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2. Parameter Optimization of Adaptive Flux-Weakening Strategy for Permanent-Magnet Synchronous Motor Drives Based on Particle Swarm Algorithm.
- Author
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Xu, Wei, Ismail, Moustafa Magdi, Liu, Yi, and Islam, Md Rabiul
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PARTICLE swarm optimization , *TORQUE control , *SYNCHRONOUS electric motors , *ELECTRIC potential , *ALGORITHMS , *PERMANENT magnet motors , *MEASUREMENT errors , *TRANSFER functions - Abstract
Operating in the high-speed range is necessary for high-performance permanent-magnet synchronous motor (PMSM) drives. However, due to the back electromotive force effect, the PMSM is approaching the voltage limit at field decreasing scope. This paper presents a new flux-weakening scheme along with an improved vector control strategy to alleviate the influence of this problem. Control parameters of the anti-windup proportional and integral (AWPI) controller are optimized off-line in relying on an adaptive velocity particle swarm optimization (AVPSO) algorithm. The AVPSO algorithm considers the summation of AWPI measurement error which is the objective function of the optimization problem without knowing the transfer function of the plant. Hence, the tuned flux-weakening controller with a filter is used to set the flux level without saturating the current controllers. Meanwhile, the other controllers of inner and outer loops award a great dynamic and steady-state performance for the PMSM. In the proposed scheme, the flux-weakening control is not dependent on machine parameters that adapts the flux level automatically and provide a fast transition between the constant torque region and the field-weakening region. Effectiveness and advantages of the proposed scheme are presented in this paper through both simulation and experimental results. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
3. A Novel Seven-Level Active Neutral-Point-Clamped Converter With Reduced Active Switching Devices and DC-Link Voltage.
- Author
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Siwakoti, Yam P., Mahajan, Akshay, Rogers, Daniel J., and Blaabjerg, Frede
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PULSE width modulation transformers , *REACTIVE power , *PASSIVE components , *ELECTRIC potential , *COST control , *SYSTEMS design - Abstract
This paper presents a novel seven-level inverter topology for medium-voltage high-power applications. It consists of eight active switches and two inner flying capacitor (FC) units forming a similar structure as in a conventional active neutral-point-clamped (ANPC) inverter. This unique arrangement reduces the number of active and passive components. A simple modulation technique reduces cost and complexity in the control system design without compromising reactive power capability. In addition, compared to major conventional seven-level inverter topologies, such as the neutral point clamped, FC, cascaded H-bridge, and ANPC topologies, the new topology reduces the dc-link voltage requirement by 50%. This recued dc-link voltage makes the new topology appealing for various industrial applications. Experimental results from a 2.2-kVA prototype are presented to support the theoretical analysis presented in this paper. The prototype demonstrates a conversion efficiency of around 97.2% ± 1% for a wide load range. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
4. Modular Two-Switch Flyback Converter and Analysis of Voltage-Balancing Mechanism for Input-Series and Output-Series Connection.
- Author
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Pagliosa, Mauro Andre, Lazzarin, Telles Brunelli, and Barbi, Ivo
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VOLTAGE control , *MODULAR design , *ELECTRIC potential , *PROTOTYPES - Abstract
The voltage-balance mechanism is a required ability to simplify the control scheme for modular input-series and output-series ($\text{ISOS}$) connection, in spite of the fairly large number of studies, such mechanism has not been addressed clearly and satisfactory. This paper proposes a methodology, based on the converter output characteristics, to standardize the analysis of voltage-balance mechanism in steady state, which allows understanding the behavior of voltage sharing among the modules in steady state, in the presence of mismatched parameters for $\text{ISOS}$ connection of modular converters. In addition, the $\text{ISOS}$ connected modular two-switch flyback converter is presented. The intrinsic voltage-balance mechanism, even operating in continuous conduction mode, make this converter feasible, as an alternative to the predecessors modular converters. The operation and analysis of the proposed connection were corroborated, based on the experiment carried out on a laboratory prototype with three modules: ${\text{1}}, {\text{200 V}}_{\text{dc}}$ total input voltage, ${\text{1.5 kW}}$ rated power, and $\text{50 kHz}$ switching frequency. This paper is accompanied by a video demonstrating the operation, in steady state, of the laboratory prototype. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
5. Control Strategy of DC-Link Voltage for Single-Phase Back-to-Back Cascaded H-Bridge Inverter for MV Drive With Interfacing Transformer Having Tertiary Winding.
- Author
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Yoo, Jeong-Mock, Jung, Hyun-Sam, and Sul, Seung-Ki
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ELECTRIC potential , *VOLTAGE control , *CASCADE converters , *PULSE width modulation transformers , *MOTOR drives (Electric motors) , *VOLTAGE-frequency converters , *REFERENCE values , *COMPUTER simulation - Abstract
This paper describes a dc-link voltage control method of a single-phase back-to-back cascaded H-bridge inverter (SBCI) for a medium-voltage motor drive system. The main advantage of the SBCI topology over the conventional regenerative cascaded H-bridge topology with a three-phase active front-end (AFE) is a simple system structure, which is composed of an input transformer, a power cell, a current sensor, etc. However, the challenging points of the SBCI are larger voltage ripple in the dc-link capacitor and imbalance of dc-link voltages of each phase. The asymmetric dc-link voltage of each power cells could cause unstable operation such as over-modulation due to the lack of the dc-link voltage of a particular phase and result in over-voltage or under-voltage faults. In this paper, the control strategy of the dc-link voltage for the SBCI that uses the negative-sequence voltage of the converter is described. The proposed control method is verified with a computer simulation whose target is a 6.6-kV–1.25-MW medium-voltage drive system. Also, through the experimental setup with the prototype SBCI whose power rating is 16.2 kVA, the dc-link voltage of each AFE has been controlled within a 0.5% error of its reference value at the full load. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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- View/download PDF
