Showing total 1,613 results

51. A SiC CMOS Digitally Controlled PWM Generator for High-Temperature Applications.

Author

Roy, Sajib, Murphree, Robert C., Abbasi, Affan, Rahman, Ashfaqur, Ahmed, Shamim, Gattis, James Austin, Francis, A. Matt, Holmes, Jim, Mantooth, H. Alan, and Di, Jia

Subjects

THERMAL stresses, ISOTHERMAL processes, THERMOMETERS, COMPLEMENTARY metal oxide semiconductors, THERMAL properties

Abstract

This paper describes a silicon carbide pulse width modulation (PWM) signal generator in the 1.2 μm HiTSiC CMOS process developed by Raytheon Systems Ltd. The design features a 6-b binary input, which allows for setting a system's duty cycle. The results presented in this paper utilize a field programmable gate array board in the test setup to dynamically set the duty cycle by controlling each bit. A control current is also available to give the user added flexibility for tuning the duty cycle. Experimental results show the duty cycle range of the PWM generator to be between 4.7% and 95.2% at 400 °C. Sustained operation of the circuit is demonstrated over a period of 50 h at 300 °C. Finally, the PWM generator is evaluated in the operation of a boost converter. [ABSTRACT FROM PUBLISHER]

Published

2017

52. Family of Soft-Switching Bidirectional Converters With Extended ZVS Range.

Author

Mohammadi, Mohammad Reza and Farzanehfard, Hosein

Subjects

CASCADE converters, ELECTRIC current converters, ROTARY converters, ELECTRIC machinery, POWER electronics

Abstract

This paper proposes a family of soft-switching bidirectional converters. In many applications, the bidirectional converters operate over a wide range of duty cycle and load variations. In the proposed converters, in order to extend the zero-voltage switching operation range, two supplemental voltage sources utilizing passive components are implemented in the auxiliary circuit. By using this method, the soft-switching features are ensured for an extensive range of the converter duty cycles. This is achieved independent of the output power value or the converter operation mode, and so, soft switching is ensured within the entire converter operating region. In these converters, all semiconductors components are soft switched, and the auxiliary circuit does not contribute to the complexity of the control circuit. Also, no extra voltage stress exists on the main switches and the voltage stress on the auxiliary switches is lower than the main switches voltage stress. In this paper, the proposed bidirectional buck/boost converter is analyzed and to confirm the feasibility of the proposed method, experimental results of a 150-W prototype converter are presented. [ABSTRACT FROM PUBLISHER]

Published

2017

53. Power Decoupling Method for Single-Phase H-Bridge Inverters With No Additional Power Electronics.

Author

Serban, Ioan

Subjects

ELECTRIC inverters, SINGLE-phase flow, POWER semiconductors, PULSATION (Electronics), CAPACITORS

Abstract

An active method for double-frequency power ripple decoupling in single-phase inverters is presented in this paper, exhibiting the main advantage of not using additional power semiconductors besides the H-bridge. The proposed method requires only two capacitors placed between the midpoint and one end of each inverter leg. An original control solution of the inverter ensures the power ripple transfer toward the two decoupling capacitors without affecting the inverter output voltage. The simple design makes the proposed solution easy to adapt for single-phase inverters in H-bridge configuration. This paper focuses on the autonomous operation mode of the inverter, detailing its operating principle and the control analysis. The system performances, including the impact of the decoupling circuit on the inverter efficiency, are assessed by means of experimental results. [ABSTRACT FROM PUBLISHER]

Published

2015

54. Interleaved Buck Converter With Continuous Input Current, Extremely Low Output Current Ripple, Low Switching Losses, and Improved Step-Down Conversion Ratio.

Author

Esteki, Morteza, Poorali, Behzad, Adib, Ehsan, and Farzanehfard, Hosein

Subjects

ELECTRIC current converters, ELECTRIC currents, CASCADE converters, ELECTRIC power distribution, ELECTRIC power conversion

Abstract

This paper proposes an interleaved buck converter (IBC) with continuous input current, extremely low output current ripple, low switching losses, and improved step-down conversion ratio. Unlike the conventional IBC, the proposed converter has a continuous input current, and its output current ripple is extremely low. The proposed converter has a lower voltage stress in comparison to the conventional IBC and can also provide a high step-down ratio, which makes it a proper choice for high-power applications where a nonisolated step-down converter with low output current ripple and continuous input current is required. Also, the proposed converter can provide current sharing between two interleaved modules without using additional current-sharing control method. All of these benefits are obtained without any additional stress on the circuit components. A prototype converter with 200-V input and 24-V–10-A output is implemented to verify the theoretical analysis. Operational principles and experimental results are presented in this paper. [ABSTRACT FROM PUBLISHER]

Published

2015

55. An Enhanced Voltage Sag Compensation Scheme for Dynamic Voltage Restorer.

Author

Rauf, Abdul Mannan and Khadkikar, Vinod

Subjects

ELECTRIC potential, ELECTRIC inverters, DC-to-DC converters, ELECTRIC current converters, CAPACITORS

Abstract

This paper deals with improving the voltage quality of sensitive loads from voltage sags using a dynamic voltage restorer (DVR). The higher active power requirement associated with voltage phase jump compensation has caused a substantial rise in size and cost of the dc link energy storage system of DVR. The existing control strategies either mitigate the phase jump or improve the utilization of dc link energy by the following: 1) reducing the amplitude of the injected voltage or 2) optimizing the dc bus energy support. In this paper, an enhanced sag compensation strategy is proposed, which mitigates the phase jump in the load voltage while improving the overall sag compensation time. An analytical study shows that the proposed method significantly increases the DVR sag support time (more than 50%) compared with the existing phase jump compensation methods. This enhancement can also be seen as a considerable reduction in dc link capacitor size for new installation. The performance of the proposed method is evaluated using simulation study and finally verified experimentally on a scaled laboratory prototype. [ABSTRACT FROM PUBLISHER]

Published

2015

56. Adding Inverter Fault Detection to Model-Based Predictive Control for Flying-Capacitor Inverters.

Author

Druant, Joachim, Vyncke, Thomas, De Belie, Frederik, Sergeant, Peter, and Melkebeek, Jan

Subjects

ELECTRIC inverters, POWER electronics, INDUCTION machinery, ALGORITHMS, COMPUTER simulation

Abstract

As inverters are often used in critical applications, reliability is an important issue. In particular, the power electronic switches and gate drivers, the most essential components of the inverter, are vulnerable parts in real live operation. Therefore, this paper focuses on open-switch fault detection for multilevel inverters. When a single-switch open-circuit fault occurs in one of the power electronic switches, the algorithm can detect the fault and the switch that is causing it. The detection is worked out for both a linear resistive inductive load and an induction motor. The proposed algorithm is an extension of an already available finite-set model-based predictive control algorithm. Therefore, no extra hardware or measurements are required. This paper also discusses a suggested method for reconfiguration after fault detection. Computer simulation and experimental verifications validate the proposed methods. [ABSTRACT FROM PUBLISHER]

Published

2015

57. A Switched-Capacitor Three-Phase AC–AC Converter.

Author

Lazzarin, Telles B., Andersen, Romero L., and Barbi, Ivo

Subjects

SWITCHED capacitor circuits, CAPACITOR switching, CONVERTERS (Electronics), ELECTRIC power conversion, ENERGY conversion

