Your search keyword '"Huang, Alex Q."' showing total 20 results

1. A Novel Order Reduced Synchronous Power Control for Grid-Forming Inverters.

Author

Quan, Xiangjun, Huang, Alex Q., and Yu, Hui

Subjects

*ELECTRIC power distribution grids, *DYNAMICAL systems, *EPISTOLARY fiction, *VOLTAGE control, *OSCILLATIONS

Abstract

Nowadays, the grid-forming inverter, also referred as the voltage-controlled inverter, has gained greater attention due to its advantages in providing power support to the grid. The power control is central to grid-forming inverters in realizing grid-support functionalities, such as the droop control or virtual inertia emulation. However, in these controls, the dynamic response of the instantaneous power usually suffers from overshoots and oscillations. To improve the dynamic response of the injected instantaneous power, this letter introduces a novel synchronous active power control for the voltage-controlled grid-connected inverter. The droop coefficient can be released from adjusting the damping factor of the system. A novel design method is proposed to reduce the second-order power loop to a first-order model. Consequently, the droop and reference-following controls operate like a first-order system with an excellent dynamic response. Moreover, the virtual inertia can be designed freely without affecting the performance of the power control. The correctness of the control is verified experimentally. [ABSTRACT FROM AUTHOR]

Published

2020

2. Predictive ZVS Control With Improved ZVS Time Margin and Limited Variable Frequency Range for a 99% Efficient, 130-W/in3 MHz GaN Totem-Pole PFC Rectifier.

Author

Huang, Qingyun, Yu, Ruiyang, Ma, Qingxuan, and Huang, Alex Q.

Subjects

PREDICTIVE control systems, POWER density, ZERO voltage switching, DEGREES of freedom

Abstract

This paper proposes a predictive zero-voltage-switching (ZVS) control with improved ZVS time margin and limited variable switching frequency range for a 99% efficient megahertz (MHz) GaN totem-pole power-factor-correction (PFC) rectifier. The conventional ZVS control methods for totem-pole PFC may lead to zero ZVS time margin and ultra-wide switching frequency range. This paper proposes that the synchronous rectifier (SR) turn-off current is a new degree of freedom for the ZVS control. Thus, the proposed cycle-by-cycle predictive ZVS control method controls the SR turn-off currents to extend the ZVS time margin and to reduce the maximum switching frequency. With the proposed ZVS control, the minimum ZVS time margin and a limited maximum switching frequency can be realized in a MHz GaN-based totem-pole PFC. With the improved ZVS time margin, the reliability for realizing ZVS is significantly improved. With the limited maximum frequency and the limited frequency range, the difficulty in high-speed current sensing and digital control is reduced, and the frequency-related loss is also reduced, which is important for improving the light-load efficiency. To accurately extract the current and timing parameters for the proposed ZVS control, an analytical model for the ZVS totem-pole PFC is proposed. The proposed ZVS control and analytical model are applicable over the full input and output voltage range, and over the full load range. In addition, a hybrid current control is proposed and implemented based on the proposed ZVS control. Finally, a 3.2-kW MHz GaN totem-pole PFC prototype is developed and tested with full-range ZVS, minimum ZVS time margin, limited switching frequency range, 99% peak efficiency, and 130-W/in3 power density based on the proposed ZVS control and system control strategy. The realized efficiency, power level, and power density are among the best ever reported for the GaN-based totem-pole PFC. [ABSTRACT FROM AUTHOR]

Published

2019

3. 7.2-kV Single-Stage Solid-State Transformer Based on the Current-Fed Series Resonant Converter and 15-kV SiC mosfets.

Author

Zhu, Qianlai, Wang, Li, Huang, Alex Q., Booth, Kristen, and Zhang, Liqi

Subjects

ELECTRIC transformers, METAL oxide semiconductor field-effect transistors, ZERO voltage switching, VOLTAGE control, ENERGY storage equipment

