzad, Adib, Ehsan, and Mazaheri Tehrani, Behrooz

Subjects

*CONVERTERS (Electronics), *DIODES, *ELECTRIC circuits, *SEMICONDUCTOR devices, *SINUSOIDAL projection (Cartography)

Abstract

In this paper, a new soft-switching bridgeless single-phase power factor correction converter is introduced and analyzed. Employing an auxiliary flyback circuit, existing dead angle in the input current is eliminated while softswitching is achieved. The flyback converter processes only small amount of output power. Therefore, conduction losses of its bridge diode and semiconductor devices are low. Also, the auxiliary flyback converter provides soft-switching condition for buck switches. All semiconductors are turned on and off under soft-switching condition. In addition to reduction of switching losses, diode's reverse-recovery problems are eliminated due to soft-switching condition. The proposed approach takes advantage of operating under discontinuous conduction mode to shape the input current into sinusoidal form inherently. Experimental results are reported for a 120-W prototype at 110 Vrms input and 48-V output. The results demonstrate efficiency of 93% at nominal load condition. Furthermore, the input current harmonics fulfill IEC61000-3-2 (Class D) standard as well. [ABSTRACT FROM AUTHOR]

Published

2019

200. Integrated Control of Five-Level Diode-Clamped Rectifiers.

Author

Montero-Robina, Pablo, Salas, Francisco, Gordillo, Francisco, and Umbria, Francisco

Subjects

*DIODES, *ELECTRIC current rectifiers, *CONVERTERS (Electronics), *CAPACITORS, *MODULATION theory

Abstract

This paper presents an approach for dealing with the control of five-level, diode-clamped rectifiers. The control of such converters is challenging, as voltage balancing among capacitors is not a trivial task. Some of the existing approaches that cope with this problem use specific modifications of one of the traditional modulation techniques, such as using redundant vectors in space vector modulation (SVM). The main feature of the proposed technique is that part of the modulation is considered in the system equations and, in this way, the voltage balance can be solved designing a specific controller for this problem. As a result, several levels are used within a switching period. Furthermore, it is shown that the proposed approach hardly affects the control of active and reactive powers and total dc-link voltage in such a way that the well-known direct power control can be applied. As a consequence, the resultant modulation stage is simpler than other techniques based on, e.g., SVM. The effectiveness and good performance of the system under the proposed control approach are validated by both simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019