Showing total 122 results

1. Energization Transient Suppression of 750 kV AC Filters Using a Preinsertion Resistor Circuit Breaker With a Controlled Switching Device.

Author

Chen, Xiaohui, He, Chunying, Deng, Junbo, Zhu, Xiaoguang, Zhang, Guanjun, Ni, Hui, Ma, Feiyue, and Chen, Lei

Subjects

*VOLTAGE references, *SWITCHING circuits, *VOLTAGE control, *ELECTRIC resistors

Abstract

Different from typical circuit breakers, breakers used to switch AC filters in convertor stations have to operate frequently according to the real-time operation mode and daily load changes. Therefore, the performance of filter breakers decreases very quickly, which leads to frequent accidents. Both preinsertion resistors and controlled switching devices can suppress switching transients. In this paper, a comparative analysis of whether a controlled switching device and preinsertion resistor should be adopted is carried out using PSCAD. The transient is calculated as the combined result of the switching angle and preinsertion resistor value, and the optimal configurations are proposed. After determining the resistor value and whether a controlled switching device should be included, the reference voltage of the arrester should be reevaluated. [ABSTRACT FROM AUTHOR]

Published

2022

2. IGBT Series Connection With Soft Switching and Power Recovery in Driver Power Supply.

Author

Guerrero-Guerrero, A. F., Ustariz-Farfan, A. J., Tacca, H. E., and Cano-Plata, E. A.

Subjects

*POWER resources, *INSULATED gate bipolar transistors, *POWER semiconductor switches, *HIGH voltages, *TRANSISTORS

Abstract

The emergence of applications which require high-voltage switches has created a tendency to use semiconductor device series stacks. These series stacks permit operation at blocking voltages above semiconductor elements’ nominal voltage. Insulated-gate bipolar transistors (IGBT) are currently utilized for controllability and switching speed, when these topologies are employed. The main challenge therewith is guaranteeing voltage balance between IGBTs, both when blocked and when switching transistors. Most of the methods which have been proposed to mitigate static and dynamic voltage unbalances increase transistor losses. The series stack loss-less high voltage switch (LHVS) which mitigates voltage unbalances, thus reducing switching losses, is presented in this paper. LHVS consists of a circuit, which ensures soft IGBT switching, an energy recovery circuit, and a gate delay compensation circuit. Additionally, the insulation voltage level is guaranteed to be equal between control circuit and high-voltage side of each IGBT. The operating principle of the LHVS is detailed in this paper, as is experimental validation which has been performed for three series stack modules. Static unbalances are reduced to 1%, while the differences between collector–emitter voltage curves in switching “on” do not surpass 8 ns, and switching losses are reduced by 41%, as compared to the hard-switching topology. [ABSTRACT FROM AUTHOR]

Published

2019

3. A Switched-Capacitor DC-DC Converter Powering an LC Oscillator to Achieve 85% System Peak Power Efficiency and −65dBc Spurious Tones.

Author

Urso, Alessandro, Chen, Yue, Staszewski, Robert Bogdan, Dijkhuis, Johan F., Stanzione, Stefano, Liu, Yao-Hong, Serdijn, Wouter A., and Babaie, Masoud

Subjects

*PHASE noise, *FREQUENCY changers, *VOLTAGE-controlled oscillators, *SWITCHING circuits, *LOGIC circuits

Abstract

In this paper, we propose a new scheme to directly power a 4.9–5.6GHz LC oscillator from a recursive switched-capacitor DC-DC converter. A finite-state machine is integrated to automatically adjust the conversion ratio and switching frequency of the converter such that its DC output voltage is within ±5% of the desired 1V across input voltage range 1.3–2.2V and < 2mA load current conditions. A gate-driver circuit is embedded in each switch of the converter to guarantee constant on-resistance across PVT variations without sacrificing device reliability. Furthermore, a spur reduction block (SRB) is embedded in the oscillator to suppress the ripple induced spurs by stabilizing its tail current. Both the converter and the oscillator are implemented in 40-nm CMOS technology. The measured peak power efficiency of the converter is 87%, while its spot noise is < 1.5nV/ $\sqrt {\mathrm{ Hz}}$ , which does not degrade the phase noise of the oscillator. The SRB suppresses the spur to < −65dBc under the 30mVpp ripple of the converter. [ABSTRACT FROM AUTHOR]

Published

2020

4. Investigation of a New Modular Multilevel Converter With DC Fault Blocking Capability.

Author

Hu, Xing, Zhang, Jianzhong, Xu, Shuai, and Jiang, Yongjiang

Subjects

*CASCADE converters, *POWER transmission, *LOW voltage systems, *ELECTRIC power transmission, *ELECTRIC circuits

Abstract

Modular multilevel converter (MMC) has been a promising candidate in high voltage direct current (HVdc) transmission systems. Due to the features of simple structure, low cost, and low power losses, half-bridge (HB) is usually adopted as the submodule circuit in the traditional MMC. However, an HB submodule circuit-based MMC does not have the capability of blocking dc short-circuit fault, which obstructs the development of low-cost HVdc systems with overhead lines. In order to solve this problem, an MMC with active clamped T-type submodule (ACTSM) to own dc fault blocking capability is proposed in this paper. Compared with other submodule circuits, the proposed ACTSM has many features, such as symmetrical blocking capability, low power losses, low voltage stress, and low amount of independent drive signals. The topology, operation principle, dc fault blocking capability, and distribution of power losses of the ACTSM are presented in this paper. The effectiveness of the ACTSM-based MMC is validated by both simulations and experiments. [ABSTRACT FROM AUTHOR]

Published

2019

5. Modulated Model Predictive Control of Modular Multilevel Converters in VSC-HVDC Systems.

Author

Mahmoudi, Hamid, Aleenejad, Mohsen, and Ahmadi, Reza

Subjects

*PREDICTIVE control systems, *CASCADE converters, *PREDICTION models, *ELECTRICAL engineering, *DIRECT currents

Abstract

This paper proposes a new modulated model predictive control method for the control of modular multilevel converters (MMCs) in voltage source converter-high voltage dc systems. The proposed method retains the advantages of the conventional finite control set-model predictive control methods by programing the nonlinear properties of the MMC into the design calculations while minimizing the ac line and circulating current ripples and steady-state error by generating modulated switching signals with a fixed switching frequency. In this paper, first, the predictive modeling of the MMC is provided. Next, the proposed control method is described. Then, the application of the proposed method to an MMC system is detailed. Finally, experimental results from an MMC system connected to a three-phase grid are provided to validate the theoretical outcomes. [ABSTRACT FROM AUTHOR]

Published

2018

6. Load-Independent Class E/EF Inverters and Rectifiers for MHz-Switching Applications.

Author

Aldhaher, Samer, Yates, David C., and Mitcheson, Paul D.

Subjects

*SWITCHING circuits, *ZERO voltage switching, *ELECTRIC current rectifiers, *WIDE gap semiconductors, *WIRELESS power transmission

Abstract

This paper presents a unified framework for the modeling, analysis, and design of load-independent Class E and Class EF inverters and rectifiers. These circuits are able to maintain zero-voltage switching and, hence, high efficiency for a wide load range without requiring tuning or use of a feedback loop, and to simultaneously achieve a constant amplitude ac voltage or current in inversion and a constant dc output voltage or current in rectification. As switching frequencies are gradually stepping into the megahertz (MHz) region with the use of wide-bandgap (WBG) devices such as GaN and SiC, switching loss, implementing fast control loops, and current sensing become a challenge, which load-independent operation is able to address, thus allowing exploitation of the high-frequency capability of WBG devices. The traditional Class E and EF topologies are first presented, and the conditions for load-independent operation are derived mathematically; then, a thorough analytical characterization of the circuit performance is carried out in terms of voltage and current stresses and the power-output capability. From this, design contours and tables are presented to enable the rapid implementation of these converters given particular power and load requirements. Three different design examples are used to showcase the capability of these converters in typical MHz power conversion applications using the design equations and methods presented in this paper. The design examples are chosen toward enabling efficient and high-power-density MHz converters for wireless power transfer (WPT) applications and dc/dc conversion. Specifically, a 150-W 13.56-MHz Class EF inverter for WPT, a 150-W 10-MHz miniature Class E boost converter, and a lightweight wirelessly powered drone using a 20-W 13.56-MHz Class E synchronous rectifier have been designed and are presented here. [ABSTRACT FROM AUTHOR]