Abstract

This paper proposes a novel two-level single-stage direct ac–ac converter for realizing a 7.2-kV medium-voltage (MV) solid-state transformer (SST) based on 15-kV SiC mosfets. A new current-fed series resonant converter (CFSRC) topology is proposed to address major challenges in MV ac–ac converters such as achieving zero-voltage switching (ZVS) for the MV mosfets across wide voltage and load ranges and minimizing system capacitance. The topology is analyzed with both time-domain analysis and first harmonic approximation to provide useful equations for circuit design. Constant deadtime strategy is adopted, allowing partial ZVS to occur at low-voltage (LV) levels. ZVS behavior over wide voltage range is investigated, and calculation of the associated loss from partial ZVS is presented. System parameters are optimized based on the tradeoff between conduction loss and switching loss. The 15-kV mosfet has been tested continuously at a park voltage of 10 kV and 37 kHz, indicating stable device operation and an extremely high voltage × frequency figure of merit. Moreover, inherent cycle-by-cycle current limiting in the proposed CFSRC under output short-circuit circumstance is realized by paralleling diodes to the LV resonant capacitors. Without employing any additional current sensors, the input and circulating currents are limited to a safe range automatically when the short-circuit occurs. This paper presents detailed short-circuit protection operating principles and peak resonant current equation to aid the design of the resonant tank. A full-scale and compact SST that converts 7.2 kV ac to 240 V ac is developed to verify the theoretical analysis. This is the highest reported voltage rating for two-level-based power converters without device series connection. ZVS is verified and achieved over wide voltage and load ranges with a peak efficiency of 97.8%. A short-circuit experiment is conducted at 3-kV peak voltage to verify the analysis. Experimental results closely match the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2019

4. A Novel Dominant Dynamic Elimination Control for Voltage-Controlled Inverter.

Author

Quan, Xiangjun, Dou, Xiaobo, Wu, Zaijun, Hu, Minqiang, Song, Hui, and Huang, Alex Q.

Subjects

VOLTAGE control, MICROGRIDS, ELECTRIC power distribution, ENERGY consumption, COMPUTER simulation, ELECTRICAL harmonics

Abstract

The inverter control plays a critical role in microgrid (MG) hierarchical control structure. In this paper, a dominant dynamic elimination control is studied for the voltage-controlled MG inverter. A compact control structure is designed to include separated static state feedback and feedforward terms. Benefitting from the designed control structure, the dominant dynamic can be canceled by the static feedforward control via the fundamental zero-pole cancelation principle. Thanks to the cancelation of the dominant dynamic, the load disturbance-rejection performance is improved, and the approximate unity gain from the reference to output is also achieved from the perspective of the application control layer, thereby the performance of power control for the upper application is improved. Furthermore, the strong robustness to parameter variations and low total harmonic distortion are also achieved. Comparative simulations and experiments are adopted to verify the effectiveness and superiority of the designed approach. [ABSTRACT FROM PUBLISHER]

Published

2018

5. Load Current Decoupling Based LQ Control for Three-Phase Inverter.

Author

Quan, Xiangjun, Wu, Zaijun, Dou, Xiaobo, Hu, Minqiang, and Huang, Alex Q.

Subjects

ELECTRIC inverters, DEGREES of freedom, ELECTRICAL load, HARMONIC distortion (Physics), ELECTRIC potential

Abstract

In classical inverter control, load current (disturbance) decoupling control is often used to improve the control performance. Yet, in a recent state-space control structure for multiresonant controllers, the load current decoupling technique is less studied. Moreover, in the classical control, the load current decoupling only has one control degree of freedom. Therefore, in this paper, a load current decoupling control combed linear quadratic (LQ) regulation is investigated, the proposed control structure that manipulates α and β axes as a unified system is adopted to increase the control degree of freedom. The LQ control synthesizes the state feedback control law including gains of the resonant controllers. Two general criteria, namely H\infty norm and zero dynamic, are proposed as the design guideline for the load current decoupling control. The effectiveness and robustness of the proposed approach are validated through MATLAB/Simulink simulations and experiments with a 5-kVA testbed. The results prove that some favorable performances, for example, the fast recovering time, the small voltage drop, and the low total harmonic distortion, are achieved by the proposed approach compared to the classical dual-loop proportional-resonant (PR) control with load current decoupling and the optimal H\infty control. [ABSTRACT FROM AUTHOR]

Published

2018

6. Integration of DC Microgrids as Virtual Synchronous Machines Into the AC Grid.

Author

Chen, Dong, Xu, Yizhe, and Huang, Alex Q.