Abstract

This paper proposes a bidirectional three-phase direct ac–ac converter, with only capacitors and switches in its power circuit and with its operation based on the switched-capacitor principle. The converter presents fixed gain, it keeps the frequencies of the output and input voltages equal, and it operates in open loop with constant switching frequency and duty cycle. The main advantages of the proposed converter are the absence of magnetic elements in the power circuit, the higher efficiency, the higher power density, the higher specific power, the lower cost, and the fact that it can convert ac–ac voltages within a wide frequency range, including dc voltage. Therefore, it is suitable to replace the conventional three-phase autotransformer in industrial, commercial, and residential applications, and it can be designated as a magnetic-less three-phase solid-state autotransformer. The principle of operation, a qualitative and quantitative analysis, the design methodology, and a fabricated example are described in this paper. In order to verify the converter in the laboratory, a prototype with the following characteristics was designed and fabricated: 6 kW, 1.35 kW/kg, 380/110 V, and switching frequency of 100 kHz. The measured efficiency at rated power was 96.3%, and other relevant experimental results are reported herein. [ABSTRACT FROM PUBLISHER]

Published

2015

58. Improvement of Adaptive Property by Adaptive Deadbeat Feedforward Compensation Without Convex Optimization.

Author

Maeda, Yoshihiro and Iwasaki, Makoto

Subjects

FEEDFORWARD control systems, MECHATRONICS, ROBUST control, LINEAR matrix inequalities, CAPACITORS

Abstract

This paper presents a novel adaptive feedforward (FF) compensation on the basis of the deadbeat control framework for the fast and precise positioning of high-performance mechatronic systems. Resonance frequency fluctuations in mechanisms generally deteriorate the positioning performance due to temperature variations, age deteriorations, and discrepancies among products. A robust controller design against the fluctuations, therefore, is one of important issues for industrial applications. In this paper, an adaptive deadbeat FF compensation is applied to provide nominal positioning performances under the parameter fluctuations. The proposed approach can adapt the FF compensator with no optimization calculation to shorten the adaptation interval period. In addition, saturation in the control input can be prevented during the adaptive compensation, on the basis of a linear matrix inequality technique. The effectiveness of the proposed approach has been verified by numerical simulations and experiments using a laboratory prototype of a galvano scanner, which is one of typical mechatronic devices for the fast and precise positioning in industrial applications. [ABSTRACT FROM PUBLISHER]

Published

2015

59. Soft-Switching AC-Link Three-Phase AC–AC Buck–Boost Converter.

Author

Amirabadi, Mahshid, Baek, Jeihoon, Toliyat, Hamid A., and Alexander, William C.

Subjects

AC-AC transformers, ELECTRIC current converters, GALVANIC isolation, ZERO voltage switching, ELECTRIC switchgear

Abstract

In this paper, the soft-switching ac-link ac–ac buck–boost converter will be studied in more detail. This single-stage converter, which is, in essence, an extension of the dc–dc buck–boost converter, can be an excellent alternative to dc-link converters. Being a buck–boost converter, this converter is capable of both stepping-up and stepping-down the voltage. The link current and voltage are both alternating, and their frequency can be as high as permitted by the switches and the sampling time of the microcontroller. This eliminates the need for dc inductors or dc electrolytic capacitors, and the main energy storage element is an ac inductor $(L)$. Moreover, in this converter, galvanic isolation can be provided by adding a single-phase high-frequency transformer to the link. Therefore, the proposed converter is expected to be more compact compared to the conventional dc-link converter. The other advantage of this converter is the soft switching of the switches, which is feasible by adding a small capacitor $(C)$ to the link. In this paper, the design and analysis of this converter will be studied in detail. In order to accurately analyze this converter, the effect of the $LC$ link resonance on the performance of the converter will be studied. This analysis helps in evaluating the performance of the converter at low power levels when the resonating time of the $LC$ link is not negligible. Using this analysis, the link peak current and the link frequency may be calculated at any point of operation. The accuracy of this method is verified through simulations and experiments. Detailed comparison of the proposed converter with the dc-link converter will be also presented in this paper. It will be shown that, despite having more switches, the current rating of the switches is lower in this converter. Moreover, the efficiencies of the two converters will be compared. Finally, the performance of the soft-switching ac-link ac–ac buck–boost converter is experimentally evaluated in this paper. It will be shown that the converter has the possibility of changing both the frequency and the voltage. Both step-up and step-down operations will be verified through experiments. [ABSTRACT FROM PUBLISHER]

Published

2015

60. A Quad Two-Level Inverter Configuration for Four-Pole Induction-Motor Drive with Single DC Link.

Author

N., Kiran Kumar and Sivakumar, K.

Subjects

ELECTRIC inverters, INDUCTION motors, PULSE width modulation, ELECTRICAL harmonics, ELECTRONIC modulation

Abstract

A multilevel inverter topology for a four-pole induction-motor drive is presented in this paper, which is constructed using the induction-motor stator winding arrangement. A single dc source with a less magnitude when compared with conventional five-level inverter topologies is used in this topology. Therefore, power balancing issues (which are major challenges in conventional multilevel inverters) are minimized. As this configuration uses a single dc source, it provides a path for zero-sequence currents because of the zero-sequence voltages present in the output, which will flow through the motor phase winding and power electronic switches. To minimize these zero-sequence currents, sine–triangle pulsewidth modulation (SPWM) is used, which will shift the lower order harmonics near to switching frequency in the linear modulation region. However, in the case of overmodulation, harmonic voltages will be introduced close to the fundamental frequency. In this regard, a modified SPWM technique is proposed in this paper to operate the drive in the overmodulation region up to the modulation index of 2/\!\surd3. The proposed quad two-level inverter topology is experimentally verified with a laboratory prototype on a four-pole 5-hp induction motor. Experimental results show the effectiveness of the proposed topology in the complete linear modulation region and the overmodulation region. [ABSTRACT FROM PUBLISHER]

Published

2015

61. Study of the Asymmetrical Half-Bridge Flyback Converter as an Effective Line-Fed Solid-State Lamp Driver.

Author

Buso, Simone, Spiazzi, Giorgio, and Sichirollo, Francesco

Subjects

ELECTRIC current converters, ELECTRIC circuits, LIGHT emitting diodes, LED lamps, CLOSED loop systems, FEEDFORWARD control systems

Abstract

This paper illustrates the design and an experimental test of a line-fed solid-state lamp driver based on the asymmetrical half-bridge flyback converter. Its favorable characteristics, in terms of soft-switching range and circuit complexity, allow the converter to operate at variable switching frequency in the range of 300–450 kHz, supplying 6 W to the load with good efficiency. The considered lamp is made up of five series-connected high-power light-emitting diodes (Cree XR-E) and is supplied with 350-mA closed-loop-regulated constant current. While presenting similar complexity and overall efficiency with respect to a conventional driver, due to an original feedforward control technique that allows shrinking the input filter capacitor, the proposed circuit allows a significant volume reduction and consequent power density improvement. [ABSTRACT FROM PUBLISHER]

Published

2014

62. Modeling, Impedance Design, and Efficiency Analysis of Quasi- $Z$ Source Module in Cascaded Multilevel Photovoltaic Power System.