Published

2018

7. A Modulation Technique for Neutral Point Voltage Control of the Three-Level Neutral-Point-Clamped Converter.

Author

Chen, Hsin-Chih, Tsai, Meng-Jiang, Wang, Yao-Bang, and Cheng, Po-Tai

Subjects

*SWITCHING circuits, *CLAMPING circuits, *VOLTAGE regulators, *ELECTRIC current converters, *ELECTRONIC modulation

Abstract

The neutral-point voltage-balancing control is a critical issue of a neutral-point-clamped converter. The conventional control strategy is to inject the specific zero-sequence voltage to regulate the redundant vector, but it is unacceptable to the three-phase four-wire system. This paper provides a neutral-point voltage-balancing control by the dipolar modulation, and the control freedom of the zero-sequence voltage is flexible. Therefore, the proposed method is suitable for both three-phase three-wire and three-phase four-wire systems. Besides, the proposed method improves the control dynamic in a reactive power system. The proposed neutral-point voltage-balancing control is verified by the mathematical analysis and experimental results. The control dynamic, power loss estimation, and the output current performance are analyzed in this paper. [ABSTRACT FROM PUBLISHER]

Published

2018

8. Principle and Topology Synthesis of Integrated Single-Input Dual-Output and Dual-Input Single-Output DC?DC Converters.

Author

Chen, Guipeng, Jin, Zhufeng, Deng, Yan, He, Xiangning, and Qing, Xinlin

Subjects

*ZERO voltage switching, *SWITCHING circuits, *ZERO current switching, *DC-to-DC converters, *INDUSTRIAL electronics

Abstract

In applications that demand single-input dual-output (SIDO) or dual-input single-output (DISO) dc–dc converters, employing two separate single-input single-output (SISO) converters is a solution. However, the number of components is doubled, resulting in high overall cost. In order to reduce costs, this paper proposes a novel topology synthesis methodology, with which a variety of SIDO and DISO dc–dc converters with reduced components can be derived. The principle of topology synthesis states that integrated SIDO and DISO dc–dc converters can be easily developed from conventional SISO converters by replacing a diode with a basic cell inclusive of additional input/output port. The principle is effective for many SISO dc–dc converters, and as an example, topology synthesis based on buck, boost, buck–boost, Cuk, sepic, and zeta SISO converters is performed in this paper. In order to achieve better understanding of the proposed converters, the integrated SIDO Cuk converter is specifically analyzed and experimentally verified. In comparison with the conventional scheme of two separate SISO Cuk converters, good cross regulation is retained while the number of diodes, inductors, and capacitors is reduced in the proposed SIDO Cuk converter. In addition, zero-voltage-switching operation of one switch is achieved, contributing to lower switching losses. Finally, a prototype circuit with 48-V input and 156 V/1 A, 24 V/4 A outputs is built to validate the theoretical analysis. [ABSTRACT FROM PUBLISHER]

Published

2018

9. DTC of Three-Level NPC Inverter Fed Five-Phase Induction Motor Drive With Novel Neutral Point Voltage Balancing Scheme.

Author

Payami, Saifullah, Behera, Ranjan Kumar, and Iqbal, Atif

Subjects

*ELECTRIC inverters, *INDUCTION motors, *VOLTAGE control, *TORQUE control, *CAPACITORS, *SWITCHING circuits

Abstract

In this paper, direct torque control (DTC) of five-phase induction motor (FPIM) is implemented using three-level neutral point clamped (TL-NPC) inverter. One of the advantages of three-level inverter over two-level one for DTC operation is the low torque ripple. Also TL-NPC inverter through space vector modulation technique gives low $ dv/dt$ transition with better voltage waveform. By applying conventional lookup table for DTC, the TL-NPC inverter does not ensures lower $dv/dt$ transition. In this paper, a novel switching scheme for DTC of FPIM using TL-NPC inverter is proposed that ensures the low $ dv/dt$ transition and balancing of dc-link capacitor voltages of TL-NPC inverter. To form the lookup table for DTC operation, instead of using voltage vectors directly, virtual vectors (VVs) are utilized. Two switching states are used in one sample time to generate a VV in $\alpha \beta$ plane, which gives zero resultant voltage in $ xy$ plane. The switching strategy ensures low number of transitions to reduce the switching losses. The switching state redundancies are used in a novel way to balance the dc-link capacitor voltages without using any additional hardware. The proposed technique to balance the dc-link capacitor voltage gives lower switching frequency. The MATLAB/Simulink environment is used for the simulation and the results are validated through experiments. [ABSTRACT FROM AUTHOR]

Published

2018

10. A Space Vector Pulse Width Modulation for Five-Level Nested Neutral Point Piloted Converter.

Author

Li, Junjie, Jiang, Jianguo, and Qiao, Shutong

Subjects

*ELECTRIC current converters, *CASCADE converters, *PULSE width modulation, *PULSE modulation, *POWER capacitors

Abstract

This paper introduces a novel five-level nested neutral point piloted (NNPP) converter and analyzes the operating principle of five-level NNPP converter. This paper presents a novel space vector pulse width modulation (SVPWM) algorithm based on gh coordinate for five-level NNPP converter. First, the common-mode voltage is reduced by choosing the appropriate redundant switching states. After that, the floating-capacitor voltage balance control strategy is presented. The appropriate switch combinations of each phase are determined by the control requirements of floating-capacitor voltages respectively and the hardware mapping method of the switching states is presented. Furthermore, the neutral-point voltage balance control strategy is presented. In order to balance the dc-link capacitor voltages, the seven-segment switching sequence is selected according to the control requirements of dc-link capacitor voltages and the neutral-point voltage regulatory factor is introduced to regulate the durations of the redundant switching states in a switching cycle. Finally, the validity of the novel SVPWM algorithm with decoupling control strategies of floating-capacitor voltages and dc-link capacitor voltages is verified by the experimental results of five-level NNPP converter under steady-state and dynamic conditions. [ABSTRACT FROM AUTHOR]

Published

2017

11. Analysis of Reference Error in High-Speed SAR ADCs With Capacitive DAC.

Author

Li, Cheng, Chan, Chi-Hang, Zhu, Yan, and Martins, Rui P.

Subjects

*SUCCESSIVE approximation analog-to-digital converters, *ERROR correction (Information theory), *REFERENCE circuits

Abstract

The high-speed successive-approximation-register (SAR) analog-to-digital converters (ADCs) rely on the switched capacitive digital-to-analog converter (CDAC) to perform the fast transition, which causes voltage ripples at the output of the reference circuits. Such ripples lead to the reference error that eventually prolongs the time for DAC settling. To minimize such error with a short available time, it either demands a power-hungry reference buffer or large die area for the decoupling. In this paper, we offer a comprehensive analysis of the reference errors in SAR ADCs with a practical reference network circuit (RNC) in consideration. A circuit model is developed in order to quantify the error amplitude for the critical DAC settling condition. Based on the proposed model, the settling behavior of the DAC with reference buffer can be precisely characterized, leading to a better understanding about the design tradeoff of the RNC. Finally, the developed model is verified by both circuit level simulations and measurement results. [ABSTRACT FROM AUTHOR]

Published

2019

12. A Dual-Output Switched Capacitor DC–DC Buck Converter Using Adaptive Time Multiplexing Technique in 65-nm CMOS.

Author

Kilani, Dima, Mohammad, Baker, Alhawari, Mohammad, Saleh, Hani, and Ismail, Mohammed

Subjects

*COMPLEMENTARY metal oxide semiconductors, *CAPACITOR switching, *WEARABLE technology