6. A 1-MHz Series Resonant DC–DC Converter With a Dual-Mode Rectifier for PV Microinverters.
- Author
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Shen, Yanfeng, Wang, Huai, Shen, Zhan, Yang, Yongheng, and Blaabjerg, Frede
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DC-to-DC converters , *CASCADE converters , *ELECTRIC current rectifiers , *ZERO current switching , *VOLTAGE control , *ZERO voltage switching , *ELECTRIC potential , *PHASE modulation - Abstract
The photovoltaic (PV) output voltage varies over a wide range depending on operating conditions. Thus, the PV-connected converters should be capable of handling a wide input voltage range while maintaining high efficiencies. This paper proposes a new series resonant dc–dc converter for PV microinverter applications. Compared with the conventional series resonant converter, a dual-mode rectifier is configured on the secondary side, which enables a twofold voltage gain range for the proposed converter with a fixed-frequency phase-shift modulation scheme. The zero-voltage switching turn-on and zero-current switching turn-off can be achieved for active switches and diodes, thereby, minimizing the switching losses. Moreover, a variable dc-link voltage control scheme is introduced to the proposed converter, leading to a further efficiency improvement and input-voltage-range extension. The operation principle and essential characteristics (e.g., voltage gain, soft-switching, and root-mean-square current) of the proposed converter are detailed in this paper, and the power loss modeling and design optimization of components are also presented. A 1-MHz 250-W converter prototype with an input voltage range of 17–43 V is built and tested to verify the feasibility of the proposed converter. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
7. Sensorless BLDC Motor Commutation Point Detection and Phase Deviation Correction Method.
- Author
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Zhou, Xinxiu, Zhou, Yongping, Peng, Cong, Zeng, Fanquan, and Song, Xinda
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BRUSHLESS direct current electric motors , *FUZZY neural networks , *ELECTRIC potential , *BRUSHLESS electric motors , *LEARNING ability , *VOLTAGE control - Abstract
Phase-to-neutral voltage or neutral-to-virtual neutral voltage zero-crossing points (ZCPs) detection method is usually used for sensorless brushless dc motor commutation control. Unfortunately, neither of them can be realized in lower speed range. In this paper, a simple commutation point detection method is proposed based on detecting inactive phase terminal to dc-link midpoint voltage. It eliminates the requirement of neutral wire or virtual neutral voltage and provides an amplified version of back electromotive force at the ZCPs which makes the lower speed range detection possible. As the speed increases, commutation point error is enlarged due to the low-pass filter. Utilizing the symmetry of the terminal to midpoint voltage, the phase error can be corrected. However, due to the nonlinear relationship between the detected voltage difference and phase error, it is difficult to regulate the error fast and robustly. Therefore, a novel phase regulator based on fuzzy neural network is proposed in this paper with simple structure and learning ability. The validity of the proposed ZCPs detection method and commutation instant shift correction method are verified through experimental results. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
8. On Exploiting Active Redundancy of a Modular Multilevel Converter to Balance Reliability and Operational Flexibility.
- Author
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Kang, Jaesik, Kim, Heejin, Jung, Hong-Ju, Lee, Dong-Su, Kim, Chan-Ki, Mantooth, H. Alan, and Hur, Kyeon
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CONVERTERS (Electronics) , *CURRENT balances (Electric meters) , *FAULT tolerance (Engineering) , *ELECTRIC potential , *SIMULATION methods & models - Abstract
This paper presents a practical strategy for utilizing the submodule (SM) redundancy of a modular multilevel converter (MMC) for its fault tolerance. This strategy provides a systematic framework for balancing the tradeoff between two conventional methods for using the active redundancy and, thus, achieves operational flexibility. One of the existing methods improves SM reliability owing to less voltage stress on the SM components by employing all of the SMs to form the ac or dc voltages (voltage-sharing mode). The other avoids transients by keeping the average SM voltage constant at the cost of slightly increased stress on the SM components (fixed-level mode), which, however, can be controlled to provide the grid-adaptive operation by reserving the energy of the SMs not in service. We, thus, develop a new redundancy management scheme by integrating these two methods and exploiting their technical benefits to meet the PQ requirements and MMC control performance. This research provides a theoretical basis and a technical guide to determining the number of SMs, which can further increase the voltage steps as per the MMC and grid conditions. This paper also connects the remaining PQ capability of the MMC at a particular operating point with the SM redundancy concept by defining a potential redundancy, especially useful when the physical redundancy is exhausted. The theoretical findings and efficacy of the proposed strategy are validated through PSCAD/EMTDC time-domain simulations followed by experiments using a nine-level single-phase MMC system. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
9. A Current-Mode Buck Converter With Reconfigurable On-Chip Compensation and Adaptive Voltage Positioning.
- Author
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Chen, Ching-Jan, Lu, Shao-Hung, Hsiao, Sheng-Fu, Chen, Yung-Jen, and Huang, Jian-Rong
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ELECTRIC potential , *INTEGRATED circuits , *CONVERTERS (Electronics) , *ANALOG-to-digital converters , *ELECTRIC circuits - Abstract
Power management integrated circuits (PMICs) with on-chip compensation are widely used to power multiple loads in mobile devices with increased power density. However, there are two issues for on-chip compensated PMICs. First, on-chip compensation reconfigurability is required to obtain the appropriate response in various passive components. Second, a converter for a processor requires adaptive voltage positioning (AVP) to reduce the output capacitor size. In this paper, a novel reconfigurable on-chip compensated current-mode buck converter with AVP is proposed to solve the aforementioned issues without requiring high-speed and high-resolution analog-to-digital converter (ADC). A reconfigurable accurate load line control scheme and on-chip compensation are proposed to achieve an accurate load line and AVP in various load lines and passive components. The control scheme, small-signal model, and circuit implementation are illustrated in this paper. The proposed buck converter was implemented into an integrated circuit to verify the analysis. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
10. A Fast-Dynamic Unipolar Switching Control Scheme for Single-Phase Inverters in DC Microgrids.
- Author
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Pokharel, Mandip, Hildebrandt, Nicolai, Ho, Carl Ngai Man, and He, Yuanbin
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MICROGRIDS , *SINGLE-phase flow , *ELECTRIC inverters , *ELECTRIC potential , *ELECTRIC currents - Abstract
This paper presents the digital implementation of a boundary controller with unipolar switching characteristic for single-phase voltage source full-bridge inverters. This paper expands the application of a second-order switching surface-based control method to unipolar switching of single-phase voltage source inverters (VSIs) using a finite-state machine. The finite-state machine has been formulated considering four different states of the inverter; positive,zero1, negative, andzero2. The second-order boundary control governs the current state of the system and provides proper switching action to keep the system within the desired reference. The control law is implemented digitally in F28m35x digital control card. A full-bridge inverter topology is used to achieve the three-level voltage switching. Various simulations and experiments were performed in a 550 VA, 120 V, 60 Hz VSI with a digitally implemented controller to verify the theoretical predictions. A high-quality voltage output was obtained for various loading conditions. The transient performance of the controller was investigated using a reference and load changes. A comparison of the implementation was made with the existing classical controllers to verify the fast-dynamic response of the system. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
11. A Comprehensive Optimization Control of Dual-Active-Bridge DC–DC Converters Based on Unified-Phase-Shift and Power-Balancing Scheme.