Author

Sun, Dongsen, Ge, Baoming, Yan, Xingyu, Bi, Daqiang, Zhang, Hao, Liu, Yushan, Abu-Rub, Haitham, Ben-Brahim, Lazhar, and Peng, Fang Zheng

Subjects

CASCADED counters, ELECTRIC inverters, PHOTOVOLTAIC power systems, ELECTRIC power production, HARMONIC motion

Abstract

The quasi- $Z$ source (qZS) cascaded multilevel inverter (CMI) (qZS-CMI) presents attractive advantages in application to photovoltaic (PV) power system. Each PV panel connects to an H-bridge qZS inverter (qZSI) to form a power generation module. The distributed maximum power point tracking and all modules' dc-link peak voltage balance can be achieved. However, it is the same with the conventional CMI that the second-harmonic ( $2\omega$) voltage and current ripples exist in each qZSI module. It is crucial for a qZS-CMI to design the reasonable qZS network parameters to limit the ripples within a desired range. This paper proposes an analytic model to accurately calculate the $2\omega$ voltage and current ripples of each qZSI module. A qZS impedance design method based on the built model is proposed to limit the $2\omega$ ripples of dc-link voltage and inductor current. Simulated and experimental results through using the designed 1.5-kW prototype validate the proposed analytic model and the design method. Furthermore, this paper analyzes all of the operating states for a qZSI module and calculates the power loss. The measured efficiency from the prototype verifies the theoretical calculation, and the qZS-CMI-based grid-tie PV power system is tested in practical. [ABSTRACT FROM PUBLISHER]

Published

2014

63. A Novel Transformerless Interleaved High Step-Down Conversion Ratio DC–DC Converter With Low Switch Voltage Stress.

Author

Pan, Ching-Tsai, Chuang, Chen-Feng, and Chu, Chia-Chi

Subjects

CONVERTERS (Electronics), CAPACITORS, ELECTRIC potential, VOLTAGE dividers, MOTHERBOARDS, BATTERY chargers

Abstract

In this paper, a novel transformerless interleaved high step-down conversion ratio dc–dc converter with low switch voltage stress is proposed. In the proposed converter, two input capacitors are series-charged by the input voltage and parallel-discharged by a new two-phase interleaved buck converter for providing a much higher step-down conversion ratio without adopting an extreme short duty cycle. Based on the capacitive voltage division, the main objectives of the new voltage-divider circuit in the converter are for both storing energy in the blocking capacitors for increasing the step-down conversion ratio and reducing voltage stresses of active switches. As a result, the proposed converter topology possesses the low switch voltage stress characteristic. This will allow one to choose lower voltage rating MOSFETs to reduce both switching and conduction losses, and the overall efficiency is consequently improved. Moreover, due to the charge balance of the blocking capacitor, the converter features automatic uniform current sharing characteristic of the interleaved phases without adding extra circuitry or complex control methods. The operation principles and relevant analysis of the proposed converter are presented in this paper. Finally, a 400-V input voltage, 25-V output voltage, and 400-W output power prototype circuit is implemented in the laboratory to verify the performance. [ABSTRACT FROM PUBLISHER]

Published

2014

64. Analysis and Experimental Validation of Bidirectional Z-Source DC Circuit Breakers.

Author

Savaliya, Swati G. and Fernandes, Baylon G.

Subjects

OCEAN waves, DETECTOR circuits, POWER series

Abstract

This paper discusses the analysis and experimental validation of bidirectional Z-source breaker and bidirectional Z-source breaker using coupled inductor for low-voltage dc microgrid application. The proposed topologies use an SCR as a switch to isolate the fault from the system, and LC network to generate required commutation conditions for the SCR under fault conditions. Thus, both topologies are able to isolate the fault naturally within a few microseconds without any fault detection and sensing circuit. In this paper, the breaker operating principle is discussed during fault condition and breaker design criteria are derived. When the breaker is connected in series with power electronic converter, Z-source components offer filtering characteristic. The filtering characteristic offered by the breaker components is analyzed. Functional prototypes are developed for both configurations to validate the breaker performance and experimental results are presented. [ABSTRACT FROM AUTHOR]

Published

2020

65. Fault Diagnosis and Monitoring of Modular Multilevel Converter With Fast Response of Voltage Sensors.

Author

Zhang, Jianzhong, Hu, Xing, Xu, Shuai, Zhang, Yaqian, and Chen, Zhe

Subjects

FAULT diagnosis, POWER capacitors, CAPACITOR switching, DETECTORS, CAPACITORS, OPEN-circuit voltage, ELECTRIC potential

Abstract

Modular multilevel converter (MMC) has been one of the most popular candidates in high-voltage applications. However, reliability is a critical issue due to a large number of power switching devices and capacitors applied in the MMC. To improve the reliability of the MMC, a fast and reliable diagnosis strategy for the open-circuit fault is proposed in this paper, where submodule voltage sensors are relocated to the upper switching device. Furthermore, a voltage observer based on the submodule voltage sensor is established to monitor the capacitor and realize the power control of the MMC under normal operation. A Boolean logic operation based fault indicator is put forward based on the relationship of the operation state and binaried output of voltage sensors, which could detect and locate the open-circuit faults of the MMC very fast. The ratio of the increment of the observed and measured capacitor voltage during the period of positive arm current is applied to monitor the capacitor. The effectiveness of the proposed fault diagnosis strategy and the capacitor monitoring strategy is verified by the experiment results. [ABSTRACT FROM AUTHOR]

Published

2020

66. Cooperative and Dynamically Weighted Model Predictive Control of a 3-Level Uninterruptible Power Supply With Improved Performance and Dynamic Response.

Author

Caseiro, Luis M. A., Mendes, Andre M. S., and Cruz, Sergio M. A.

Subjects

UNINTERRUPTIBLE power supply, PREDICTION models, STEADY-state responses

Abstract

In this paper, we propose a 3-level double conversion uninterruptible power supply with a new cooperative and dynamically weighted model predictive control technique. A 3-level dc–dc converter is used to improve the dc bus balance and the overall response of the uninterruptible power supply (UPS). A new cooperative model predictive control principle is proposed to enhance the response of multiconverter systems. New controllers are proposed for all converters of the UPS, based on the dynamically weighted model predictive control technique and using the presented cooperative principle. A new power management technique is also proposed for the UPS. The proposed 3-level UPS system presents improved dynamic response and steady-state performance in distinct operating points, when compared to the conventional system. Experimental results demonstrate the advantages of each proposed novelty. [ABSTRACT FROM AUTHOR]

Published

2020

67. A High-Voltage Series-Stacked IGBT Switch With Active Energy Recovery Feature for Pulsed Power Applications.

Author

Mohsenzade, Sadegh, Zarghani, Mostafa, and Kaboli, Shahriyar

Subjects

POWER semiconductor switches, INSULATED gate bipolar transistors, POWER resources, POWER series

Abstract

Applying series configuration of the insulated gate bipolar transistors (IGBTs) to the pulsed power supplies offers unique features such as compactness and long life time. In the high-voltage pulsed power supplies, a large number of the IGBTs are required to be serially connected. Hence, the safe operating condition provision for the series IGBTs is an important and crucial issue. The effect of the voltage unbalancing factors becomes remarkable when the number of switches in the series structure increases. There are passive and active methods to balance the voltage of the series IGBTs. In both of these methods, an amount of power must be dissipated to remove the effect of the voltage unbalancing factors. Consequently, the power loss is considerable when a large number of series devices are necessary. This paper proposes an effective power recovery system that recovers the power associated with the series stacking of the IGBTs. Using this proposal, the efficiency of the resulted series switch enhances considerably. The power recovery system can be implemented easily for any number of series IGBTs. It consists of a simple dc–dc converter and several interconnection diodes for power recovery procedure. Proper performance of the proposed structure is evaluated by the aid of simulations and experiments. [ABSTRACT FROM AUTHOR]

Published

2020

68. Passive Integration Using FMLF Technique for Integrated Boost Resonant Converters.

Author

Deng, Cheng, Yong, Masiqian, Rodriguez, Luciano Andres Garcia, Balda, Juan Carlos, and Li, Rui

Subjects

PHOTOVOLTAIC power generation, METAL foils, COMPUTATIONAL electromagnetics, PASSIVE components, POWER density, CAPACITORS

Abstract

As a high-efficiency converter for photovoltaic power generation, the integrated boost series resonant (IBSR) converter includes three inductors, two capacitors, and one transformer, which occupy a significant volume. In order to further increase the power density, this paper proposes a novel passive integrated unit with the flexible multilayer foil integration technique for the above six passive components. First of all, the distributed electromagnetic component model of one new flexible three-layer film shows that the distributed parasitic capacitors formed by the insulation film are combined into the resonant capacitance. Then, the configuration of the proposed integrated unit is described in detail, and the electromagnetic analysis is given. Furthermore, the design procedure for the proposed integrated unit is demonstrated. Finally, a prototype for a 350 W IBSR converter has been built and the experimental results prove the validity of the proposed idea. [ABSTRACT FROM AUTHOR]