Abstract

This paper presents an area- and power-efficient dual-output switched capacitor (DOSC) dc–dc buck converter for wearable biomedical devices. The DOSC converter has an input voltage range between 1.05 and 1.4 V and generates two simultaneous regulated output voltages of 1 and 0.55 V. The DOSC consists of two main blocks: a switched capacitor regulator and an adaptive time multiplexing (ATM) controller. The switched capacitor regulator generates a single regulated voltage using pulse frequency modulation based on a predetermined reference voltage. In addition, the ATM controller generates two simultaneous output voltages and eliminates the reverse current using pulse width modulation during the switching between the output voltages. Addressing the reverse current problem is important to reduce the output voltage droop and improve the performance. The proposed converter supports load currents of 10– $350~\mu \text{A}$ and 1– $10~\mu \text{A}$ at load voltages of 1 and 0.55 V, respectively. The DOSC circuit is fabricated in 65-nm CMOS, and it occupies an active area of 0.27 mm2. Measured results show that a peak efficiency of 78% is achieved at a load power of $300~\mu \text{W}$. [ABSTRACT FROM AUTHOR]

Published

2018

13. Evolving Fault and Parallel Switching for SF6 Circuit Breakers.

Author

Heiermeier, Helmut and Raysaha, Rosy Balaram

Subjects

*OCEAN waves, *SWITCHING circuits, *FLOW simulations, *FORECASTING

Abstract

A special stress for circuit breaker is the occurrence of evolving fault or parallel switching condition. These switching cases are not standardized by international standards, but may occur in service and may create problems for the breaker. In the past, it was a problem mainly with oil circuit breakers and some types of air-blast circuit breakers but lesser known with SF6 circuit breakers. In the meantime, with upcoming new switching technologies along with changed operating duties, some doubts exist that these switching cases may become an issue again. This paper explains in detail the background of these stresses and presents a method to evaluate the capability of SF6 circuit breakers for such situations. The theoretical evaluation involves network calculations, gas flow simulations, and dynamic dielectric analysis. It is important to note here that several tests have been done in the past for evolving and parallel switching faults for both puffer as well as self-blast circuit breakers with the knowledge available at that time. These test results are used to validate the outcome of the theoretical evaluation which will help in better prediction of the circuit breaker behavior before performing actual tests. It can be concluded that theoretical simulation may, in majority of the cases, serve as sufficient proof to show feasibility for such cases. [ABSTRACT FROM AUTHOR]

Published

2020

14. 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

15. 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

16. Experimental Design of Fixed Switching Frequency Model Predictive Control for Sensorless Five-Level Packed U-Cell Inverter.

Author

Sebaaly, Fadia, Vahedi, Hani, Kanaan, Hadi Y., and Al-Haddad, Kamal

Subjects

*PREDICTIVE control systems, *SWITCHING circuits, *FREQUENCY changers, *ELECTRIC inverters, *VOLTAGE control, *MATHEMATICAL optimization

Abstract

In this paper, a fixed switching frequency model predictive current controller is designed and implemented on a sensorless five-level packed U-cell (PUC5) inverter interfacing the utility. The predictive control methodology is based on a voltage vector generation technique for the cost function optimization by nullifying its derivative. The aim of the controller is to allow a fixed-frequency operation with no iterations while operating as a utility line current regulator. A pulsewidth modulator based on employing PUC5 redundant switching states fixes the PUC5 auxiliary dc bus capacitor voltage to its desired level with no necessity of a regulator; the overall technique reduces system complexity with less sensors and no loops in the predictive algorithm making it suitable for industrial applications. System discrete model is developed and experimental results verify the performance of the designed controller in making a fast response in regulating the grid current and balancing the capacitor voltage. [ABSTRACT FROM AUTHOR]

Published

2019

17. Active Gate-Driver Withdv/dtController for Dynamic Voltage Balancing in Series-Connected SiC MOSFETs.

Author

Marzoughi, Alinaghi, Burgos, Rolando, and Boroyevich, Dushan

Subjects

*SEMICONDUCTORS, *VOLTAGE control, *HIGH voltages, *SWITCHING circuits, *SILICON, *ELECTRIC circuits

Abstract

Series connection of individual semiconductors is an effective way to achieve higher voltage switches. However, the inherent unequal dynamic voltage sharing problem needs to be solved, even when well-matched gate drivers and semiconductors are used. A majority of the existing voltage balancing schemes are developed for slow-switching silicon (Si)-based semiconductors, and are also associated with a significant amount of additional losses in the control circuit or on the switches. In this paper, a novel method is proposed for balancing the dynamic voltages among series-connected silicon carbide (SiC) MOSFETs with highdv/dtrates. The method takes advantage of a small capacitor to provide additional current to the gate of the MOSFETs at turn-off, meaning the switching speed (and thus, the device voltage after turn-off) is controlled. The proposed method generates negligible losses in the control circuit, and also does not significantly increase the switching losses of the semiconductors. Experimental results are provided to prove the effectiveness of the proposed voltage balancing scheme on two SiC MOSFETs inside a module connected in series. In order to do so, an active gate driver is designed embedding the activedv/dtcontrol scheme as well as other essential functionalities needed for operation of SiC MOSFETs. [ABSTRACT FROM AUTHOR]

Published

2019

18. A Hybrid Nine-Level, 1-φ Grid Connected Multilevel Inverter With Low Switch Count and Innovative Voltage Regulation Techniques Across Auxiliary Capacitor.

Author

Phanikumar, Chamarthi, Roy, Jibanesh, and Agarwal, Vivek

Subjects

*ELECTRON tube grids, *ELECTRIC inverters, *TECHNOLOGICAL innovations, *ELECTRIC potential, *CAPACITORS

Abstract

A 1-φ hybrid nine-level inverter (H9LI) topology has been proposed in this paper. The proposed H9LI topology uses a simple phase disposition pulsewidth modulation strategy to generate nine-voltage levels in the output. The main advantage of this topology is that it has a low switch count (ten switches) compared to the existing nine-level inverter topologies. To regulate the voltage across auxiliary capacitor, two innovative control techniques are proposed, which are integrated with the inverter modulation technique itself. Hence, it does not require any extra voltage balancing circuits to maintain the voltage across the auxiliary capacitor and input dc capacitors. A major advantage of these control techniques is that they eliminate the sensing of the coupled inductor current. Another significant advantage of H9LI is that loss distribution among all the power switches is more uniform compared to existing nine-level inverters. Due to low part count and absence of extra voltage balancing circuits, the H9LI achieves higher efficiency (η ≍ 94.5%) and lower cost. Furthermore, the requirement of filter size reduces due to the presence of coupled inductor in H9LI. The proposed 1-φ grid connected H9LI is verified through MATLAB/Simulink simulations and validated through experiments on a laboratory prototype of 400-VA rating. [ABSTRACT FROM AUTHOR]

Published

2019

19. Low-Complexity Model Predictive Control of Single-Phase Three-Level Rectifiers With Unbalanced Load.

Author

Ma, Junpeng, Song, Wensheng, Wang, Xiongfei, Blaabjerg, Frede, and Feng, Xiaoyun

Subjects

*ELECTRIC currents, *ELECTRIC potential, *SWITCHING circuits, *PREDICTIVE control systems, *ELECTRIC current rectifiers

Abstract

The neutral-point potential fluctuation in single-phase three-level rectifiers leads to coupling between the line current regulation and dc-link capacitor voltage balancing, deteriorating waveform quality of the line current. For addressing this issue, this paper proposes a low-complexity model predictive current control (MPCC) with constant switching frequency, which achieves a decoupling control of the line current and the neutral-point potential under the unbalanced load condition. The switching frequency is fixed by combining the MPCC scheme with predefined switching sequences. The boundary of the durations for voltage vectors in switching sequences is presented to balance the capacitor voltage without worsening the line current quality. The optimal switching sequence and the corresponding optimal durations of voltage vectors in the switching sequence are readily derived without the assessment of the cost function, which dramatically simplifies the complexity of the MPCC scheme. Finally, simulations and experimental results are conducted to verify the effectiveness of the proposed MPCC scheme. [ABSTRACT FROM AUTHOR]

Published

2018

20. Control Scheme for Autonomous and Smooth Mode Switching of Bidirectional DC–DC Converters in a DC Microgrid.

Author

Kwon, Minho and Choi, Sewan

Subjects

*MICROGRIDS, *CASCADE converters, *SWITCHING circuits, *ENERGY storage, *ENERGY management