- Author
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Hou, Nie, Song, Wensheng, Li, Yunwei, Zhu, Yanan, and Zhu, Yutong
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CONVERTERS (Electronics) , *DIRECT currents , *LOAD flow analysis (Electric power systems) , *ELECTRIC potential , *ELECTRIC power systems - Abstract
This paper presents a comprehensive optimization control scheme to improve efficiency and dynamic response of dual-active-bridge (DAB) dc–dc converters. Unified-phase-shift (UPS) control is widely used to increase the efficiency of DAB dc–dc converters by minimizing the peak current, but dynamic performance of the converters needs to be further enhanced. In this paper, to gain superior dynamic performance of DAB dc–dc converters, an equivalent power-balancing (PB) model is employed, which is capable of predicting dynamic behavior of converter output voltages due to input voltage fluctuation and load disturbance. And then, combining the UPS control and the PB control, a comprehensive UPS and PB (UPS-PB) scheme is proposed to improve the efficiency and dynamic performance simultaneously. This work also includes the detailed inductance parameter sensitivity of the proposed UPS-PB scheme and a zonal voltage control strategy to further improve dynamic responses of the output voltage under the start-up process or a large step change of the output voltage reference. Moreover, the variant of UPS-PB scheme for constant power load is analyzed in the experimental part. Finally, experimental results have verified the excellent performance of the proposed UPS-PB scheme and correctness of theoretical analysis in this work. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
12. Input–Output Linearization of a Boost Converter With Mixed Load (Constant Voltage Load and Constant Power Load).
- Author
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Arora, Sameer, Balsara, Poras, and Bhatia, Dinesh
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CONVERTERS (Electronics) , *ELECTRIC potential , *POWER electronics , *ELECTRIC impedance , *IMPEDANCE control - Abstract
Power converters and electric motor drives when tightly regulated behave as constant power loads. These loads are different from resistive loads and have destabilizing negative impedance characteristics, which impact a system's stability. A boost converter is intrinsically nonlinear and is a nonminimum phase system at the output voltage with respect to the control input. The linear approximation of this boost converter loaded with a constant power load has a zero and poles in the right half of the $s$ -plane, making the system unstable and very difficult to control. Control techniques that employ some form of system inversion cannot be implemented for a nonminimum phase system. This paper describes a technique to modify the nonminimum phase boost converter to a minimum phase for a constant power load, further implementing the input–output linearization technique to stabilize the system. This paper also provides a methodological analysis of the problem followed by the proposed solution. Furthermore, it verifies the analysis of the proposed solution through simulation and experimental results. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
13. Active Power Oscillation Cancelation With Peak Current Sharing in Parallel Interfacing Converters Under Unbalanced Voltage.
- Author
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Nejabatkhah, Farzam, Li, Yun Wei, Sun, Kai, and Zhang, Ruixue
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CONVERTERS (Electronics) , *ALTERNATING currents , *DIRECT currents , *ELECTRIC potential , *ELECTRIC currents - Abstract
In a hybrid ac/dc grid, the ac-side unbalance voltage introduces adverse effects on dc grids and interfacing converters (IFC) (active power oscillations, dc-link voltage oscillations, and IFC peak current increase at the same average power production). For parallel IFCs, these adverse effects can be easily aggregated. In this paper, two new control strategies are proposed for parallel IFCs to improve both ac and dc subgrids power quality. The proposed control strategies focus on canceling active power oscillations of parallel IFCs that provide oscillation-free dc link and sharing collective peak current of parallel IFCs. In the first proposed control strategy, IFCs’ power coefficients are controlled by solving a set of nonlinear equations, and this method is called as coefficient-based strategy, whereas, in the second proposed control strategy, peak currents of IFCs are controlled directly through the derived relationship of IFCs' peak currents under zero power oscillation in this paper, and this method is named as peak current based strategy. This peak current based strategy features much simplified calculation and could be easy to implement. To achieve control objectives, thorough study on parallel IFCs' peak currents is conducted. Based on the study, it is shown that the collective peak current of all IFCs is a constant under zero total active power oscillation, and therefore, keeping all IFCs' peak currents in the same phase and in-phase with collective peak current optimizes the utilization range of parallel IFCs. The numerical examples and experimental results are provided to verify the validity of the proposed control strategies under different operating conditions. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
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14. An Alternative IPT Pickup Controller for Material Handling Using a Current Doubler.
- Author
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Beh, Hui Zhi, Neath, Michael, Boys, John T., and Covic, Grant A.
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INDUCTIVE power transmission , *MATERIALS handling , *ELECTRIC controllers , *VOLTAGE doublers , *ELECTRIC potential - Abstract
Inductive power transfer systems deployed in material handling have traditionally used parallel-tuned (current-sourced) boost regulators to independently control and regulate the load on each secondary. This paper evaluates the current doubler as an alternative parallel-tuned secondary controller within this application to better match the current and voltage requirements in the secondary resonant tuning network in high-power applications. This enables designs that enable the secondary magnetic pickup to achieve a smaller profile and fit within typical space constraints of material-handling vehicles. This paper presents the design approach needed for this regulator and compares its operation and performance against a traditional boost controller using both the simulation and the measurement of two built 5-kW secondary regulators. The current doubler naturally achieves a lower output ripple due to its interleaved switching and is found to have a comparable efficiency to the boost controller but requires slightly more components. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
15. Topology and Control of a Split-Capacitor Four-Wire Current Source Inverter With Leakage Current Suppression Capability.
- Author
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Sun, Yao, Liu, Yonglu, Su, Mei, Han, Hua, Li, Xing, and Li, Xin
- Subjects
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STRAY currents , *CAPACITORS , *ELECTRIC potential , *ELECTRIC inverters , *TIME-domain analysis - Abstract
This paper proposes a split-capacitor four-wire current source inverter, which is the dual of the split-capacitor four-wire voltage source inverter. Since the midpoint of the dc link is tied to the neutral point of ac filter capacitors, the common-mode voltage (CMV) is reduced significantly. Consequently, the leakage current issue is effectively addressed. The proposed circuit is cost-effective as no extra switch is added. This paper, first, establishes the equivalent common-mode circuit of the proposed inverter. The impact of the neutral line inductance on CMV is also analyzed. Then, a specific modulation is introduced to balance the dc-link voltages/currents. To achieve good input/output performance, a nonlinear control method is developed based on time-domain models. Finally, all the proposed methods and related theoretical analysis are verified by simulations and experimental results. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