Published

2020

69. An Effective Sliding Mode Control Design for a Grid-Connected PUC7 Multilevel Inverter.

Author

Makhamreh, Hamza, Trabelsi, Mohamed, Kukrer, Osman, and Abu-Rub, Haitham

Subjects

SLIDING mode control, ELECTRIC inverters, COST functions, PULSE width modulation transformers, ONLINE algorithms, SAMPLING errors

Abstract

This paper proposes an effective sliding mode controller (SMC) for a grid-connected 7-level packed U-cell (PUC7) inverter. The aim is to design a simple controller that deals effectively with the complex control problem of the PUC7 inverter (multiobjective control problem). The selection of the control actions is achieved according to the system state error at every sampling time, regardless of the previous values, which makes the control technique model-independent. The control algorithm evaluates online two cost functions (one for each state error), which are derived on the basis of sliding mode theory, and it selects the optimal control input in order to satisfy the reaching conditions of the two cost functions. Compared with the existing solutions, the proposed SMC technique ensures lower average switching frequency by tuning the hysteresis bandwidth of the capacitor-voltage error. The fast implementation, needless of gains tuning, and simple design procedure are the main features of the proposed algorithm. Simulation and experimental results are presented to prove the effectiveness of the proposed technique in controlling the PUC7 inverter with high dynamic performance and robustness against disturbances and parameters mismatch. [ABSTRACT FROM AUTHOR]

Published

2020

70. Design and Implementation of New Multilevel Inverter Topology for Trinary Sequence Using Unipolar Pulsewidth Modulation.

Author

Prabaharan, Natarajan, Salam, Zainal, Cecati, Carlo, and Palanisamy, Kaliannan

Subjects

PULSE width modulation

Abstract

This paper proposes a new multilevel inverter (MLI) topology that utilizes trinary sequence for the dc sources. It gives maximum output voltage level with minimum dc source and switch count when compared to other sequences, such as symmetric, natural, binary, and quasi-linear. This is due to the fact that the trinary sequence generates of all additive and subtractive combinations of input dc levels in the output voltage waveform. The concept is implemented on a 9-level asymmetric MLI using only four active devices. Multicarrier unipolar pulsewidth modulation technique is adopted to create the switching pulses. Theoretical calculation of total harmonic distortion in both voltage and current waveforms has been performed using asymptotic time domain formula. These values are compared with simulation and experimental values for different modulation indices. Power loss calculation for proposed topology is discussed with appropriate mathematical equations. [ABSTRACT FROM AUTHOR]

Published

2020

71. Study and Analysis of Pulsating and Nonpulsating Input and Output Current of Ultrahigh-Voltage Gain Hybrid DC–DC Converters.

Author

Andrade, Antonio Manuel Santos Spencer and Martins, Mario Lucio da Silva

Subjects

VOLTAGE multipliers, CAPACITOR switching, ON-chip charge pumps, DC-to-DC converters, CASCADE converters

Abstract

In this paper, eight ultrahigh-voltage gain dc–dc converters are proposed. These sets of converters are derived by the association of boost cells, coupled inductor, voltage multiplier, switched capacitors, and LC filter cells. The nonpulsating input and output converters are evaluated in terms of: principle of operation, voltage gain, voltage and current stress, estimated power losses, and efficiency. Following full analysis prototypes built in the laboratory show experimental results verifying the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2020

72. Closed-Loop Control and Boundary for CCM and DCM of Nonisolated Inverting N× Multilevel Boost Converter for High-Voltage Step-Up Applications.

Author

Iqbal, Atif, Bhaskar, Mahajan Sagar, Meraj, Mohammad, Padmanaban, Sanjeevikumar, and Rahman, Syed

Subjects

SEMICONDUCTOR devices, VOLTAGE multipliers, CONTEMPORARY Christian music, VOLTAGE-frequency converters, HIGH voltages, ELECTRIC current rectifiers

Abstract

In this paper, closed-loop control and boundary condition for continuous conduction mode and discontinuous conduction mode of nonisolated inverting N× multilevel boost converter (MBC) are articulated. Inverting N× MBC combines the features of classical boost converter and voltage multiplier to attain inverting N times higher voltage. Consequently, the inverting N× MBC provides a viable solution for high-voltage step-up photovoltaic applications with low voltage rating reactive components and semiconductor devices. The control strategy with saturation limiter is employed to achieve highly stable voltage. The modes of operation, benefits of inverting N× MBC, and key factors for the selection of semiconductor devices and sizing of the reactive components are discussed. Additionally, the effects of reactive components and semiconductor devices on the output voltage are examined. Experimental results of the developed circuit are presented to validate the design of converter, and effectiveness and robustness of the implemented control algorithm for different input and output side perturbations. [ABSTRACT FROM AUTHOR]

Published

2020

73. Design Considerations for Voltage Sensorless Control of a PFC Single-Phase Rectifier Without Electrolytic Capacitors.

Author

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

Subjects

ELECTROLYTIC capacitors, VOLTAGE control, CORRECTION factors, MOTOR drives (Electric motors), AC DC transformers, ELECTRIC potential, DESIGN

Abstract

In this paper, a voltage sensorless controller is developed for a two-switch single-phase rectifier that involves power factor correction and active pulsating power buffering without electrolytic capacitors. While a two-switch rectifier normally requires four sensed signals for control, only one current sensor is required in this proposal, thereby offering advantages such as low cost, high compactness, isolation between control and power circuits, and improved reliability. While the basic operating principle follows that of a conventional voltage sensorless controller for single-switch converters, several critical design considerations are the key to the success of the implementation which is explained in detail. The feasibilities of the controller are experimentally testified with a 100-W rectifier prototype regarding both steady state and dynamic performance. [ABSTRACT FROM AUTHOR]

Published

2020

74. Parallel Implementation of Model Predictive Control for Multilevel Cascaded H-Bridge STATCOM With Linear Complexity.

Author

Zhang, Yonglei, Yuan, Xibo, Wu, Xiaojie, Yuan, Yalei, and Zhou, Juan

Subjects

DIGITAL signal processing, SYNCHRONOUS capacitors, PREDICTION models, CASCADE converters, QUANTUM gates, FIELD programmable gate arrays, GATE array circuits

Abstract

The algorithm complexity of model predictive control (MPC) for cascaded H-bridge (CHB) static synchronous compensators (STATCOMs) was optimized to a polynomial level in previous studies. However, implementing MPC with conventional approaches still suffers from long execution time, where a low cost digital signal processor (DSP) is used to execute optimization algorithms and a small-sized field-programmable gate array (FPGA) is used to extend gate signals and sampling functions. This paper presents a parallel implementation approach to reduce the execution time of MPC, where the FPGA is configured to be used for accelerating the high-complexity sorting tasks. By running the DSP and FPGA in parallel, the algorithm execution time is only determined by the DSP, and the resource consumption is only determined by the FPGA. To minimize the resource consumption and requirement in FPGA, a parallel comparison-based sorter with multiple comparison and accumulators is proposed. The proposed implementation method can reduce the time and space complexity of the MPC from the polynomial level to a linear level without additional hardware cost, which means the MPC for medium-voltage CHB STATCOMs (e.g., 20 stages) can be implemented online with existing control platforms. Experimental results for various CHB STATCOMs are presented to validate the proposed configuration and algorithm. [ABSTRACT FROM AUTHOR]