Abstract

In dc microgrid (MG) systems, energy storage systems (ESSs) capable of short- or long-term energy buffering are indispensable for energy management and providing high-quality electric energy. The MG should be able to operate in both islanded and grid-connected modes. A sudden failure of ac utility grids can lead to an inoperable condition of the MG or a large transient phenomenon accompanied by oscillation and overshoot during the mode transition. This paper proposes a control scheme of the bidirectional dc–dc converter for the ESS to resolve the issue associated with mode switching. The proposed control scheme provides autonomous and smooth mode switching, thereby reducing the reliance on the communication with the central controller, and enhancing the reliability of the system. To validate the proposed concept, simulation results and experimental results are provided. [ABSTRACT FROM AUTHOR]

Published

2018

21. An Efficient Polarity Detection Technique for Thermoelectric Harvester in L-based Converters.

Author

Alhawari, Mohammad, Mohammad, Baker, Saleh, Hani, and Ismail, Mohammed

Subjects

*POLARITY (Physics), *ENERGY harvesting, *THERMOELECTRIC generators

Abstract

This paper presents a new method for detecting and reversing the polarity of a low-voltage thermoelectric generator (TEG) in inductor-based converters. The proposed technique makes use of the inductor response to a voltage change due to the flip in the TEG polarity. The inductor voltage provides two distinguishable states which correspond to the normal and the reversed TEG polarity. A switch matrix circuit is then used to correct the polarity by physically reversing the TEG connection. The detection circuit along with the switch matrix provide a positive input voltage from the TEG to the inductor-based converter. The proposed technique is an efficient polarity detection with all-digital implementation, fully integrated, small area and power overhead. The prototype chip is fabricated in 65-nm CMOS and occupies an area of 0.09 mm2. Measurement results confirm a maximum efficiency of 70% at 50 mV TEG voltage and 40~\mu \text A output current. The proposed technique is part of an autonomous thermal energy harvesting system that detects and corrects the TEG polarity. [ABSTRACT FROM AUTHOR]

Published

2017

22. Generalized High Step-Up DC-DC Boost-Based Converter With Gain Cell.

Author

Schmitz, Lenon, Martins, Denizar C., and Coelho, Roberto F.

Subjects

*DC-to-DC converters, *DIRECT currents, *ELECTRIC currents

Abstract

High step-up conversion is an indispensable feature for the power processing of low voltage renewable sources in grid-connected systems. Motivated by this necessity, this paper presents a study on non-isolated dc-dc converters based on the conventional Boost converter that can provide such feature with high efficiency. By the topological variation and gain cell concepts, it is demonstrated that these converters can be treated as a unique generalized converter, called Boost Converter with Gain Cell (BCGC). The operating principle, the key waveforms and the components stresses of the BGCG are analyzed for the continuous-conduction mode, independently of the employed gain cell. A methodology to create the gain cells is developed from the combination of coupled inductors and voltage multiplier techniques. In order to verify the realized analysis, a 150 W prototype concerning to the proposed generalized converter and able to operate with several different gain cells is developed for the comparison between theoretical and experimental static gain results. [ABSTRACT FROM PUBLISHER]

Published

2017

23. Implementation of Bridgeless Cuk Power Factor Corrector With Positive Output Voltage.

Author

Yang, Hong-Tzer, Chiang, Hsin-Wei, and Chen, Chung-Yu

Subjects

*ELECTRIC power factor, *ELECTRIC circuit design & construction, *CASCADE converters, *VOLTAGE control, *ZERO current switching

Abstract

A single-phase bridgeless Cuk ac/dc power factor correction (PFC) rectifier with positive output voltage is proposed in this paper. For low output voltage product applications, the rectifier is designed to convert high input voltage to low output voltage. Due to no bridge diodes required and thus decreased input conduction losses, the proposed rectifier efficiency can be improved. The proposed rectifier operates in discontinuous conduction mode, and the current-loop circuit is hence not needed. In addition, only a single switch is used in the rectifier to simplify the control circuit design. A simple translation method to have the positive output voltage in the Cuk converter is presented in the rectifier to reduce the component counts and the cost. The operational principles, steady-state analysis, and design procedure of the proposed rectifier are addressed in detail in this paper. Simulation and experimental results obtained from a 150-W rated prototype circuit with input of 90–130 Vrms, 60 Hz, and output of 48 Vdc have verified the validity of the proposed rectifier. [ABSTRACT FROM PUBLISHER]

Published

2015

24. Two-Stage Power Conversion Architecture Suitable for Wide Range Input Voltage.

Author

Seungbum Lim, Ranson, John, Otten, David M., and Perreault, David J.

Subjects

*ELECTRIC power conversion, *ELECTRIC potential, *ELECTRIC circuits, *CAPACITORS, *ELECTRIC transformers, *LIGHT emitting diodes

Abstract

This paper presents a merged-two-stage circuit topology suitable for either wide-range dc input voltage or ac line voltage at low-to-moderate power levels (e.g., up to 30 W). This two-stage topology is based on a soft-charged switched-capacitor preregulator/transformation stage and a high-frequency magnetic regulator stage. Soft charging of the switched capacitor circuit, zero voltage switching of the high-frequency regulator circuit, and time-based indirect current control are used to maintain high efficiency, high power density, and high power factor. The proposed architecture is applied to an LED driver circuit, and two implementations are demonstrated: a wide input voltage range dc-dc converter and a line interfaced ac-dc converter. The dc-dc converter shows 88%-96% efficiency at 30-W power across 25-200-V input voltage range, and the ac-dc converter achieves 88% efficiency with 0.93 power factor at 8.4-W average power. Contributions of this paper include: 1) demonstrating the value of a merged two-stage architecture to provide substantial design benefits in high-input voltage, low-power step down conversion applications, including both wide-range-input dc-dc and line-input ac-dc systems; 2) introduction of a multimode soft-charged SC stage for the merged architecture that enables compression of an 8:1 input voltage range into a 2:1 intermediate range, along with its implementation, loss considerations, and driving methods; and 3) merging of this topology with an resonant transition discontinuous-mode inverted buck stage and pseudocurrent control to enable step-down power conversion (e.g., for LED lighting) operating at greatly increased frequencies and reduced magnetics size than with more conventional approaches. [ABSTRACT FROM AUTHOR]

Published

2015

25. A Simple and Direct Dead-Time Effect Compensation Scheme in PWM-VSI.

Author

Lee, Dong-Hee and Ahn, Jin-Woo

Subjects

*PULSE width modulation, *IDEAL sources (Electric circuits), *LOGIC circuits, *VOLTAGE control, *FEEDBACK control systems, *SWITCHING circuits

Abstract

This paper presents the direct compensation of the switching interval error of the effective voltage vectors by the dead time of a pulsewidth modulation voltage source inverter (PWM-VSI). The output voltages of a three-phase PWM-VSI are distorted and have voltage errors from the dead time to avoid the shoot-through of inverter arms and the time delay of the gate drive. Voltage distortion increases the harmonics of the output voltages and decreases control performance. This paper presents a simple and direct compensation technique to solve this problem in a three-phase VSI. The practical switching output voltages are determined by the dc-link voltage, the switching signals of each phase, the dead time, the time delay, and the current polarities of each phase. For these reasons, output voltage errors are not constant. In order to analyze the dead-time effect in the actual switching voltages of each phase, the practical switching voltages in a sampling period of a space vector PWM (SVPWM) method are calculated according to the current polarity. In the calculation, the dead time, the time delay of devices, and the voltage drops on power devices are included to consider nonlinear voltage distortion. From these practical switching voltages during the switching intervals in a sampling period, the average output voltages of each phase can be derived, and the output voltage errors between the voltage commands and the average output voltages of each phase are obtained. The SVPWM switching intervals of each phase can be derived by the average output voltages that are calculated according to the current polarity and nonlinear voltage distortion to compensate for the output voltage errors. With the simple detection of the current polarity, the practical errors of the switching intervals of each phase can be compensated by the addition of the compensated switching time. Simulation and experimental results validating the proposed compensation method are presented in this paper. [ABSTRACT FROM AUTHOR]