Subjects

MICROGRIDS, ELECTRIC power distribution, SMART power grids, ELECTRIC power distribution automation, CASCADE converters

Abstract

A smart and autonomous integration concept for dc microgrids into the legacy ac grid is proposed based on the virtual synchronous machine (VSM) concept. It utilizes a dc–ac converter as a universal VSM-based interface (VSMBI) between the ac grid and various distributed energy resources (DER) connected on the dc side. The control strategy of it includes: 1) a frequency regulation improved from previous VSM works, which is suitable for the microgrid integration; 2) an improved dual droop control between the ac frequency and the dc side energy storages; 3) a power system stabilizer to enhance the system stability. Under this concept, the VSMBI integrates the DERs, loads and energy storages in the dc microgrid into a VSM. The VSMBI and the dc microgrid together will respond to short-term and long-term requirements of the grid frequency regulation, and achieve autonomous power management for the ac grid and the dc microgrid. It is therefore an important step forward in supporting high DER penetration. The concept, its design and small-signal analysis are presented in this paper. Its effectiveness and functions are verified by simulation and experimental results. [ABSTRACT FROM PUBLISHER]

Published

2017

7. FREEDM system: An electronic smart distribution grid for the Future.

Author

Karady, George G., Huang, Alex Q., and Baran, Mesut

Abstract

The NSF-sponsored FREEDM Engineering Research Center (ERC) is developing a revolutionary smart distribution grid, which will facilitate seamless integration of distributed renewable power generation and storage resources. The major component of the grid is a 12.47kV loop that is divided into sections. Each section is terminated by an electronic circuit breaker. The loads within the section are supplied by solid-state transformer, whose function is to rectify the 60Hz AC voltage and covert it to high frequency AC voltage. A high frequency transformer reduces the voltage, which is corrected to obtain 400V DC. This voltage will then supply the distributed generation and storage capabilities. The 400V DC will be converted to 240V/120V AC voltage, which will supply the local loads. The major components of the generation and storage system are in advanced stage of development. This panel paper describes the system and the developed components, together with the computer control of the system. [ABSTRACT FROM PUBLISHER]

Published

2012

8. Power management strategy for plug and play DC microgrid.

Author

Yu, Xunwei, Wang, Fei, and Huang, Alex Q.

Abstract

DC microgrid is getting more and more attention as an effective and efficient solution to integrate different kinds of renewable energy storage and energy resources with DC loads. A typical DC microgrid envisioned for future DC powered residential homes is investigated in this paper, including distributed power management strategy design, plug and play function implementation, communication ports to monitor the system performance. In this power management strategy, each module in the system is in the distributed control and can be plugged and unplugged into the system without affecting the system performance. Furthermore, the communication ports guarantee all modules information can be sent to the control center to monitor the whole system information. [ABSTRACT FROM PUBLISHER]

Published

2012

9. A new nonisolated three-port DC-DC converter with high step-up/down ratio.

Author

Chen, Yen-Mo, Yu, Xunwei, and Huang, Alex Q.

Abstract

A new nonisolated three-port dc-dc converter integrating PV and battery power is proposed in this paper. The topology includes two coupled inductors and two active-clamp circuits. The coupled inductors are used to achieve high step up/down gain and to reduce the voltage stress on both primary and auxiliary switches. Two sets of active-clamp circuits in the proposed converter are used to recycle the energy stored in the leakage inductors. Therefore, the system efficiency can be improved. Charging/discharging transition of the battery is autonomous while tracking the maximum power of PV source and regulating the output voltage simultaneously. When the charging voltage is too high, the control loop of PV port will be switched from maximum power point tracking (MPPT) to battery voltage regulation. Experimental results of a 200W laboratory prototype are presented to verify the performance of the proposed three-port converter. [ABSTRACT FROM PUBLISHER]

Published

2012

10. A monolithic CMOS synchronous Buck converter with a fast and low-cost current sensing scheme.

Author

Du, Yu, Liu, Qiaoqiao, and Huang, Alex Q.