Published

2020

75. Determination of Stray Inductance of Low-Inductive Laminated Planar Multiport Busbars Using Vector Synthesis Method.

Author

Lu, Binxian, Pickert, Volker, Hu, Junzhu, Wu, Haimeng, Naayagi, R. T., Kang, Wei, and Liao, Sizhuo

Subjects

ELECTRIC inductance, BUS conductors (Electricity), CAPACITOR switching, POWER capacitors, HARBOR management, ELECTROMAGNETIC interference

Abstract

Laminated busbars connect capacitors with switching power modules, and they are designed to have low stray inductance to minimize electromagnetic interference. Attempts to accurately measure the stray inductance of these busbars have not been successful. The challenge lies with the capacitors, as they excite the busbar producing their individual stray inductances. These individual stray inductances cannot be arithmetically averaged to establish the total stray inductance that applies when all the capacitors excite the busbar at the same time. It is also not possible to measure the stray inductance by simultaneous excitation of each capacitor port using impedance analyzers. This paper presents a solution to the above dilemma. A vector synthesis method is proposed, whereby the individual stray inductance from each capacitor port is measured using an impedance analyzer. Each stray inductance is then mapped into an xyz frame with a distinct direction. This mapping exercise allows the data to be vectored. The total stray inductance is then the sum of all the vectors. The effectiveness of the proposed method is demonstrated on a busbar designed for H-bridge inverters by comparing the simulation and practical results. The absolute error of the total stray inductance between the simulation and the proposed method is 0.48 nH. The proposed method improves the accuracy by 14.9% compared to the conventional technique in measuring stray inductances. [ABSTRACT FROM AUTHOR]

Published

2020

76. A 5-Level Inverter Scheme Using Single DC Link With Reduced Number of Floating Capacitors and Switches for Open-End IM Drives.

Author

Majumder, Mriganka Ghosh, Yadav, Apurv Kumar, Gopakumar, K., R, Krishna Raj, Loganathan, Umanand, and Franquelo, Leopoldo Garcia

Subjects

CAPACITOR switching, POWER semiconductor switches, ELECTRIC current rectifiers, PULSE width modulation transformers, POWER capacitors, INDUCTION machinery, CAPACITORS

Abstract

This paper presents a 5-level inverter topology for open-end induction motor drives by using a single dc source. The open stator windings of the drive are supplied with a 3-level flying capacitor inverter from one end and capacitor-fed 2-level inverter from another end. The voltage ratio of the dc link to the capacitor in 2-level inverter is maintained at 4:1 ratio to generate five-level voltage output. The capacitor in 2-level inverter is balanced by the switching redundant vector combinations from both the inverters while the floating capacitors in the 3-level inverter are balanced by using redundant switching states. The proposed topology gives 5-level operation with less number of floating capacitors and power semiconductor switches compared to other existing topologies. Also, the balancing of the capacitors is independent of load power factor and modulation index. Further, the generalization of the proposed dual inverter scheme for any n-level inverter is also included in this paper. The experimental results and required analysis are also presented to validate the inverter scheme. [ABSTRACT FROM AUTHOR]

Published

2020

77. A 20 MHz Low-Profile DC–DC Converter With Magnetic-Free Characteristics.

Author

Guan, Yueshi, Wang, Yijie, Wang, Wei, and Xu, Dianguo

Subjects

LIGHT emitting diodes, CAPACITORS, DC-to-DC converters, ELECTRIC capacity, AC DC transformers

Abstract

This paper proposes a 20 MHz low-profile dc–dc converter with magnetic-free characteristics based on aircore planar inductors. The switch and diode of the proposed converter operate in soft-switching modes, which significantly reduces the switching loss. Furthermore, the parasitic capacitances are taken as part of corresponding resonant capacitors. A high-performance aircore inductor with a variable width and an optimal connecting angle is analyzed. The optimal parameters design method to achieve minimum winding resistance is derived in detail. The resonant driving method is adopted to reduce driving loss in a high-frequency condition. A 20 MHz prototype is built to verify the feasibility of the proposed converter. [ABSTRACT FROM AUTHOR]

Published

2020

78. 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

79. S-Hybrid Step-Down DC–DC Converter—Analysis of Operation and Design Considerations.

Author

Seo, Gab-Su and Le, Hanh-Phuc

Subjects

DC-to-DC converters, CASCADE converters, USB technology, BATTERY chargers

Abstract

This paper presents a new highly integrable hybrid step-down converter that merges switched-inductor and switched-capacitor operations and significantly reduces onboard loss by using the input cable's parasitic inductance as its main inductor. This converter has the inductor placed at the input with a smaller voltage swing, leading to possible use of a smaller inductor and low-voltage rating switches that generally translate to reduced conduction losses. Analyses of converter operation and losses to reveal its original characteristics and design guidelines are presented to facilitate the components optimization. The converter architecture is verified by a proof-of-concept 15-W inductor-less lithium-ion battery charger prototype that uses a 1-m USB 3.0 cable as inductor. The converter, switched at 2 MHz from a 5-V input, experimentally achieves 89.7% peak efficiency and 6% higher efficiency at full load than a Buck converter counterpart. This high efficiency and zero onboard inductor yield a relative 45.7% onboard loss reduction at full load, promising excellent integration feasibility and superior system thermal management. [ABSTRACT FROM AUTHOR]

Published

2020

80. Analysis, Design, and Experimental Verification of a Mixed High-Order Compensations-Based WPT System with Constant Current Outputs for Driving Multistring LEDs.

Author

Li, Yong, Hu, Jiefeng, Li, Xiaofei, Chen, Feibin, Xu, Qiaodi, Mai, Ruikun, and He, Zhengyou

Subjects

MODULAR design, WIRELESS power transmission, TECHNOLOGY transfer, COST control, CONSTRUCTION costs, ELECTRIC power, LIGHT emitting diodes

Abstract

Current imbalance in multistring light-emitting diodes (LEDs) is a critical issue. It may cause overcurrent in one or more LED strings, leading to rapid degradation. In this paper, a mixed high-order compensation networks-based wireless power transfer system is proposed to generate multiple constant current outputs. It is composed of an LCC resonant network in the transmitting side, a series resonant network, and multiple CLC resonant rectifiers in the receiving side. The CLC resonant rectifiers are connected in parallel to form multiple independent output channels, and each channel is then connected to an LED string. Based on the analysis of the T resonant circuit and the modeling of coupling coils, multiple constant output currents can be derived. As a result, current balance can be achieved, which is very suitable for driving multistring LEDs. The proposed system also offers a modular, scalable, and maintenance-free design, which can significantly reduce the construction cost and the control complexity. In addition, the inverter in the transmitting side can achieve zero phase angle. A laboratory prototype with dual independent output currents is built to verify the proposed method. The experimental results agree well with the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2020

81. Unified Second-Stage LC Filter Applied in the Three-State Switching Cell Buck–Boost Converter: Static and Dynamic Analysis and Experimentation.