Published

2014

26. AC Voltage Sag/Swell Compensator Based on Three-Phase Hybrid Transformer With Buck-Boost Matrix-Reactance Chopper.

Author

Kaniewski, Jacek, Fedyczak, Zbigniew, and Benysek, Grzegorz

Subjects

*ELECTRICAL energy, *ELECTRIC power distribution grids, *ELECTRICAL load, *ELECTRIC potential, *SWITCHING circuits, *VOLTAGE regulators, *VOLTAGE control

Abstract

The parameters of electrical energy such as voltage amplitude are very important, particularly from the viewpoint of the final consumer and sensitive loads connected to the grid. The dynamic states in the power grid—deep voltage sags and swells—might cause faults and defects in sensitive loads. This paper deals with a three-phase hybrid transformer (HT) without dc energy storage to compensate voltage sags and swells and to protect sensitive loads against the rapid and extensive changes in supply voltage amplitude. The analyzed HT contains two main units: the first one is the conventional electromagnetic transformer, realizing an electromagnetic coupling, and the second one is the buck–boost matrix-reactance chopper, realizing an electrical coupling in the HT unit. In the presented solution, output voltage is transformed in two ways—electromagnetically and electrically. This paper presents an operational description, the theoretical analysis, and the experimental test results from a 2-kVA laboratory model. On the basis of the authors' research, it can be stated that the HT makes it possible to compensate deep voltage sags (deeper than 50% of nominal source voltage) and overvoltages (up to 140% of nominal source voltage) while maintaining good dynamic properties. The main advantages of the proposed solution, in comparison to other conventional solutions, are the ability to control the output voltage in the range of 0.66–3.5 US, good dynamics (transient state during source voltage uS amplitude change is shorter than 10 ms), and galvanic separation between source and load (such as in the case of the conventional electromagnetic transformer). [ABSTRACT FROM PUBLISHER]

Published

2014

27. A Symmetrical Cascaded Compact-Module Multilevel Inverter (CCM-MLI) With Pulsewidth Modulation.

Author

Lee, Sze Sing, Heng, Yeh En, Sidorov, Michail, and Idris, Nik Rumzi Nik

Subjects

*ELECTRIC inverters, *PULSE width modulation transformers, *TOPOLOGY, *SWITCHING circuits, *VOLTAGE control

Abstract

Cascaded H-bridge (CHB) multilevel inverters (MLIs) have been widely used for power electronics systems. While high-voltage blocking across power switches is not a constraint for low voltage applications, the research trend has been oriented to the design of more compact module topologies as an alternative for CHB. Despite the generation of more voltage levels with reduced switch count, the existing module topologies in recent literature take no account of the freewheeling current path during dead-time, thus, inducing multistep jumps in voltage levels and giving rise to undesirable voltage spikes. Addressing this concern, this paper proposes two symmetrical compact-module topologies for cascaded MLI, where freewheeling current path during dead-time is provided for smooth transition between voltage levels to prevent voltage spikes. The proposed 7-level and 13-level compact-modules demonstrated low number of conducting switches for all voltage levels. Comprehensive analysis and comparison with the latest module topologies are conducted. To validate the operation of the proposed compact-module topologies, simulation and experimental results are presented. [ABSTRACT FROM PUBLISHER]

Published

2018

28. Arc-to-Glow Transition Approach for Practical Use in DC Low-Power, Low-Voltage Electric Grids.

Author

Miedzinski, B., Wisniewski, G., Kharin, S. N., Nouri, H., and Grechanyuk, N.

Subjects

*LOW voltage systems, *ELECTRIC power distribution grids, *DIRECT currents, *SEMICONDUCTORS, *VOLTAGE control

Abstract

This paper presents and discusses results of analysis from investigations of arc-to-glow transformation phenomenon at contact opening, under dc low-energy ( $\leq 10$ J) and low-voltage ( $\leq 250$ V) inductive loads. Dependence of the duration of arcing and glowing on current magnitude, voltage magnitude, properties of the contact material, gas quenching medium velocity and its pressure, as well as contact opening velocity and contact gap are investigated. The transition phenomenon of arc-to-glow is analyzed by means of fast photography and emission spectroscopy. Also discussed is the theoretical evaluation of conditions of arc instability. From the results, possible procedures are formulated to control the arc-to-glow transformation for practical use in dc low-voltage and low-power electrical grids. [ABSTRACT FROM AUTHOR]

Published

2018

29. Mitigation of Positive Zero Effect on Nonminimum Phase Boost DC?DC Converters in CCM.

Author

Paduvalli, Vikas V., Taylor, R. J., Hunt, Louis R., and Balsara, Poras T.

Subjects

*CONVERTERS (Electronics), *ELECTRIC inductors, *ELECTRIC power conversion, *CIRCUIT elements, *PHASE-locked loops

Abstract

The control loop stability in boost converters operating in continuous conduction mode has been restricted due to its nonminimum phase nature: the presence of a positive zero (right-half plane zero) in the control to output voltage transfer function. This paper proposes a method to mitigate the effect of the zero on the control loop by shifting the position of the zero to the left-half plane and hence leading to increased stability for the control loop of the boost converter. Superior performance of the proposed method has been clearly demonstrated using simulation and experimental results. [ABSTRACT FROM PUBLISHER]

Published

2018

30. Simple Voltage Balancing Method to Protect Series-Connected Devices Experimentally Verified in a 5L-MPC Converter.

Author

Mazuela, Mikel, Baraia, Igor, Sanchez-Ruiz, Alain, Echeverria, Ivan, Torre, Inigo, and Atutxa, Inigo

Subjects

*INSULATED gate bipolar transistors, *VOLTAGE regulators, *CLAMPING circuits, *CONVERTERS (Electronics), *SEMICONDUCTORS, *IDEAL sources (Electric circuits)

Abstract

This paper presents a solution for the voltage balance problem of the series-connected devices that can be applied to multilevel converters in which the series-connected devices need to block twice their switched voltage. The solution is based on two ideas, the control of the switching commands to achieve proper switching losses balance and the use of additional circuitry to achieve proper voltage balance during their blocking state. The proposed strategy is experimentally validated into a 5-level multipoint clamped full-scale converter. However, it can be used in any other converter topology in which the devices need to block twice their switched voltage. [ABSTRACT FROM PUBLISHER]

Published

2018

31. Advanced Active Gate Drive for Switching Performance Improvement and Overvoltage Protection of High-Power IGBTs.

Author

Zhang, Fan, Yang, Xu, Ren, Yu, Feng, Lei, Chen, Wenjie, and Pei, Yunqing

Subjects

*INSULATED gate bipolar transistors, *OVERVOLTAGE protection, *SWITCHING circuits, *GATE array circuits, *IDEAL sources (Electric circuits), *VOLTAGE control

Abstract

This paper presents a new active gate drive (AGD) for switching performance improvement and overvoltage protection of high-power insulated gate bipolar transistors (IGBTs). In addition to the conventional gate drive (CGD) based on fixed voltage sources and fixed gate drive resistors, the proposed AGD has a complementary current source to provide extra gate drive current into the gate. Specific transient switching stages of the IGBT can be therefore accelerated, leading to higher switching speed and lower switching loss of the IGBT. Additionally, the turn-off voltage overshoot of the IGBT can be controlled at a preset reference value with a fast closed-loop overvoltage protection circuit. Moreover, the switching speed of the IGBT, including the turn-on/off delay times and the turn-on/off voltage slopes, can be effectively regulated with an adaptive switching speed control method. Accordingly, the gate drive is capable of operating the IGBT at specified delay times and fixed voltage slopes when varying the switching conditions (e.g., temperature, load current). The operation principle of the proposed AGD and control concept are presented. By comparing with the CGD, the proposed method is experimentally verified on a 3.3 kV/1.5 kA IGBT module in both double-pulse and multipulse tests. [ABSTRACT FROM PUBLISHER]

Published

2018

32. A Variable Switching Point Predictive Current Control Strategy for Quasi-Z-Source Inverters.

Author

Karamanakos, Petros, Ayad, Ayman, and Kennel, Ralph

Subjects

*VARIABLE capacitors, *SWITCHING circuits, *QUASI-free reactions, *RIPPLES (Fluid dynamics), *ELECTRIC potential