16. A New PV Converter for a High-Leg Delta Transformer Using Cooperative Control of Boost Converters and Inverters.
- Author
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Yamaguchi, Daiki and Fujita, Hideaki
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PHOTOVOLTAIC cells , *CONVERTERS (Electronics) , *ELECTRIC inverters , *PHOTOVOLTAIC power generation , *ELECTRIC current converters - Abstract
This paper proposes a new high-efficiency photovoltaic (PV) converter for grid connection through a high-leg delta transformer. The converter is composed of a symmetrically connected boost converter and three half-bridge inverters. One of the three half-bridge inverters is connected to the boost converter, and the others are directly connected to the PV terminals. As a result, this circuit configuration enables to reduce the power losses in both boost converter and inverters. This paper also proposes a new cooperative control method between the symmetrically connected boost converter and inverter. The control method can reduce the average switching frequency to 75% of that in a conventional one, resulting in a great reduction in the switching power loss. Experimental results confirm that the proposed circuit configuration makes it possible to improve its European efficiency from 91.6% to 94.5%. Moreover, system performance is evaluated on the assumption of maximum power point tracking operation. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
17. A Comparison on Finite-Set Model Predictive Torque Control Schemes for PMSMs.
- Author
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Sandre-Hernandez, Omar, Rangel-Magdaleno, Jose, and Morales-Caporal, Roberto
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TORQUE control , *GATE array circuits , *ELECTRIC potential , *PREDICTIVE control systems , *COST functions - Abstract
This paper introduces the comparison of four predictive torque control schemes for a permanent-magnet synchronous machine (PMSM). The first method is the finite-set model predictive control (FS-MPC). In FS-MPC, the optimal switching state is selected based on the evaluation and minimization of a cost function for all possible voltage space vectors (VSVs) of the inverter. The second method performs a simplified FS-MPC where the selection and evaluation of the possible VSVs are reduced to only three. The third method is based on the principle of predictive direct torque control (PDTC), where the duty cycle of the switching state is optimized for application in the inverter. Finally, a method that combines FS-MPC and PDTC named model predictive torque control is presented. This paper introduces the methodology and the results of a comprehensive comparison of the four predictive schemes based on different criterions. The control schemes are implemented on a field-programmable gate array and are applied to a PMSM. Experimental results are presented to validate the presented comparison and discussion. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
18. Dynamic Control and Performance of a Dual-Active-Bridge DC–DC Converter.
- Author
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Takagi, Kazuto and Fujita, Hideaki
- Subjects
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CASCADE converters , *DIRECT currents , *PHASE-shifting interferometry , *PHASE shifters , *MAGNETIC flux , *ELECTRIC potential , *CONTINUOUS functions - Abstract
This paper discusses dynamic behavior of a dual-active-bridge (DAB) dc–dc converter. Conventional phase-shift control methods for the DAB converter may cause dc offsets in both inductor current and transformer magnetizing current in transient states. The dc offset in the inductor current would introduce an excessive peak current through the switching devices. The dc offset in the magnetizing current may induce magnetic-flux saturation. Conventional methods simultaneously turn on and off the diagonal switches in each H-bridge converter and produce a square-wave voltage with a 50% duty ratio. In contrast, the proposed method in this paper independently controls each switch to modify the duty ratio in transient states. This paper clearly derives the requirements of each switch to eliminate the dc offsets in both currents with a settling time shorter than half the switching period. Experimental results using a 5-kW 20-kHz system verify the validity of the proposed control method, which is effective not only in a single step change, but also in a continuous change in the phase-shift reference. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
19. Instantaneous Phase Voltage Sensing in PWM Voltage-Source Inverters.
- Author
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Schubert, Michael and De Doncker, Rik W.
- Subjects
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PULSE width modulation transformers , *ELECTROMECHANICAL devices , *ROTORS , *ELECTRIC potential , *POWER electronics , *ELECTRIC filters - Abstract
The output voltage of power electronic converters is a very important quantity for dynamic control of power electronic systems. In electrical drives without electromechanical position or speed sensor, the terminal reference voltage is used to obtain the rotor position. Dead-time effects and semiconductor voltage drop lead to distortion in the actual output voltage and degrade the control performance when the back electromotive force magnitude is low. Thus, for stable low-speed operation, output voltage sensing becomes necessary. Due to the switching nature of power electronic systems, this is not a trivial task, especially when instantaneous measurement of the terminal voltage is required. In this paper, an instantaneous switching-period average voltage sensing technique is proposed that utilizes a combined approach of oversampling and filtering. Based on the theoretical analysis of the sampling- and filter-induced measurement distortion, a general solution for an optimal filter design is derived. The additional sensing circuit is integrated into the low-side gate driver of the converter outputs. This paper includes details about the hardware implementation and extensive verification measurements. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
20. A Universal Multiple-Vector-Based Model Predictive Control of Induction Motor Drives.
- Author
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Zhang, Yongchang, Bai, Yuning, and Yang, Haitao
- Subjects
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INDUCTION motors , *PREDICTIVE control systems , *ELECTRIC potential , *SIMULATION methods & models , *MOTOR drives (Electric motors) - Abstract
Conventional finite control set-model predictive control (FCS-MPC) applies single voltage vector within each control period. This leads to relatively high steady-state ripples and requires fast sampling rate. Additionally, enumeration-based optimal vector selection is computationally intensive. Recently, double-vector-based schemes have been proposed to improve the steady-state performance of FCS-MPC. However, they are usually complicated in vector selection and duty ratio calculation. In this paper, a universal multiple-vector-based MPC (UMV-MPC) is proposed, which achieves the same performance as the state-of-the-art double-vector-based MPC, but executes in a much more efficient and universal way. Unlike conventional FCS-MPC, enumerating process and state predictions for candidate voltage vectors are not required in the proposed UMV-MPC to select the best voltage vectors. In UMV-MPC, the optimal vectors and duty ratios are directly constructed from deadbeat control (DBC) based on space vector modulation (SVM), which is easy to follow and quick to use. The proposed UMV-MPC is not only more efficient than prior methods, but also reveals the inherent relationship between double-vector-based MPC and DBC with SVM. A comparative study of UMV-MPC and prior double-vector-based MPC is carried out in this paper. The theoretical analysis as well as simulation and experimental tests on a 2.2-kW induction motor drive are demonstrated to validate the effectiveness of the proposed UMV-MPC. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