Author

Larico, Hugo Rolando Estofanero, de Tomin, Valdir Pedrinho, and Larico, Edwin Red Estofanero

Subjects

FILTERS & filtration, LOW voltage systems

Abstract

This paper presents a unified second-stage LC filter applied in the three-state switching cell buck–boost converter, which provides current and voltage with low ripple and low noise. The unified second-stage filter promotes a reduction in the number of devices while maintaining the filtering performance of the converter, with second-stage LC filters at the input and at the output. Moreover, the unified filter, when associated with a three-state switching cell buck–boost converter, allows a size reduction of filter devices, especially for designs with duty cycle range around 1/2. Furthermore, the unified filter arrangement provides nondissipative clamping of switching devices and reduce the system order when compared to the converter with second-stage LC filters. In this paper, the static and dynamic characteristics of the proposed converter in continuous conduction mode (CCM) are reported. Experimental data were obtained from a laboratory prototype with an input range of 32 $\sim$ 72 V, constant output of 48 V, a load of 150 W, and switching frequency of 45 kHz. The measured efficiency for the rated load was 97% for maximum input voltage. A comparison of the size and performance of the proposed filter with the topology that uses second-stage LC filters at the input and at the output is also presented. [ABSTRACT FROM AUTHOR]

Published

2020

82. A Family of Low-Spike High-Efficiency Y-Source Inverters.

Author

Liu, Hongpeng, Li, Yuhao, Zhou, Zichao, Wang, Wei, and Xu, Dianguo

Subjects

FAMILIES, ELECTRIC potential, CAPACITORS, LEAKAGE, DIODES

Abstract

In this paper, many impedance-source inverters with coupled inductors have been investigated to obtain a high step-up boost ratio. However, the leakage inductors in these topologies induce great voltage spikes at the dc link, which will increase the voltage stress of switches. Thus, the power level of inverters is limited. Furthermore, the efficiency of the inverters can be degraded by the losses associated with leakage inductors. To address abovementioned issues, this paper proposes a family of low-spike high-efficiency Y-source inverters. The proposed inverters have the ability of eliminating voltage spikes at the dc link and recycling the leakage energy via the additional diode and capacitor. In order to show the excellent characteristics of the proposed topologies, this paper compares the performances of the proposed inverters and the improved-Y-source inverter in many aspects. Simulation and experimental results have verified the abilities of the proposed inverters. [ABSTRACT FROM AUTHOR]

Published

2019

83. Design of Double-Line-Frequency Ripple Controller for Quasi-Single-Stage AC–DC Converter With Audio Susceptibility Model.

Author

Cai, Yaping, Xu, Jianping, Yang, Ping, and Liu, Gao

Subjects

AC DC transformers, SECOND harmonic generation, CORRECTION factors, PULSE width modulation

Abstract

Power factor correction (PFC) converter suffers from serious double-line-frequency output voltage ripple due to the difference between instantaneous ac input power and dc output power. To suppress such double-line-frequency output voltage ripple, a ripple cancellation circuit (RCC) is utilized to generate the same magnitude but 180° phase shifted double-line- frequency voltage ripple. This paper provides an insight into the relationship between control scheme and double-line-frequency ripple suppression from the perspective of audio susceptibility model. For the purpose of reducing the double line frequency ripple, the closed-loop audio susceptibility of series RCC should be designed relatively low at double line frequency. According to such requirement, a ripple controller with improved voltage feed-forward (FF) scheme and quasi-proportional-resonant (QPR) compensator is designed. As QPR compensator can increase the denominator of the closed-loop audio susceptibility, while voltage FF scheme can reduce its numerator, its magnitude at double line frequency is thus greatly reduced and double-line-frequency ripple is also significantly suppressed. Moreover, due to the flexibility of QPR compensator, the proposed ripple controller presents good ripple suppression in a different line frequency application. Finally, experimental results of a flyback PFC with buck-type RCC quasi-single-stage ac–dc converter are provided to verify the validity of the proposed ripple controller. [ABSTRACT FROM AUTHOR]

Published

2019

84. Second Harmonic Current Reduction for a Battery-Driven Grid Interface With Three-Phase Dual Active Bridge DC–DC Converter.

Author

Wang, Deqiang, Nahid-Mobarakeh, Babak, and Emadi, Ali

Subjects

BATTERY storage plants, MARINE terminals, CASCADE converters, BUILDING performance

Abstract

Two-stage isolated battery-driven grid interface (IBDGI) with front-end three-phase dual active bridge (DAB) dc–dc converter is promising to be applied in the residential battery energy storage system for supporting photovoltaic (PV) integration, load shifting, and backup power purposes. However, the second harmonic current (SHC) caused by the pulsating power of the downstream single-phase inverter will increase the battery's degradation and the component stress of the front-end converter. In this paper, a reduction method is proposed for the IBDGI with three-phase DAB converter using a load current feedforward control. The proposed idea is to incorporate virtual impedance to the output impedance of the front-end converter. The easy-to-be-implemented method does not need to modify the original voltage closed-loop controller but suppress SHC while keeping good dynamic performance. As the first step, the small-signal model of the three-phase DAB converter is provided. The parameter sensitivity analysis is proposed to demonstrate that the SHC can be well-suppressed within $\pm \text{20}\%$ parameter error of the feedforward control. Finally, a 1 kW experiment setup is built to verify the performance of the proposed SHC reduction method. [ABSTRACT FROM AUTHOR]

Published

2019

85. 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

86. Diffusive Representation and Sliding Mode Control of Charge Trapping in Al$_2$O$_3$ MOS Capacitors.

Author

Bheesayagari, Chenna Reddy, Pons-Nin, Joan, Atienza, Maria Teresa, and Dominguez-Pumar, Manuel

Subjects

SLIDING mode control, CAPACITORS, NEUTRON irradiation

Abstract

The objective of this paper is to introduce a modeling strategy to characterize the dynamics of the charge trapped in the dielectric of MOS capacitors, using diffusive representation. Experimental corroboration is presented with MOS capacitors made of Alumina in three different scenarios. First, the model predictions are compared with the trapped charge evolution due to arbitrary voltage excitations. Second, the predictions are compared with the measurements of a device in which a sigma–delta control of trapped charge is implemented. Finally, the time evolution when the device is simultaneously controlled and irradiated with X-rays is compared with the predictions. In all cases, a good matching between the models and the measurements is obtained. [ABSTRACT FROM AUTHOR]

Published

2019

87. Modular Multilevel Converter Synthetic Inertia-Based Frequency Support for Medium-Voltage Microgrids.

Author

Yang, Shunfeng, Fang, Jingyang, Tang, Yi, Qiu, Huan, Dong, Chaoyu, and Wang, Peng

Subjects

CASCADE converters, SYNCHRONOUS generators, MICROGRIDS, ELECTRIC power distribution grids, ENERGY storage, FREQUENCY response, CAPACITORS

Abstract

High penetration of renewable energies through fast-response power converters results in a considerable displacement of conventional synchronous generators and losing of system inertia for frequency control. Modular multilevel converters (MMCs) can be employed serving as an interface between the large-scale renewable generation and power grids. In a microgrid with high shares of renewables integrating through MMCs, submodule (SM) capacitors can be used as energy storage to provide a degree of synthetic inertia for system frequency support. This paper quantitatively exploits the MMC synthetic inertia in a microgrid with flexible renewable penetration levels. An MMC inertia coefficient concept is proposed. It is mainly affected by the penetration ratio, the SM capacitance, and the modulation index of an MMC, with the system operation constraints. According to the analysis, a substantial portion of system inertia can be provided by properly designed MMCs. Detailed MMC frequency control loops are presented. The capacitor average voltage is proportionally linked to the frequency deviation, in order to flexibly adjust the capacitor energy during frequency events. The MMC output active power is deliberately and simultaneously regulated according to the capacitor energy change rate. By controlling the MMC capacitor voltage, dc side power, and output active power, an amount of energy can be released or absorbed by SM capacitors to improve the system frequency response during the frequency event transients, while the renewable generation is scarcely influenced. The proposed concept is experimentally verified and the results show that, with proper system parameters and control loops, the line frequency deviation and the rate of change of frequency can be significantly reduced. Good agreements of the system frequency characteristics have been achieved between the theoretical calculation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

88. Full-State Feedback Control of Back-to-Back Converters Based on Differential and Common Power Concepts.

Author

Rodriguez-Cabero, Alberto, Prodanovic, Milan, and Roldan-Perez, Javier

Subjects

REACTIVE power control, CONVERTERS (Electronics), CASCADE control, POWER transmission, PHASE-locked loops, ELECTRONIC feedback