Abstract

This paper presents a variable switching point predictive current control (VSP $^2$CC) for the quasi-Z-source inverter (qZSI). The proposed VSP $^2$CC aims to remove the output current error on the ac side, as well as the inductor current and capacitor voltage errors of the quasi-Z-source network on the dc side of the converter. Unlike the previously presented direct model predictive control (MPC) strategies for the qZSI, the proposed control scheme can directly apply the switching signals not only at the discrete time instants, but at any time instant within the sampling interval. Consequently, the shoot-through state can be applied for a shorter time than the sampling interval, resulting in lower output and inductor currents ripples. Experimental results based on field programmable gate array are provided to verify the effectiveness of the introduced control method. As it is shown, the proposed method leads to lower inductor current ripples and less output current total harmonic distortion when compared with the conventional direct MPC. [ABSTRACT FROM AUTHOR]

Published

2018

33. Design of Class E Power Amplifier with New Structure and Flat Top Switch Voltage Waveform.

Author

Hayati, Mohsen, Roshani, Sobhan, Roshani, Saeed, Kazimierczuk, Marian K., and Sekiya, Hiroo

Subjects

*DIELECTRIC amplifiers, *WAVE analysis, *SWITCHING circuits, *VOLTAGE control, *ELECTRIC capacity

Abstract

In this paper, a new topology of the class E power amplifier (PA) is proposed. The output circuit in the proposed PA is different from that in the conventional class E PA. The conventional output circuit of class E PA consists of shunt capacitor, resonant capacitor, resonant inductor, and shifting inductor. An additional shunt capacitance is added between the resonant capacitance and the shifting inductor to shape the reduced switch voltage. The peak switch voltage of the proposed class E PA is approximately 78% of that of the conventional one, which shows a reduction in peak switch voltage. The lower peak switch voltage reduces the breakdown voltage of the active device. Also, the proposed structure can introduce a new family of switching PAs with interesting specifications. Several values of switch voltage reduction and output power capability could be achieved by varying the circuit elements. Zero voltage and zero derivative switching conditions are achieved in the switch voltage of the designed circuit. The simulation of the proposed circuit is performed using PSpice software. For verification, the presented PA is fabricated and measured. [ABSTRACT FROM PUBLISHER]

Published

2018

34. DC?AC Converter-Fed Induction Motor Drive With Fault-Tolerant Capability Under Open- and Short-Circuit Switch Failures.

Author

Farhadi, Masoud, Fard, Majid Tahmasbi, Abapour, Mehdi, and Hagh, Mehrdad Tarafdar

Subjects

*INDUCTION motors, *DC-AC converters, *FAULT-tolerant control systems, *SHORT circuits, *SWITCHING circuits, *FAILURE analysis

Abstract

In this paper, a new fault tolerant dc–ac converter-fed induction motor drive is proposed to maintain motor as close as possible to its desired normal operation under open- and short-circuit switch failures. The operational principles for fault detection and isolation schemes are provided. Two control strategies including predictive control and voltage mode-controlled PWM with integral-double-lead controller for two stage of the converter are presented in conjunction with the elaborated discussion. The control strategy determines appropriate switching states for continuous operation of the drive after a fault. The proposed topology makes it possible to integrate the minimal redundant hardware and full tolerance capability which is an important advantage of the proposed topology. Moreover, the most important advantages of the proposed topology are a fast response in a fault condition and low cost of the converter in comparison with the evaluated topologies. A Joule-integral-based method for selecting an appropriate rating of applied fuses has been presented to provide a reliable fault-isolation operation. Also, a comparison with currently available fault-tolerant dc–ac converters is given to show the merits of the proposed topology. Finally, the experimental results are presented to verify the validity of the theoretical analysis and industrial feasibility of the proposed converter. [ABSTRACT FROM AUTHOR]

Published

2018

35. Single-Switch Single-Magnetic PWM Converter Integrating Voltage Equalizer for Partially Shaded Photovoltaic Modules in Standalone Applications.

Author

Uno, Masatoshi and Kukita, Akio

Subjects

*PULSE width modulation, *ELECTRIC current converters, *VOLTAGE control, *PHOTOVOLTAIC cells, *VOLTAGE multipliers

Abstract

To prevent partial-shading issues in photovoltaic (PV) systems, various kinds of voltage equalizers that virtually unify characteristics of shaded and unshaded modules have been proposed. Although PV string utilization can be dramatically improved, PV systems tend to be complex and costly because, in addition to the main converter for string control, voltage equalizers are separately necessary. This paper proposes the single-switch single-magnetic pulse width modulation (PWM) converter integrating the voltage equalizer using the series-resonant voltage multiplier (SRVM) for standalone PV systems. By utilizing a square wave voltage generated across a filter inductor in a PWM buck converter for driving the SRVM, the main PWM converter and voltage equalizer can be integrated into a single unit with reducing the total switch and magnetic component counts, achieving not only system-level but also circuit-level simplifications. The experimental test using the prototype for three PV modules connected in series was performed emulating a partial-shading condition. The integrated converter effectively precluded the partial-shading issues and significantly improved the power available at a load, demonstrating its efficacy. [ABSTRACT FROM AUTHOR]

Published

2018

36. Cell-by-Cell-Based Finite-Control-Set Model Predictive Control for a Single-Phase Cascaded H-Bridge Rectifier.

Author

Qi, Chen, Chen, Xiyou, Tu, Pengfei, and Wang, Peng

Subjects

*ELECTRIC current rectifiers, *PREDICTIVE control systems, *MATHEMATICAL optimization, *INTERVAL analysis, *SWITCHING circuits, *ELECTRIC potential measurement

Abstract

The traditional finite-control-set model predictive control (FCS-MPC) method for a cascaded H-bridge (CHB) rectifier has two main issues: heavy computational burden and low steady-state current performance. In this paper, a novel FCS-MPC method has been proposed for a single-phase CHB rectifier. The proposed method solves the optimization problem of FCS-MPC for one cell by one cell, like a “pipeline.” In the proposed method, the sampling period is divided into equal intervals by the number of cells. At the beginning of the first interval, the first cell selects its switching state to be applied. Then, the following cell selects its switching state to be applied at the beginning of next interval. Finally, the selected switching state of last cell will be applied at the beginning of the last interval. A cost function presenting the control objectives of common source current error and itself dc-link voltage error is evaluated for each cell. A single-phase three-cell CHB rectifier controlled by a DSpace DS1104 is tested and the experimental results show that a significant reduction in computational time, an improved steady-state current performance, and a comparable dynamic response are achieved in the proposed method in comparison with the traditional FCS-MPC method. [ABSTRACT FROM AUTHOR]

Published

2018

37. A Low-EMI Fully Integrated Switched-Capacitor DC/DC Converter.

Author

Kennedy, Simon, Yuce, Mehmet Rasit, and Redoute, Jean-Michel

Subjects

*CONVERTERS (Electronics), *ELECTRIC power conversion, *ELECTRIC potential, *ELECTROMAGNETIC compatibility, *CAPACITORS

Abstract

This paper presents a novel fully integrated step-up dc/dc converter containing circuits to improve electromagnetic emissions. This design utilizes current sources to limit the impulsive current flow into the integrated flying capacitors. This reduces the discontinuous pulse currents normally associated with capacitive converters causing electromagnetic interference (EMI). A variable reference current enables the converter to operate with the lowest possible emissions through the entire operating range and is used to regulate the output voltage. The inclusion of low EMI techniques enables fully integrated power converters to be implemented in systems where noise produced by converters currently restricts or prohibits their use. The proposed 3.2 mW voltage doubler was fabricated in a 0.18 $\mu$m CMOS process. With an input voltage range of 1–1.8 V, the converter produces a 1.6–3.3 V output. Experimental results verify the reduction of emissions to meet IEC 61967-4 Class L using current control with a reduction of noise voltage when compared with the circuit without the proposed techniques. [ABSTRACT FROM AUTHOR]

Published

2018

38. High Performance Parallel Single-Phase Converter Reconfiguration for Enhanced Availability.

Author

Hedayati, Mohammad Hassan and John, Vinod

Subjects

*ELECTRIC power systems, *PHOTOVOLTAIC effect, *BATTERY chargers, *ELECTROMAGNETIC measurements, *FREQUENCY meters

Abstract

Paralleling power converters is a common practice in industries to enhance total power rating, reliability, and availability of the system. In case of fault occurring in systems with parallel converters, the faulty power converter can be isolated and the system can still be operated at reduced power level. In this paper, a grid-connected power converter consisting of two parallel H-bridge converters with low ground leakage current is considered. Two contingency configurations, that are also of low ground leakage current, are proposed to enhance the availability of the system. This is done by reconfiguring the power circuit to a single H-bridge in the case of failure in one of the bridges. The power converter is experimentally tested with the proposed configurations for experimental validation. The results show that the second configuration has better performance in terms of power loss and current total harmonic distortion when operating at lower power level. [ABSTRACT FROM AUTHOR]

Published

2018

39. Parabolic-Modulated Sliding-Mode Voltage Control of a Buck Converter.

Author

Qi, Wenlong, Li, Sinan, Tan, Siew-Chong, and Hui, S. Y. R.