21. Interconnected Autonomous ac Microgrids via Back-to-Back Converters—Part II: Stability Analysis.
- Author
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Naderi, Mobin, Khayat, Yousef, Shafiee, Qobad, Dragicevic, Tomislav, Bevrani, Hassan, and Blaabjerg, Frede
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MICROGRIDS , *IDEAL sources (Electric circuits) , *SENSITIVITY analysis , *VOLTAGE control , *ELECTRIC potential - Abstract
In this article, the stability of voltage source converter-based autonomous ac microgrids (MGs), which are interconnected through back-to-back converters (BTBCs), is analyzed. The small-signal stability analysis is based on a detailed, comprehensive and generalized small-signal modeling of the ac interconnected MGs (IMGs), which is possible for any number of MGs and interconnections. The large-signal stability of the IMGs is investigated for the case of the initial BTBC dc voltage as a part of paper contribution. A new margin/criterion is determined for the initial dc voltage in different situations of the BTBC operation. According to the proposed criterion, a fundamental difference between very weak MGs and conventional strong grids in the BTBC voltage stability is addressed. Using eigenvalue analysis and participation matrix, the main participating state variables and corresponding parameters in the dominant critical modes are recognized for an equilibrium point. Sensitivity analysis involves changing initial values of the state variables, parameters, and forcing functions to study their different values and find acceptable ranges of the parameters. Particularly, the considerable contribution of the BTBC in the critical modes is found out by analyzing the initial dc voltage, dc voltage controller and PLLs. In order to observe possible unstable situations and verify the transient studies, real-time simulations are provided for two and three MGs interconnected through BTBCs using OPAL-RT digital simulator. The IMGs can be robustly stable only by specifying the stabilizing ranges of the sensitive parameters to the critical modes and selecting their appropriate values. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
22. Optimized Design of a High Input-Voltage-Ripple-Rejection Converter for LED Lighting.
- Author
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Arias, Manuel, Castro, Ignacio, Lamar, Diego G., Vazquez, Aitor, and Sebastian, Javier
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CONVERTERS (Electronics) , *LED lighting , *BANDWIDTHS , *AC DC transformers , *BRIDGE circuits , *ELECTRIC potential - Abstract
The asymmetrical half-bridge (AHB) converter has been deeply analyzed as second stage in ac–dc light emitting diode (LED) drivers. Galvanic isolation, high reliability and high efficiency are their main advantages while a limited duty cycle range (i.e., 0–0.5) and a poor dynamic behavior are their main disadvantages. As second stage of an LED driver, the most demanding requirement for its control loop is cancelling the low-frequency ripple introduced by the first stage. According to its limited maximum attainable bandwidth, this is normally achieved by implementing a feedforward loop. Nonetheless, the static gain of the standard AHB converter presents a nonlinear relation between the output voltage and the duty cycle. As a consequence, the effectiveness of this feedforward loop is limited. In this paper, the use of the zeta AHB converter as second stage of an LED driver is analyzed and an optimized design is proposed. Regarding its advantages, it presents an extended duty cycle range (theoretically, 0–1.0). Besides, it presents a linear relation between the output voltage and the duty cycle. Therefore, although its dynamic behavior is still limited, it can perfectly cancel the low-frequency ripple introduced by the first stage of the LED driver by means of a straightforward feedforward loop. The optimized design proposed in this paper is focused on minimizing the losses in the magnetic components (transformer and inductor) by wisely choosing the value of the two turns ratios of the transformer. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
23. Isolated Boost DC–DC Converter With Three Switches.
- Author
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Nguyen, Minh-Khai, Duong, Truong-Duy, Lim, Young-Cheol, and Kim, Yong-Jae
- Subjects
- *
DC-to-DC converters , *SWITCHING circuits , *ELECTRIC waves , *ELECTRIC potential , *SNUBBERS (Electrical engineering) - Abstract
This paper documents a new three-switch, isolated boost dc–dc converter. The major features of the proposed converter are as follows: 1) continuous input current; 2) reduced one active switch, one additional diode, and one additional capacitor; 3) unchanged primary and secondary voltage waveforms of the transformer when the duty cycle is changed; and 4) removal of the snubber circuit. This paper presents the operating principles, analysis, parameter design guidelines, and simulation results for the proposed converter. To verify the performance of the proposed converter, a 400 W prototype was constructed with a 40–60 V dc input. A PID controller was used to maintain the dc output voltage at 400 V. The simulation and experimental results matched those of the theoretical analysis. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
24. Sensor-Less Current Sharing Over Wide Operating Range for Extended-Duty-Ratio Boost Converter.
- Author
-
Roy, Jinia and Ayyanar, Raja
- Subjects
- *
ELECTRIC currents , *CASCADE converters , *ELECTRIC potential , *ELECTRIC properties of gallium nitride , *CAPACITORS - Abstract
An extended-duty-ratio (EDR) boost converter is studied extensively in this paper for high voltage gain applications with a wide input (and/or output) voltage range. The EDR is a unique combination of an interleaved, multiphase boost converter and switched capacitor configuration that achieves high voltage gain with significantly lower switch voltage stress and switching losses compared to conventional high-gain solutions. Most of the switches in the multiphase EDR experience only a fixed fraction of the output voltage ($1/M, 2/M$ , etc., where $M$ is the number of phases). Through extensive analysis over a wide operating range, it is shown here that the EDR boost converter has inherent current sharing among the phases only in a limited range of duty ratio— $(M-1)/M \leq D \leq 1$. As the duty ratio reduces beyond this range as required in wide input voltage applications, inherent current sharing property is lost. In this paper, techniques to ensure current sharing under all operating zones without requiring current sensors are presented. Instead of having equal duty ratio for each phase, it is adjusted for each phase according to the operating region of the converter. Extensive analysis is presented to derive the required duty ratio changes for the different phases. The proposed concept is validated with experimental results from a 250 W, 3-phase EDR boost, and GaN-based hardware prototype. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
25. A Single-Stage Two-Switch PFC Rectifier With Wide Output Voltage Range and Automatic AC Ripple Power Decoupling.
- Author
-
Li, Sinan, Qi, Wenlong, Tan, Siew-Chong, and Hui, S. Y. Ron
- Subjects
- *
ELECTRIC current rectifiers , *ELECTRIC power factor , *ELECTROLYTIC capacitors , *ELECTRIC potential , *ALTERNATING currents - Abstract
Conventional single-phase power-factor-correction (PFC) rectifiers with active power decoupling capability typically require more than three active switches in their circuits. By exploring the concept of power-buffer cell, a new single-stage PFC rectifier with two active switches, one inductor and one small power-buffering capacitor is reported in this paper. The proposed converter can achieve high-power factor, wide output voltage range, and power decoupling function without using electrolytic capacitor. Additionally, an automatic power decoupling control scheme that is simple and easy to implement is proposed in this paper. The operating principle, control method, and design considerations of the proposed rectifier are also provided. A 100-W prototype with ac input voltage of 110 Vrms and a regulated dc output voltage ranging from 30 to 100 V has been successfully designed and practically tested. The experimental results show that with only a 15 μF power-buffering film capacitor, the proposed converter can achieve an input power factor of over 0.98, peak efficiency of 93.9%, and output voltage ripple of less than 3%, at 100-W output power. [ABSTRACT FROM PUBLISHER]