Abstract

Monolithic power management integrated circuit chips are widely used in both consumer products and industrial products. In some applications the load changes drastically. A 2MHz integrated synchronous Buck converter is designed to manage the dynamic load for these applications. The current mode control and active voltage positioning are employed to achieve high transient performance at pulse load conditions. A fast and lossless current sensing scheme with a low-cost, high-voltage-gain and high-bandwidth amplifier configured in open loop is proposed to sense the inductor current for implementing peak current control. With the proposed fast current sensor, the simple first-order compensator is required to obtain active voltage positioning with good stability and transient response. The chip was fabricated with 0.5um CMOS process and the test results were reported. [ABSTRACT FROM PUBLISHER]

Published

2012

11. Design and Demonstration of a 3.6-kV–120-V/10-kVA Solid-State Transformer for Smart Grid Application.

Author

Xu She, Xunwei Yu, Fei Wang, and Huang, Alex Q.

Subjects

SMART power grids, SOLID state electronics, PROTOTYPES, ELECTRIC power conversion, POWER electronics

Abstract

Solid-state transformer (SST) has been regarded as one of the most important emerging technologies for traction system and smart grid application. This paper presents the system design and performance demonstration of a high-voltage SST lab prototype that works as the active grid interface in smart grid architecture. Specifically, the designs of the key components of the system, including both power stage and controller platform, are presented. In addition, the advanced control system is developed to achieve high-performance operation. Furthermore, integration issues of SST with dc microgrid are presented. Lastly, tests under different scenarios are conducted to verify the following advanced features of the presented SST technology: 1) VAR compensation; 2) voltage regulation; 3) source voltage sag operation; and 4) microgrid integration. [ABSTRACT FROM AUTHOR]

Published

2014

12. System Integration and Hierarchical Power Management Strategy for a Solid-State Transformer Interfaced Microgrid System.

Author

Xunwei Yu, Xu She, Xijun Ni, and Huang, Alex Q.

Subjects

SYSTEM integration, ELECTRIC power management, SOLID state batteries, ELECTRIC transformers, SYSTEMS on a chip

Abstract

This paper investigates, and for the first time presents, the system integration of a novel solid-state transformer (SST) interfaced microgrid system. Accordingly, a hierarchical power management strategy is proposed for this system to enable islanding mode operation, SST enabled operation, and the seamless transfer between two modes. The proposed power management strategy includes three control levels: primary control for the local controller; secondary control for the dc microgrid bus voltage recovery; and tertiary control to manage the battery state of charge. The proposed system architecture and control strategies are detailed in this paper and a lab test bed is constructed to verify the system performance. Finally, several typical case studies are carried out. The experimental results verify the proposed system and distributed power management strategy. [ABSTRACT FROM AUTHOR]

Published

2014

13. Power Management for DC Microgrid Enabled by Solid-State Transformer.

Author

Yu, Xunwei, She, Xu, Zhou, Xiaohu, and Huang, Alex. Q.

Abstract

A novel distributed power management scheme is proposed in this paper for a DC microgrid system, which is enabled by Solid-State transformer (SST). The proposed system includes distributed renewable energy resource (DRER) and distributed energy storage device (DESD). The proposed distributed control algorithm, which only relies on the local information and guarantees full utilization of each module in the system based on their characteristics, is applied to both SST and DC microgrid. To this end, a simulation platform is developed in MATLAB/Simulink, in which Photovoltaic (PV), fuel cell and battery are selected as the typical DRERs and DESD, respectively. Lastly, several typical case studies are carried out and the simulation results verify the proposed distributed power management. [ABSTRACT FROM PUBLISHER]

Published

2014

14. A High Step-Up Three-Port DC–DC Converter for Stand-Alone PV/Battery Power Systems.

Author

Chen, Yen-Mo, Huang, Alex Q., and Yu, Xunwei

Subjects

*DC-to-DC converters, *PHOTOVOLTAIC power systems, *ELECTRIC batteries, *TOPOLOGY, *ELECTRIC inductors, *PROTOTYPES