Subjects

*SLIDING mode control, *POWER electronics, *SWITCHING circuits, *ELECTRICAL conductivity transitions, *VOLTAGE control

Abstract

Conventional hysteresis-modulation-based sliding-mode (SM) controller exhibits a varying switching frequency. Existing SM controllers for achieving constant-switching-frequency operation often have complicated structures and/or are less straightforward to design to meet different steady state, transient, and loading requirements. In this paper, a new direct SM voltage controller based on parabolic modulation (PM) is proposed and applied to a buck converter. The objective is to achieve constant-switching-frequency operation of a switching converter with simple control structure and good operating performance. Both theoretical study and experimental work on a buck converter show that the proposed PM-based SM control can achieve 1) constant switching frequency in the continuous-conduction mode (CCM) and quasi-constant switching frequency in the discontinuous-conduction mode (DCM) of operation, 2) inherent input-disturbances rejection and superior reference tracking performance, and 3) seamless mode transition between CCM and DCM. [ABSTRACT FROM PUBLISHER]

Published

2018

40. Current-Mode Hysteretic Buck Converter With Spur-Free Control for Variable Switching Noise Mitigation.

Author

Nashed, Mina and Fayed, Ayman A.

Subjects

*HYSTERESIS, *CASCADE converters, *SWITCHING circuits, *NOISE control, *DIRECT currents, *POWER management of integrated circuits

Abstract

This paper proposes a current-mode hysteretic buck converter with a spur-free constant-cycle frequency-hopping controller that fully eliminates spurs from the switching noise spectrum irrespective of variations in the switching frequency and operating conditions. As a result, the need for frequency regulation loops to ensure nonvarying switching frequency (i.e., fixed spurs location) in hysteretic controllers is eliminated. Moreover, compared to frequency regulation loops, the proposed converter offers the advantage of eliminating mixing and interference altogether due to its spur-free operation, and thus, it can be used to power, or to be integrated within noise-sensitive systems while benefiting from the superior dynamic performance of its hysteretic operation. The proposed converter uses dual-sided hysteretic band modulation to eliminate the inductor current imbalance that results from frequency hopping along with the output voltage transients and low-frequency noise floor peaking associated with it. Moreover, a feedforward adaptive hysteretic band controller is proposed to reduce variations in the switching frequency with the input voltage, and an all-digital soft-startup circuit is proposed to control the in-rush current without requiring any off-chip components. The converter is implemented in a 0.35-μm standard CMOS technology and it achieves 92% peak efficiency. [ABSTRACT FROM PUBLISHER]

Published

2018

41. Fixed-Switching Frequency Interleaved Sliding Mode Eight-Phase Synchronous Buck Converter.

Author

Repecho, Victor, Biel, Domingo, Ramos-Lara, Rafael, and Vega, Pilar Garcia

Subjects

*SWITCHING circuits, *SLIDING mode control, *CASCADE converters, *CHATTERING control (Control systems), *SYNCHRONOUS circuits

Abstract

This paper describes the design of an interleaved sliding mode control for a multiphase synchronous buck converter, which inherits the properties of sliding mode control, operates with fixed switching frequency in the steady-state, and ensures current equalization among phases. Moreover, a power management algorithm is added in order to decide the number of active phases as function of the power load demand, thus optimizing the converter efficiency. The system uses a Master–Slave structure where each phase can actuate as the Master one in such a way that the overall system reliability is improved. Experimental results in a 1.5 kW eight-phase synchronous buck converter show that interleaving operation, robust output voltage regulation, phase current equalization, switching frequency regulation, and power management are achieved. [ABSTRACT FROM PUBLISHER]

Published

2018

42. Control of Modular Multilevel Converter With Parallel Connectivity?Application to Battery Systems.

Author

Goetz, Stefan M., Li, Zhongxi, Liang, Xinyu, Zhang, Chengduo, Lukic, Srdjan M., and Peterchev, Angel V.

Subjects

*CASCADE converters, *ELECTRIC batteries, *ELECTRICAL load, *SWITCHING circuits, *FEASIBILITY studies

Abstract

This paper presents a multiobjective real-time controller for a modular multilevel converter capable of parallel module connectivity, the so-called modular multilevel series parallel converter (MMSPC). The MMSPC topology allows the batteries to be dynamically rewired in various series–parallel configurations, generating a wide range of output voltage levels. The novel control method parallelizes the modules to balance their voltages without the need for individual module voltage monitoring. Additionally, the controller optimizes across the large number of feasible system configurations to minimize switching and conduction losses. Finally, the controller efficiently encodes the system configuration with module interconnection states rather than the module switch states, which substantially simplifies control. Furthermore, this work experimentally validates the MMSPC topology and concept. In the prototype, the parallel mode reduced the system losses at 5 kW output power by 18% and 24% for load power factors of 1.0 and 0.8, respectively. Sensorless balancing via parallelization maintained well-matched module voltages (standard deviation = 0.045 V) over a 5-h battery discharge with highly variable load current. The reduced conduction losses and simple balancing capability of the MMSPC can enable new applications at medium and low voltages that benefit from its high-quality output, elimination of filtering magnetics, fast response, and modularity. [ABSTRACT FROM AUTHOR]

Published

2017

43. Dynamic Voltage Restorer Using Switching Cell Structured Multilevel AC–AC Converter.

Author

Kim, Sanghun, Kim, Heung-Geun, and Cha, Honnyong

Subjects

*ELECTRIC potential, *SWITCHING circuits, *AC-AC transformers, *CASCADE converters, *PULSE width modulation

Abstract

Dynamic voltage restorer (DVR) technology has become a mature power quality product. In high-power applications, DVR using a multilevel converter is commonly used. However, DVR using a multilevel direct pulse width modulation (PWM) ac–ac converter has not been well studied. This paper presents a new DVR topology using a cascaded multilevel direct PWM ac–ac converter. In the proposed scheme, the unit cell of the multilevel converter consists of a single-phase PWM ac-ac converter using switching cell structure with coupled inductors. Therefore, the multilevel converter can be short- and open-circuited without damaging the switching devices. Neither lossy RC snubber nor a dedicated soft commutation strategy is required in the proposed DVR. This improves the reliability of the DVR system. The output voltage levels of the multilevel converter increase with the number of cascaded unit cells, and a high ac output voltage is obtained by using low-voltage-rating switching devices. Furthermore, a phase-shifted PWM technique is applied to significantly reduce the size of the output filter inductor. A 1-kW prototype of single-phase DVR is developed, and its performance is experimentally verified. Finally, the simulation results are shown for a three-phase DVR system. [ABSTRACT FROM AUTHOR]

Published

2017

44. Predictive Controller Based on Switching State Grouping for a Modular Multilevel Converter With Reduced Computational Time.