- Published
- 2017
- Full Text
- View/download PDF
26. Tan-Sun Coordinate Transformation System Theory and Applications for Three-Phase Unbalanced Power Systems.
- Author
-
Tan, Guangjun, Cheng, Jie, and Sun, Xiaofeng
- Subjects
- *
THREE-phase alternating currents , *COORDINATE transformations , *HARMONIC analyzers , *ELECTRIC potential , *CONVERTERS (Electronics) - Abstract
This paper proposes a new-type Tan-Sun coordinate transformation system, which is an extended version of Clarke coordinate transformation system. The main purpose of the proposed coordinate transformation system is to convert three-phase unbalanced alternating-current quantities into two orthogonal alternating-current quantities with equal amplitudes, and further into two direct-current quantities without second harmonic components through Park transformation method. By applying Tan-Sun coordinate transformation system to three-phase unbalanced converters, we can realize the direct-current decoupling of the three-phase unbalanced currents in the direct-quadrature synchronous rotating coordinate system, so the control methods developed for three-phase converters under balanced voltage conditions can be migrated into those under unbalanced voltage conditions directly. Three-phase unbalanced phase-locked loop technique and active and reactive power definition and calculation for three-phase unbalanced power systems based on Tan-Sun coordinate transformation system are also proposed in this paper. The comparison between Tan-Sun coordinate transformation system and the traditional coordinate transformation system under unbalanced voltage conditions both from the aspects of theory analysis and simulation and experimental verification is provided, and these results indicate the superiority of Tan-Sun coordinate transformation system. [ABSTRACT FROM PUBLISHER]
- Published
- 2017
- Full Text
- View/download PDF
27. Active Output-Voltage-Sharing Control Scheme for Input Series Output Series Connected DC?DC Converters Based on a Master Slave Structure.
- Author
-
Qu, Lu, Zhang, Donglai, and Bao, Zhiyun
- Subjects
- *
DC-to-DC converters , *ELECTRIC current converters , *ELECTRIC potential , *ROTARY converters , *ELECTRIC controllers - Abstract
DC/DC converters connected in series or parallel allow low power devices to be used in high power conversions. The input series output series (ISOS) connection is suitable for situations where both the input and output sides are high voltage fields. To ensure that each module shares voltage with the other, this paper proposes an active output voltage sharing (AOVS) control scheme. The scheme introduces sharing control in the output side so that the isolation is not needed between the input and output sides in the control loop. The AOVS control scheme, consisting of a common output voltage loop and individual output voltage sharing loop, has a master–slave structure. To improve the reliability and realize a hot-plug, this paper also provides an automatic master–slave form of the AVOS control scheme. A simulation of the frequency and time domains is used to verify the accuracy of the small signal model, and an ISOS-connected prototype consisting of three forward converters is made to test the steady and dynamic characteristics of the proposed scheme. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
28. Unified Wide-Speed Sensorless Scheme Using Nonlinear Optimization for IPMSM Drives.
- Author
-
Sun, Yingguang, Preindl, Matthias, Sirouspour, Shahin, and Emadi, Ali
- Subjects
- *
PERMANENT magnet motors , *SYNCHRONOUS electric motors , *ELECTRIC power distribution grids , *POWER distribution networks , *ELECTRIC potential - Abstract
This paper proposes a novel unified nonlinear optimization-based speed and position estimation algorithm for interior permanent magnet synchronous motor drives at wide speed range operations. A cost function based on the voltage equations in the stationary reference frame is employed for speed and position estimation. The speed and position can be estimated by minimizing the cost function. At low speed, including the standstill condition, the cost function is modified and high-frequency sinusoidal voltage signals are injected in the estimated magnetic axis. A phase locked loop is combined with the proposed position estimator for reducing the noise of estimation results. Compared with existing sensorless methods, a unified estimator is used at low- and high-speed operations and a better performance is obtained in transient and steady-state conditions. The convexity of the cost functions with respect to the speed and position estimation errors is analyzed in the paper. The feasibility of the proposed estimation algorithm is validated with an experimental test bench. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
29. Load and Source Battery Simulator Based on Z-Source Rectifier.
- Author
-
Choi, Seong-Chon, Lee, Jung-Hyo, Noh, Yong-Su, Kim, Do-Yun, Kim, Bum-Jun, and Won, Chung-Yuen
- Subjects
- *
ELECTRIC current rectifiers , *LITHIUM-ion batteries , *CLOSED loop systems , *VOLTAGE control , *ELECTRIC potential - Abstract
This paper proposes a battery simulator (BS) based on a Z-source rectifier (ZSR), with the intention of emulating the discharge or charge characteristic of an actual lithium-polymer battery with high voltage and large capacity. The proposed BS is used for power testing for battery applications. The battery model, combined with a Shepherd model and a Thevenin model, is adopted to freely change the properties and specifications of the battery and to replicate the dynamic behavior of the battery, which is discretized to utilize the digital controller of the BS. The closed-loop voltage controller at the dc side of the ZSR is designed to emulate the rapid dynamic characteristics of the battery based on small-signal methods, considering the influence of the components of the impedance network. In this paper, battery voltage control algorithm (BVCA) is also utilized to minimize the voltage stress across switches while controlling two dc-side voltages within a wide range of output voltages. Simulation and experimental results are provided to verify the BS of the new feature and the proposed control method. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
30. Low-Voltage-Ride-Through (LVRT) Control of an HVDC Transmission System Using Two Modular Multilevel DSCC Converters.
- Author
-
Oguma, Kota and Akagi, Hirofumi
- Subjects
- *
HIGH-voltage direct current transmission , *LOW voltage systems , *ELECTRIC potential , *ELECTRIC cables , *DIRECT currents - Abstract
This paper presents an intensive discussion on a high-voltage direct-current (HVDC) long-distance transmission system combining two modular multilevel double-star chopper-cells (DSCC) converters with dc power cables. Hereinafter, each converter is referred to simply as a DSCC converter, or just as a DSCC for more simplicity. Such an HVDC transmission system is required to provide low-voltage-ride-through (LVRT) capability to enhance system availability. This paper proposes a practical LVRT control characterized by the use of power-line communications between the two DSCC converters. The validity and effectiveness of the LVRT control is verified not only by simulated waveforms obtained from the software package “PSCAD/EMTDC” but also by experimental waveforms from a three-phase 200-V, 400-Vdc, 10-kW, 50-Hz downscaled system with 300-m-long dc power cables. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