Abstract

A three-port dc–dc converter integrating photovoltaic (PV) and battery power for high step-up applications is proposed in this paper. The topology includes five power switches, two coupled inductors, and two active-clamp circuits. The coupled inductors are used to achieve high step-up voltage gain and to reduce the voltage stress of input side switches. Two sets of active-clamp circuits are used to recycle the energy stored in the leakage inductors and to improve the system efficiency. The operation mode does not need to be changed when a transition between charging and discharging occurs. Moreover, tracking maximum power point of the PV source and regulating the output voltage can be operated simultaneously during charging/discharging transitions. As long as the sun irradiation level is not too low, the maximum power point tracking (MPPT) algorithm will be disabled only when the battery charging voltage is too high. Therefore, the control scheme of the proposed converter provides maximum utilization of PV power most of the time. As a result, the proposed converter has merits of high boosting level, reduced number of devices, and simple control strategy. Experimental results of a 200-W laboratory prototype are presented to verify the performance of the proposed three-port converter. [ABSTRACT FROM AUTHOR]

Published

2013

15. Voltage and Power Balance Control for a Cascaded H-Bridge Converter-Based Solid-State Transformer.

Author

Zhao, Tiefu, Wang, Gangyao, Bhattacharya, Subharshish, and Huang, Alex Q.

Subjects

VOLTAGE control, BRIDGE circuits, VOLTAGE-frequency converters, SOLID state electronics, POWER transformers, REACTIVE power

Abstract

The solid-state transformer (SST) is an interface device between ac distribution grids and dc distribution systems. The SST consists of a cascaded multilevel ac/dc rectifier stage, a dual active bridge (DAB) converter stage with high-frequency transformers to provide a regulated 400-V dc distribution, and an optional dc/ac stage that can be connected to the 400-V dc bus to provide residential 120/240 Vac. However, due to dc-link voltage and power unbalance in the cascaded modules, the unbalanced dc-link voltages and power increase the stress of the semiconductor devices and cause overvoltage or overcurrent issues. This paper proposes a new voltage and power balance control for the cascaded H-Bridge converter-based SST. Based on the single-phase dq model, a novel voltage and the power control strategy is proposed to balance the rectifier capacitor voltages and the real power through parallel DAB modules. Furthermore, the intrinsic power constraints of the cascaded H-Bridge voltage balance control are derived and analyzed. With the proposed control methods, the dc-link voltage and the real power through each module can be balanced. The SST switching model simulation and the prototype experiments are presented to verify the performance of the proposed voltage and power balance controller. [ABSTRACT FROM AUTHOR]

Published

2013

16. Coupling Effect Reduction of a Voltage-Balancing Controller in Single-Phase Cascaded Multilevel Converters.

Author

Xu She, Huang, Alex Q., Tiefu Zhao, and Gangyao Wang

Subjects

*VOLTAGE control, *PID controllers, *CASCADE converters, *ALGORITHMS, *CAPACITORS

Abstract

This paper presents a new voltage-balancing controller for cascaded multilevel converters, especially for single-phase cascaded multilevel converters. It proposes a control algorithm that devotes itself not only to balancing the floating dc capacitors but also to eliminating the coupling effect between the voltage-balancing controller and the original system controller (controller without additional voltage-balancing controllers). Specifically, the average model in the d-q coordinate frame is derived and the control law is established. Then, the coupling effect between the voltage-balancing controller and the original system controller is identified and a new expression for duty cycle modification is proposed thus to eliminate the effect. Furthermore, this paper gives the design considerations of the pro- posed method, including the derivation of key transfer functions and effective voltage-balancing area, for the completeness of the discussion. Moreover, the reference generation techniques of the voltage-balancing controller are also discussed. This paper investigates the voltage imbalance in the soft-start process caused by an unsuitable reference, and presents a simple modified reference generation solution. Finally, both simulation and experimental results verify the performance of the proposed control system. [ABSTRACT FROM AUTHOR]

Published

2012

17. Modulation Technique to Reverse Power Flow for the Isolated Series Resonant DC–DC Converter With Clamped Capacitor Voltage.

Author

Du, Yu, Lukic, Srdjan M., Jacobson, Boris S., and Huang, Alex Q.