Abstract

The back-to-back (BTB) converter is one of the most popular converter topologies for the control of electrical machines, power transmission systems, and power quality applications. The conventional cascade control structure is commonly used due to its simple design procedure and reliable operation. However, the bandwidth of the dc-link voltage controller has to be limited in order to avoid instability issues and be restrictive in high-performance applications. This paper presents a differential- and common-current (power)-based state-feedback control for BTB converters. This controller features a fast control of active and reactive powers, and a stiff regulation of the dc-link voltage. A theoretical analysis of the proposed controller along with a strategy for current limiting is presented. Its robustness was tested against variations of the filter parameters, the dc capacitance, the grid inductance, and the grid voltage values. The controller was experimentally validated under nominal operation, voltage sags, and connected to a weak grid by using a 15-kVA BTB converter in a laboratory test network. [ABSTRACT FROM AUTHOR]

Published

2019

89. Lyapunov-Based Model Predictive Control of a PUC7 Grid-Connected Multilevel Inverter.

Author

Makhamreh, Hamza, Kukrer, Osman, Sleiman, Mohammad, and Al-Haddad, Kamal

Subjects

LYAPUNOV functions, ELECTRIC controllers, ELECTRIC inverters, COEFFICIENTS (Statistics), SIMULATION methods & models

Abstract

In this paper, a new Lyapunov-based model predictive controller is proposed for a 7-level packed U-cell (PUC7) grid-connected inverter. A cost function of the proposed model predictive controller is designed from the system stability point of view, inspired by the Lyapunov control theory. The proposed controller eliminates the need for gains that are associated with cost function coefficients, as seen in classical model predictive control based controllers. Therefore, the control design problem is significantly simplified. In addition, the average switching frequency is also reduced, as shown in both simulation and experimental results, leading to a reduction in switching losses. Simulation and experimental tests, on a PUC7 lab prototype, demonstrate the excellent performance of the proposed control system, in terms of high disturbance rejection, robustness to parameter mismatches, and fast dynamic response. Such features qualify the proposed control strategy as a good candidate for grid-tied applications. [ABSTRACT FROM AUTHOR]

Published

2019

90. 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

91. Modular Design of a Bipolar-Pulse-Power-Supply-Based LCC Resonant Converter for Strategic Mineral Exploration.

Author

Bae, Jung-Soo, Kim, Jong-Soo, Kim, Hyoung-Suk, Yu, Chan-Hun, and Jang, Sung-Roc

Subjects

BIPOLAR integrated circuits, PROSPECTING, ELECTRIC potential, MODULES (Algebra), CONVERTERS (Electronics)

Abstract

This paper describes a bipolar pulsed power supply for strategic mineral exploration. Depending on the operating conditions, the bipolar pulsed power supply is capable of delivering the required high voltage and low current or low voltage and high current when operated, respectively, in either the grounded dipole mode or the loop mode. Based on a 500-V 12.5-A unit module, series and parallel connections of four modules are configured to satisfy both the grounded dipole mode (2000 V) and the loop mode (50 A), respectively. A unit module comprising an LCC resonant converter and a full-bridge-based bipolar pulse-switching unit is designed. In order to achieve high power density, the leakage inductance of the transformer is used as a resonant inductor in place of an external inductor. Accordingly, the resonant tank parameters are designed to give the resonant current a trapezoidal shape to reduce conduction loss and provide high efficiency. In addition, a simple gate-driving algorithm that uses the repetitive short pulse to cover the frequency range from dc to 8 kHz is proposed to allow the compact design of a minimized gate transformer. In this paper, the detailed design of the resonant circuit and the transformer of a unit module is described, and the operation is verified through simulation and experimental results. Finally, the developed LCC resonant converter achieves the maximum efficiency of 95%, the maximum power factor of 0.96, and a high power density of 806.5 W/L. [ABSTRACT FROM AUTHOR]

Published

2019

92. A Family of Coupled-Inductor-Based Soft-Switching DC–DC Converter With Double Synchronous Rectification.

Author

Cheng, Xu-Feng, Zhang, Yong, and Yin, Chengliang

Subjects

ELECTRIC inductors, CONVERTERS (Electronics), TRANSISTORS, TOPOLOGY, PROTOTYPES

Abstract

In this paper, several new coupled-inductor-based soft-switching dc–dc converters are proposed. These converters are obtained by changing the coupled branch of several existing dc–dc converters. Meanwhile they have similar characteristics to these existing converters, and provide more choices for the practical application. Then by applying an existing efficiency improvement method, which is used in the buck-type soft-switching converter, to all abovementioned converters, several new converters with efficiency improvement characteristics are obtained. This efficiency improvement method utilizes the low conduction performance of the transistor to reduce the loss. In addition, this method has the same control complexity to original topologies, because the auxiliary transistor has the same control timing to one of main transistors. The characteristic of new converters and efficiency improvement method are presented by analyzing two new topologies (boost-type converters). Finally simulation and experimental results are given and analyzed by designing a prototype. Based on these results, soft-switching conditions and efficiency improvement capability are verified. [ABSTRACT FROM AUTHOR]

Published

2019

93. Hybrid MVDC Circuit Breaker Based on Enhanced Arc Voltage of Vacuum Interrupter.

Author

Wu, Yifei, Xiao, Yu, Wu, Yi, Rong, Mingzhe, and Yang, Fei

Subjects

VACUUM arcs, VACUUM circuit breakers, HYBRID integrated circuits, POWER electronics, MAGNETIC fields

Abstract

The hybrid dc circuit breaker (HDCCB) is one of the most promising solutions for the dc interruption. But the power electronics-based load commutation switch (LCS) in the main current path causes the high on-state loss and cost, which inhibits the application of the HDCCB. In this paper, a novel hybrid dc circuit breaker is proposed, in which the vacuum interrupter with the external transverse magnetic field (ETMF) is designed to improve the arc voltage and thus enhance the current commutation to power electronics. The ETMF-based vacuum interrupter achieves the fast current commutation instead of the LCS, which realizes the low on-state loss and cost while preserving the short commutation and interruption time. The arc voltage characteristic with ETMF is analyzed, and the influence of the different factors on the commutation time and di/dt before current zero are investigated in detail. Based on the calculation results, a 10 kV dc breaker prototype based on the proposed topology is developed with the breaking current of 15.5 kA. Finally, the application of the proposed scheme in HVdc grids is discussed. [ABSTRACT FROM AUTHOR]

Published

2022

94. Versatile Three-Level FC-NPC Converter With High Fault-Tolerance Capabilities: Switch Fault Detection and Isolation and Safe Postfault Operation.

Author

Bennani-Ben Abdelghani, Afef, Ben Abdelghani, Hafedh, Richardeau, Frederic, Blaquiere, Jean-Marc, Mosser, Franck, and Slama-Belkhodja, Ilhem

Subjects

ELECTRIC power system faults, FAULT tolerance (Engineering), SWITCHING power supplies, FIELD programmable gate arrays, RENEWABLE energy sources

Abstract

This paper deals with a hybrid fault-tolerant converter topology. It is performed through the connection of a classical three-phase three-level neutral-point-clamped (3L-NPC) converter with a fourth three-level flying capacitor (3L-FC) leg. The 3L-FC leg actively balances the 3L-NPC neutral-point voltage. For normal operation mode, this paper proposes a mathematical design of the filter needed to connect these two different topologies. Experimentally, and thanks to the already existing decoupling capacitors of the 3L-NPC converter, this filter requires the addition of only one low size inductance. When one fault of the power switch of the 3L-NPC occurs, this paper proposes a hardware reconfiguration technique based on only two fuses and one thyristor per leg allows a safe postfault operation recovery. This is achieved thanks to a simple fault-detection method and a new technique that combines fault leg isolation and corresponding phase postfault connection to the neutral point. Also, a dedicated field-programmable gate array (FPGA)-based control of the reconfigured converter is synthetized to ensure power system availability under fault operation mode. The converter fault-tolerant capabilities are addressed through simulation results and original overall experimental validations of the fault detection and isolation and the postfault operation steps, carried out on a 15-kW prototype converter. [ABSTRACT FROM AUTHOR]

Published

2017

95. An Output-Current-Dependent DC-Link Energy Regulation Scheme for a Family of Soft-Switched AC/DC Offline LED Drivers Without Electrolytic Capacitors.