31. Arm Current Balancing Control for Modular Multilevel Converters Under Unbalanced Grid Conditions.
- Author
-
Wang, Jinyu, Tang, Yi, and Liu, Xiong
- Subjects
- *
TEMPERATURE distribution , *ARM , *VOLTAGE control , *ELECTRIC potential , *DIRECT currents - Abstract
Symmetrical ac-side current control is widely used for grid-connected modular multilevel converters (MMCs) under grid fault conditions. However, it is revealed that this control method can lead to unbalanced arm currents and consequently asymmetrical electrical stresses and nonuniform temperature distributions. This paper aims to analyze the mechanism of the unbalanced arm currents and propose an effective method to solve this problem. First, the electrical quantities inside MMCs are analyzed under unbalanced grid fault conditions. The analytical expressions of the unbalanced arm currents are derived considering different fault severities and operating conditions to reveal the “side-effects” of the symmetrical ac-side current control. After that, a zero-sequence ac voltage injection method is proposed. The injected voltage is directly derived from negative-sequence ac current controller and ac-side current with pure mathematical manipulations, which can be easily obtained without extra controllers. The effect of the injected voltage on the original modulation index is very limited according to an accurate quantitative analyzation. Moreover, the proposed method does not affect the already achieved symmetrical ac-side current control and the circulating current suppression. The effectiveness and performance of the proposed analysis and control method are verified by both simulation and experimental results. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
32. Control and Experiment of a TLC-MMC Hybrid DC–DC Converter for the Interconnection of MVDC and HVDC Grids.
- Author
-
Cui, Shenghui, Hu, Jingxin, and De Doncker, Rik W.
- Subjects
- *
CURRENT transformers (Instrument transformer) , *DIRECT currents , *DC-to-DC converters , *VOLTAGE control , *CASCADE converters , *ELECTRIC potential measurement , *ELECTRIC potential , *SEMICONDUCTOR devices - Abstract
An isolated bidirectional dc–dc converter, which combines parallel-connected two-level converters (TLCs) on the medium-voltage side and a modular multilevel converter (MMC) on the high-voltage side, namely a TLC-MMC converter, is a promising candidate for the interconnection of medium-voltage direct current (MVDC) and HVdc grids. Different from typical phase-shift controlled isolated bidirectional dc–dc converters, transformer currents of a TLC-MMC converter are regulated by the MMC in a closed-loop manner in order to achieve extremely low switching losses and low total device rating of power-semiconductor devices in TLCs. This paper addresses the dedicated operation technique and the voltage-balancing control of the TLC-MMC converter. The MMC in the TLC-MMC converter operates with six-step phase voltages and sinusoidal phase currents. Such an operation makes the MMC present remarkable differences to ac–dc applications. The direct-modulation technique, which is the most-used technique performed to MMCs in line-frequency ac–dc power conversion, has been concluded not applicable to the MMC in a TLC-MMC converter due to the significant sixth-order oscillation resulted in the dc-link voltage. Thus, the indirect-modulation technique is employed, and consequently a closed-loop voltage-balancing control is mandatory for the MMC. Possible measures for voltage balancing have been explored, and effective voltage-balancing control with a simplified implementation is proposed. Validity and effectiveness of the proposed control strategy have been verified by both simulations and experiment using a downscale prototype. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
33. Ripple Voltage Injection to Mitigate Limit Cycle in Digitally Controlled Intermediate Bus Architectures.
- Author
-
Roy, Rabisankar, Kumar, V. Inder, and Kapat, Santanu
- Subjects
- *
LIMIT cycles , *ELECTRIC potential , *ARCHITECTURE , *BUSES , *ELECTRIC motor buses - Abstract
This paper proposes a ripple injection method in a two-stage intermediate bus architecture to overcome the incremental negative-impedance effect in the intermediate bus converter (IBC) induced by the constant power load, which is essentially a tightly regulated point of load (PoL) converter. The proposed method uses the voltage ripple of the intermediate bus in the feedback path for the closed-loop PoL converter while operating the IBC in open loop. The small-signal model is derived and verified using SIMPLIS simulation. The voltage ripple is shown to carry the inductor current information of the PoL converter. Thus, the proposed scheme is expected to retain the superior line regulation of current mode control for the PoL converter even without sensing the inductor current. Load current feed forward can improve the transient response for the PoL converter. Moreover, the load current information is also used to generate the appropriate duty ratio for the IBC during transient recovery. A simple PI controller is used for the PoL converter, which reduces the design complexity using the proposed control scheme. A hardware prototype is made, and the superior performance using the proposed control scheme is experimentally verified. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
34. High-Efficiency Three-Level DC–DC Converter With Reduced Circulating Current and Rectifier Voltage Stress.
- Author
-
Kim, Keon-Woo, Han, Jung-Kyu, Lee, Byoung-Hee, and Moon, Gun-Woo
- Subjects
- *
ELECTRIC current rectifiers , *ZERO voltage switching , *VOLTAGE control , *ELECTRIC potential - Abstract
This paper proposes a high-efficiency three-level (TL) dc–dc converter with reduced circulating current and rectifier voltage stress by using coupled inductor in the rectifier circuit. Because of decreased circulating current, the conduction loss in the primary circuit is reduced. In addition, since the rectifier diodes with low forward voltage drop can be employed due to the small voltage stress, the conduction loss of rectifier diodes can be reduced. Therefore, the efficiency can be increased due to the reduction of the conduction losses in the primary circuit and rectifier diodes. The characteristics of the proposed converter are analyzed and compared with other TL converters. The validity of the proposed converter is verified by the experimental results of the prototype with 540–600 VDC input and 750 W (48 V/15.625 A) output. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
35. Constrained Modulated Model-Predictive Control of an LC-Filtered Voltage-Source Converter.
- Author
-
Zheng, Changming, Dragicevic, Tomislav, Majmunovic, Branko, and Blaabjerg, Frede
- Subjects
- *
VECTOR spaces , *ANALYTICAL solutions , *COST functions , *VOLTAGE control , *PULSE width modulation transformers , *ELECTRIC potential , *NONLINEAR statistical models , *ELECTRIC network topology - Abstract
This paper proposes a constrained modulated model-predictive control (M $^{2}$ PC) scheme for an LC-filtered voltage-source converter (VSC). To tackle the coupling effects of the state variables in a second-order LC filter, a dual-objective cost function (CF) is used to explicitly track both capacitor voltage and inductor current references, which can achieve an improved voltage quality. To handle the state and control input constraints of VSCs, a constrained M $^{2}$ PC scheme is proposed with an “online post-correction” constraint-handling technique. First, the unconstrained optimal voltage vector (OVV) is derived. It is generated by seeking the minimum analytical solution of the CF offline, simplifying the online implementation. Then, an “online post-correction” strategy is employed by reconsidering the constraints to correct the precalculated OVV online, which guarantees the future states within the allowed range. Finally, the corrected OVV is synthesized by the space vector modulation, resulting in a fixed switching frequency and low harmonics. Compared with the typical constrained model-predictive control, the presented scheme has the advantages of improved steady-state performance, flexible constraint-handling ability, and lower computational cost. Additionally, design procedures for weighting factor selection in the CF are given. Comparative experiments are investigated to verify the presented control strategy. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