Author

Rashwan, Ahmed, Sayed, Mahmoud A., Mobarak, Youssef A., Shabib, Gaber, and Senjyu, Tomonobu

Subjects

*SWITCHING circuits, *ELECTRIC power conversion, *CONVERTERS (Electronics), *ELECTRIC measurements, *CAPACITORS

Abstract

Recently, a modular multilevel converter (MMC) has become one of the most popular converters in medium/high-power applications. In this paper, a new technique is presented to decrease the computational time of the MMC by using switching state grouping for the predictive controller. The proposed technique has the ability to control the output current, minimize the circulating currents, and balance all capacitor voltages, simultaneously. For a predefined number of MMC submodules, the number available switching states is known. The proposed technique uses two stages of predictive modules. In the first stage, the switching states of the MMC are divided equally into a number of groups, controlled simultaneously by the same number of predictive modules. The optimal number of the switching state groups in the first stage is obtained. In the second stage, only one predictive module is used to obtain the optimal switching state of the MMC without any other complexities or additional sorting controllers. The effectiveness of the proposed control technique has been verified by using MATLAB/SIMULINK software considering steady state and dynamic analysis. The results of the proposed technique are compared with the conventional one in terms of computation time, verifying better performance of the proposed method. [ABSTRACT FROM PUBLISHER]

Published

2017

45. A Single-Phase Buck Matrix Converter With High-Frequency Transformer Isolation and Reduced Switch Count.

Author

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

Subjects

*MATRIX converters, *CONVERTERS (Electronics), *ELECTRIC transformers, *ELECTRIC currents, *ELECTRIC potential

Abstract

In this paper, a new type of matrix converter (MC) also called a single-phase high-frequency transformer isolated (HFTI) buck MC is proposed. The proposed converter can provide step-down operation of the input voltage with various types of output voltages such as in-phase and out-of-phase output voltages, rectified (or positive) output voltage, and output voltage with step-changed frequency. By incorporating HFT isolation, the proposed MC saves an extra bulky line frequency transformer, which is required for the conventional MCs to provide electrical isolation and safety, when used in application such as dynamic voltage restorers, etc. Two different circuit variations of the proposed HFTI MC are presented with and without continuous output currents, with the latter having less passive components. The safe-commutation strategy is also employed for the proposed HFTI MC to provide current path for the inductor during dead-time, which avoids switch voltage spikes without adding any snubber circuits. The operation principle and circuit analysis of the proposed MC are presented, and switching strategies are also developed to obtain various output voltages. Moreover, a prototype of the proposed MC is fabricated, and experiments are performed to produce in-phase/out-of-phase and rectified output voltages, and output voltage with step-changed frequency. [ABSTRACT FROM PUBLISHER]

Published

2017

46. Generalized DTC Strategy for Multilevel Inverter Fed IPMSMs With Constant Inverter Switching Frequency and Reduced Torque Ripples.

Author

Mohan, Deepu, Zhang, Xinan, and Beng Foo, Gilbert Hock

Subjects

*ELECTRIC inverters, *TORQUE control, *SWITCHING circuits

Abstract

This paper proposes a generalized direct torque control (DTC) strategy for multilevel inverter fed DTC (MLI-DTC) drives. By using a simple voltage vector decomposition technique, the proposed method is compatible with inverters possessing any number of voltage levels. Consequently, voltage vectors are applied in a similar way as in the case of a two-level inverter fed DTC. A constant inverter switching frequency is imposed in the proposed method by using a torque regulator in place of the traditional torque hysteresis controller, which enables the application of two voltage vectors within one switching cycle. This also contributes to reduce the torque and flux ripples. Detailed design guidelines for the proposed torque regulator are provided. Experimental results obtained with a three-level neutral point clamped inverter show that the proposed MLI-DTC drive operates with low, constant switching frequency while alleviating torque and flux ripples under all operating conditions. Comparative study with a prior art and parametric sensitivity analysis are also presented to verify the effectiveness and robustness of the proposed MLI-DTC method. [ABSTRACT FROM PUBLISHER]

Published

2017

47. Digitally Implemented Charge Control for LLC Resonant Converters.

Author

Kang, Sang-Woo and Cho, Bo-Hyung

Subjects

*RESONANT power convertors, *VOLTAGE control, *CAPACITORS, *SWITCHING circuits, *CURRENT distribution

Abstract

This paper proposes a digitally implemented charge control for LLC resonant converters. By analyzing the small-signal characteristics of the resonant capacitor, it is revealed that the resonant capacitor has exactly the same functionality as a resettable integrator in the charge control for a PWM converter. Based on the analyzed results, the proposed charge control is implemented simply by sensing the voltage across the resonant capacitor in a switching period. The proposed method features simple implementation with resistive voltage divider and suitability for digital control as well as good performance as other multiloop controls have. The design guideline for the charge controller is given based on the loop gain analysis. Finally, the operation and performance of the proposed method are verified with a 240-W LLC resonant converter. [ABSTRACT FROM AUTHOR]

Published

2017

48. Active Virtual Ground—Bridgeless PFC Topology.

Author

Ho, Carl Ngai Man, Li, River Tin-ho, and Siu, Ken King-Man

Subjects

*ELECTRIC power factor, *REACTIVE power, *ELECTRIC potential, *ELECTRIC power conversion, *ELECTRIC inductance

Abstract

The paper presents a new bridgeless power factor correction (PFC) topology, using a recently proposed controllable LCL filter, namely active virtual ground to achieve efficient power conversion, and high-frequency common mode voltage (CM) reduction. The proposed PFC circuit consists of high-frequency semiconductors for shaping inductor current and low-frequency semiconductors to form two different LCL structures for different conditions. This reduces grid differential mode current ripple or inductance. Besides, the PFC CM voltage, a main problem of bridgeless PFCs, is significantly reduced, since the capacitor in the LCL filter clamps the voltage between the grid and the converter ground. The performance of the proposed PFC is experimentally verified. The results show that the proposed PFC guarantees sinusoidal input current, low high-frequency common-mode voltage noise, and has a good agreement with the theoretical findings. [ABSTRACT FROM AUTHOR]

Published

2017

49. A 300-nW Sensitive, 50-nA DC-DC Converter for Energy Harvesting Applications.

Author

Chowdary, Gajendranath and Chatterjee, Shouri

Subjects

*DC-to-DC converters, *ENERGY harvesting, *ELECTRIC potential, *SWITCHING circuits, *ELECTRIC power consumption, *EQUIPMENT & supplies

Abstract

A maximum-power-point-tracking DC-DC boost converter to harvest energy from sub-\muW power sources is presented. For available input-power levels below 1 \muW, voltage boosting is achieved by operating all circuits in the sub-threshold region, and by switching the DC-DC converter at tens of Hz, thereby reducing switching losses. The paper further explores the possibility of energizing the DC-DC inductor for an optimum duration, such that switching and resistive losses are minimized. The sub-\muW energy harvesting circuit uses an area of 0.2 mm^2 on a standard 180 nm CMOS process, and utilizes an auxiliary voltage source for start-up. The designed and fabricated system is more than 50% efficient when the available power is greater than 2 \muW. The circuit can harvest energy whenever the available power is more than 0.3 \muW. Efficiency at 0.3 \muW is 25%, at 0.5 \muW is 37% and at 1 \muW is 48%. The complete IC consumes 50 nA for internal operations and the input voltage can be as low as 70 mV. [ABSTRACT FROM PUBLISHER]

Published

2015

50. An Optimized SVPWM Strategy for Five-Level Active NPC (5L-ANPC) Converter.

Author

Guojun Tan, Qingwei Deng, and Zhan Liu

Subjects

*CASCADE converters, *PULSE width modulation, *ELECTRIC potential, *SWITCHING circuits, *CAPACITORS

Abstract

The five-level active neutral-point-clamped (5L-ANPC) converter has been widely studied for its excellent performance in high-power medium-voltage applications. This paper analyzes the space vector pulse width modulation (SVPWM) strategy of the 5L-ANPC converter in the virtual coordinate, and presents an optimized control strategy which can balance the neutral point (NP) voltage and avoid the dead-time effects for the first time. In this strategy, on one hand, the 125 space vectors are combined by 96 triangles in the seven-segment vector synthesis method, then the triangles are divided into seven categories which have different characteristics of balancing the NP voltage, and every category has its own principles to choose the vector sequence and compute the vector durations. On the other hand, the dead-time effects of the 5L-ANPC converter are studied in detail and the transitions between different switching states are constrained in the optimized control strategy to avoid the dead-time effects that cannot be compensated by traditional pulse-based dead-time compensation methods. Finally, the optimized SVPWM strategy is experimentally verified in this paper. [ABSTRACT FROM AUTHOR]

Published

2014