Subjects

DC-to-DC converters, ELECTRONIC modulation, CAPACITORS, ENERGY storage, RESONANCE

Abstract

The series resonant dc–dc converter with clamped capacitor voltage exhibits excellent characteristics in forward operating mode, including simple control, high reliability, soft switching, high power density, and inherently limited load fault current. However, the conventional single angle phase-shift modulation that works well in the forward mode cannot reverse the power flow. In this paper, we propose a modulation strategy for reverse-mode operation by utilizing three phase-shift angles afforded by the two active full bridges of the circuit. We identify the optimal modulation trajectories in 3-D modulation space and implement a lookup-table-based modulator for power flow control. A high-fidelity simulation model of a 35-kW 750-V input, 300–600-V output, and 50-kHz insulated-gate bipolar-transistor-based converter was used for verification. The proposed modulation scheme and efficiency calculations were validated on a scaled-down (15-kW) prototype. The power loss distribution was analyzed for further converter efficiency optimization. [ABSTRACT FROM PUBLISHER]

Published

2012

18. On Integration of Solid-State Transformer With Zonal DC Microgrid.

Author

She, Xu, Huang, Alex Q., Lukic, Srdjan, and Baran, Mesut E.

Abstract

The contribution of this paper has been focused on investigating a new microgrid architecture that integrates the solid-state transformer with zonal dc microgrids. By utilizing the dc and ac links of the solid-state transformer, both ac and dc networks can access the distribution system, which renders the coordinate management of the power and guarantees high power supply reliability. In addition, the presented system together with the proposed power management strategy can minimize the effect of newly established zonal dc microgrid to the existing power grid, of which promises a better stability. To this end, this paper takes the photovoltaic and battery as the typical renewable energy resource and energy storage device, and develops a simulation platform for system study. Simulation results are shown to demonstrate the feasibility of the proposal. [ABSTRACT FROM PUBLISHER]

Published

2012

19. Research on Voltage and Power Balance Control for Cascaded Modular Solid-State Transformer.

Author

Shi, Jianjiang, Gou, Wei, Yuan, Hao, Zhao, Tiefu, and Huang, Alex Q.

Subjects

ELECTRIC potential, CASCADE converters, ELECTRIC transformers, POWER electronics, BRIDGE circuits, BRIDGE rectifiers, SEMICONDUCTORS, ELECTRIC current rectifiers

Abstract

The solid-state transformer (SST) is one of the key elements in power electronic-based microgrid systems. The single-phase SST consists of a modular multilevel ac–dc rectifier, a modular dual active bridge (DAB) dc–dc converter with high-frequency transformers, and a dc–ac inverter stage. However, due to dc bus voltage and power unbalancing in each module, the modular SST often presents instability problems making its design difficult and causing unpredictable behavior. Moreover, the unbalanced dc-link voltages increase the stress of the semiconductor devices, and also cause high harmonic distortions of grid current, therefore, necessitating the use of a bigger ac filter. This paper presents a novel single-phase d–q vector-based common-duty-ratio control method for the multilevel rectifier, and a voltage feedforward and feedback based controller for the modular DAB converter. With the proposed control methods, the dc-link voltage and power in each module can be balanced. In addition, the low-distortion grid current, unity power factor, and bidirectional power flow can be achieved. Simulation and experimental results are presented to validate the proposed control methods. [ABSTRACT FROM AUTHOR]

Published

2011

20. Transient-Voltage-Clamp Circuit Design Based on Constant Load Line Impedance for Voltage Regulator Module.

Author

Lim, Sungkeun, Fan, Jiwei, and Huang, Alex Q.

Subjects

VOLTAGE-clamp techniques (Electrophysiology), VOLTAGE regulators, ELECTRONIC circuit design, ELECTRIC impedance, CAPACITORS, DC-to-DC converters, ELECTRIC transients

Abstract

A transient-voltage-clamp (TVC) circuit acts as a replacement of bulk capacitors, which is required for voltage regulator (VR) module (VRM) to clamp output voltage spikes. With the TVC circuit, VRM size is greatly reduced with similar transient performance. This paper presents a new TVC circuit. This TVC circuit is designed based on the constant load line impedance which is recently given by Intel's VRM11.0. The TVC circuit works in parallel with VR decoupling capacitors to achieve faster voltage regulation. The impedances of the VR, output capacitors, and the proposed TVC circuit are analyzed. The TVC circuit design procedure is described, and the transient performance and power consumption are discussed. The theoretical analysis is verified by simulation results. Moreover, the proposed TVC circuit is fabricated with a 0.6-\mu \m CMOS process, and experimental results verify the simulation results and theoretical analysis. [ABSTRACT FROM PUBLISHER]

Published

2010