Author

Lam, John, El-Taweel, Nader, and Abbasi, Mehdi

Subjects

AC DC transformers, LIGHT emitting diodes, ZERO current switching, ZERO voltage switching, POWER factor measurement

Abstract

In order to provide a constant current to the Light-emitting diodes (LEDs) and to minimize the size and cost of the driver circuit in ac/dc offline LED drivers, electrolytic capacitors are conventionally used due to their high energy density and low cost. However, electrolytic capacitors are sensitive to operating temperature and have much shorter lifetime than the LED semiconductor devices. This paper proposes an improved control scheme that is capable to control the output LED current and regulate the dc-link capacitor's energy simultaneously for a family of single-stage soft-switched high power factor LED driver topologies. Each of these topologies consists of an integrated power factor correction (PFC) circuit. Due to the proposed controller's capability to control the LED current directly via variable frequency control and the dc-link capacitor's voltage via duty ratio control, the required energy storage capacitance can be significantly reduced, thereby allowing small size film capacitor to be used as the energy storage capacitor. Simulation results are provided on two different LED driver topologies, one with an integrated boost PFC stage and the other one with an integrated buck–boost PFC stage, to verify the performance of the proposed control scheme. Experimental results are also been provided on a 12-W prototype to highlight the merits of this paper. [ABSTRACT FROM PUBLISHER]

Published

2017

96. Synchronverters With Better Stability Due to Virtual Inductors, Virtual Capacitors, and Anti-Windup.

Author

Natarajan, Vivek and Weiss, George

Subjects

ELECTRIC inverter design & construction, SYNCHRONOUS electric machinery, ELECTRIC power system stability, ELECTRIC current regulators, CAPACITORS

Abstract

Synchronverters are inverters that mimic the behavior of synchronous generators. In this paper, we propose five modifications to the synchronverter algorithm from the paper “Synchronverters: Inverters that mimic synchronous generators,” (IEEE Trans. Ind. Electron., vol. 58, no. 4, pp. 1259–1267, Apr. 2011), to improve its stability and performance. These modifications are implemented in software and do not require any changes in the inverter hardware. The first two modifications concern the control of the virtual field current in the synchronverter so that it is more robust to faults. We prove the stability of the grid-connected synchronverter with this improved field current controller. The third modification is to increase the effective size of the filter inductors virtually. This is motivated using results from the stability analysis of a constant field current synchronous generator connected to an ac power grid and also by practical considerations. Simulations and experiments show that this leads to a much better response to changes in grid frequency, voltage, or to imbalance in the grid. The fourth modification is to change the formula for the (virtual) nominal active mechanical torque to take into account the (virtual) losses in the output impedance of the converter. This makes the tracking of the desired active power much more accurate. The fifth modification is to introduce virtual capacitors in series with the inverter outputs to filter spurious dc components from the current supplied to the grid. [ABSTRACT FROM PUBLISHER]

Published

2017

97. Derivation of Voltage Source Multilevel Converter Topologies.

Author

Yuan, Xibo

Subjects

VOLTAGE control, INSULATED gate bipolar transistors, LOW voltage systems, ELECTRIC network topology, HARMONIC analysis (Mathematics), CASCADE converters

Abstract

Multilevel converters have gained popularity in both medium voltage and low voltage applications. To find out the connections between various multilevel voltage-source converter topologies and to reveal how to obtain new topologies, this paper has presented four methods to derive multilevel converter topologies. Many existing topologies as well as new topologies can be derived with the methods presented in this paper. The fundamental characteristics of the multilevel converters which determine their usability such as dc-link neutral point voltage balancing and flying capacitor voltage control are also investigated in this paper with a mathematical model and an example. It is expected that more new topologies will be invented based on the work in this paper for emerging applications. [ABSTRACT FROM AUTHOR]

Published

2017

98. A Full Soft-Switching ZVZCS Flyback Converter Using an Active Auxiliary Cell.

Author

Tarzamni, Hadi, Babaei, Ebrahim, and Gharehkoushan, Amirreza Zarrin

Subjects

ZERO current switching, PULSE width modulation, CAPACITORS, DC-to-DC converters, ELECTRIC network topology

Abstract

In this paper, a new soft switching flyback dc–dc converter with a simple zero-voltage and zero-current switching (ZVZCS) cell is proposed. The auxiliary resonant cell consists of one switch, one diode, one inductor, and two capacitors. It provides ZVZCS not only for the main switch but also for the auxiliary switch at both turn-on and turn-off times. In addition, all the auxiliary diodes and body diodes of the switches operate under full ZVZCS except the output diode which turns off only with zero current switching. This soft switching technique makes the proposed converter have less switching losses which leads the converter to operate in higher frequencies and efficiency. Another outstanding feature of the proposed converter is using the auxiliary resonant cell out of the main power path to have lower voltage stress on the switches. In this paper, pulse width modulation (PWM) is employed to control the main switch. A detailed mode analysis of the proposed converter operation is presented along with design procedure. Finally, the accuracy performance of the converter is verified through a 60 W experimental prototype results. [ABSTRACT FROM AUTHOR]

Published

2017

99. Adaptive Voltage Control for Bidirectional Converter in Flicker-Free Electrolytic Capacitor-Less AC?DC LED Driver.

Author

He, Jiexiu, Ruan, Xinbo, and Zhang, Li

Subjects

VOLTAGE control, ELECTROLYTIC capacitors, LIGHT emitting diodes, ADAPTIVE control systems, POWER factor measurement

Abstract

In this paper, an electrolytic capacitor-less ac–dc light-emitting diode (LED) driver, consisting of a power factor correction (PFC) converter and a buck/boost bidirectional converter, is investigated. The buck/boost bidirectional converter is connected in parallel with the output of the PFC converter and serves to absorb the second harmonic current in the PFC output current, leaving only a dc component to drive the LEDs. This paper proposes an adaptive voltage control scheme for the storage capacitor in the buck/boost bidirectional converter to make the storage capacitor voltage adaptively decrease as the load becomes lighter. Hence, the power losses of the buck/boost bidirectional converter could be reduced at light load. Experimental results are provided to verify the effectiveness of the proposed control scheme. [ABSTRACT FROM PUBLISHER]

Published

2017

100. High-Voltage Gain Half-Bridge Z-Source Inverter With Low-Voltage Stress on Capacitors.

Author

Babaei, Ebrahim and Shokati Asl, Elias

Subjects

ELECTRIC inverters, LOW voltage systems, CAPACITORS, STRESS waves, TOPOLOGY

Abstract

In this paper, a new topology for half-bridge Z-source inverter is proposed. The proposed topology has only one impedance network. Unlike to the conventional half-bridge inverter, the proposed topology can provide zero voltage level at the output. It also increases output voltage level and stabilizes it in the desired value. Capacitor voltage stress in the proposed topology is low, and, therefore, nominal voltage of capacitor and cost decreases. In this paper, the steady-state analysis of the proposed inverter in two new operations which are named synchronous operation of diodes and asynchronous operation of diodes is conducted based on mathematics calculations. A method to obtain high-voltage gains by cascading the Z-network and combining middle inductors is presented that leads to cost, size, and weight reduction. Comparison among the proposed converter with conventional ones shows its excellent performance. The experimental results have good agreement with analytical analysis for the proposed topology. [ABSTRACT FROM PUBLISHER]

Published

2017