36. A Dynamic Priority Factor Loop for Fast Voltage Equalization Applied to High Power Density DC–DC Converter System.
- Author
-
Zhang, Rui, Xu, Honghua, and Wang, Yibo
- Subjects
- *
POWER density , *VOLTAGE control , *ELECTRIC potential , *CASCADE converters , *CAPACITOR switching , *ELECTRIC inductance , *CONVERTERS (Electronics) - Abstract
A fast output voltage equalization control strategy applied to 10-kV/100-kW high power density photovoltaic dc–dc converter system is proposed in this paper. The converter modules in the system have two dynamic priority factor loops for fast response with an inconsistent voltage between modules and a soft start-up circuit to precharge output capacitance for solving inrush current problem in boost circuit. The proposed strategy can realize fast voltage equalization control under inconsistent leakage inductance and parasitic resistance parameters condition between modules compared to the traditional unified duty cycle control strategy. The fast equalization performance is verified by 10-kV/100-kW photovoltaic dc–dc converter system. The converter system adopts an isolated boost full-bridge topology and input parallel output series structure, which meets high conversion ratio and high-power density requirements. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
37. Analysis and Design of LLC Converter Considering Output Voltage Regulation Under No-Load Condition.
- Author
-
Kim, Jong-Woo, Park, Moo-Hyun, Lee, Byoung-Hee, and Lai, Jih-Sheng
- Subjects
- *
ELECTRICAL conductivity transitions , *ELECTRIC potential , *GOVERNMENT regulation , *RESONANT power convertors , *ELECTRIC current converters , *VOLTAGE control , *CASCADE converters - Abstract
In the no-load condition, LLC converter usually fails to regulate its output voltage although it operates at a high switching frequency. Till now, it is hard to obtain the exact relationship between design parameters and the maximum switching frequency for no-load regulation capability. In this paper, a specific criterion for no-load regulation of LLC converter is provided, without using active components or other modulation schemes. By analyzing the macroscopic switching period and microscopic switching transition in the no-load condition, it is shown that not only the peaking resonant current during the switching transition, but also the resonant tank design affect the no-load regulation of the LLC converter, which affects the no-load regulation capability. Furthermore, the relationship among design parameters is analyzed and the design guideline is also provided to achieve no-load regulation at the specified maximum switching frequency. To verify the effectiveness of the proposed design, 400 V input and 50 V/200 W output prototype is built and tested. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
38. An Interleaved Active-Clamp Forward Converter Modified for Reduced Primary Conduction Loss Without Additional Components.
- Author
-
Jeong, Yeonho, Park, Jae-Do, and Moon, Gun-Woo
- Subjects
- *
HIGH voltages , *POWER density , *ELECTRIC transformers , *VOLTAGE control , *ELECTRIC potential , *AC DC transformers - Abstract
This paper proposes an interleaved active-clamp forward (IACF) converter modified for high efficiency without any additional component. To employ high input voltage, the components on one active-clamp forward module are re-arranged from the conventional IACF converter. The proposed converter can significantly reduce the primary conduction loss with large turns-ratio of the transformer due to the higher input voltage of the modified module and the expanded duty ratio at the nominal input voltage. In addition, unlike the existing approaches, the power density is not affected because there is no additional component. Finally, the proposed converter is validated experimentally using a prototype converter with 36–72 Vdc input and 480 W (12 Vdc/40 A) output. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
39. Negative Sequence Voltage Compensating for Unbalanced Standalone Brushless Doubly-Fed Induction Generator.
- Author
-
Xu, Wei, Elbabo Mohammed, Omer Mohammed, Liu, Yi, and Islam, Md. Rabiul
- Subjects
- *
INDUCTION generators , *ALTERNATING current generators , *ELECTRIC potential , *VOLTAGE control , *WIND power - Abstract
During the unbalance operation of a standalone brushless doubly-fed induction generator (BDFIG), the negative sequence component causes significant unbalanced effect on the voltage and current of the power winding (PW). In this paper, a new control strategy is proposed to minimize the voltage unbalance effect of a standalone BDFIG under unbalanced loads. The proposed control strategy consists of two parts. The first part represents the conventional direct voltage control strategy to control the frequency and magnitude of the positive sequence PW voltage. The second part is the proposed strategy to minimize the negative sequence component in the output voltage of PW with a negative sequence compensator in the machine side converter. The dual second-order generalized integrator is used to extract negative-sequence component of the PW voltage. Proportional integral controllers are used to obtain reference of the control winding (CW) current which compensate the negative sequence component of the PW voltage. The proportional-integral-resonant controller is applied to regulate the CW current in positive reference frame. A prototype 30 kVA BDFIG test platform is developed in the laboratory to verify the proposed strategy. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
40. Ultra-Wide Output Voltage Range Power Supply Based on Modular Switched-Converter Principle.
- Author
-
Lu, Yangjun, Wu, Hongfei, Tu, Bo, Li, Mengxi, Xia, Yuzheng, and Xing, Yan
- Subjects
- *
POWER resources , *CASCADE converters , *ELECTRIC potential , *DC-to-DC converters , *BALANCE of power , *VOLTAGE control - Abstract
A systematic method for developing ultra-wide output voltage range power supply based on modular switched-converter principle is proposed in this paper. The basic symmetric switched-converter (SSC) module is composed of two dc–dc modules, two diodes, and one active switch. Multi-stage SSC modules are generated by symmetric cascaded connection method. By controlling the active switches in multi-stage SSC modules, the connections of all the dc–dc modules’ output ports can be changed flexibly among series, parallel, and partial–parallel–partial-series connections. Then segmented regulation can be realized and system output voltage range can be widely extended. Meanwhile, the voltage range of each dc–dc module can be narrowed and the voltage/current stress can be reduced to simplify the design, increase device utilization ratio, and improve overall efficiency. A full-bridge isolated buck–boost converter with a semiactive rectifier, which features soft-switching and wide voltage adjustment range, is adopted as the dc–dc module to realize the proposed system. Input current sharing control strategy is adopted to ensure proper power balancing in all possible operating modes. The stability of the proposed system is also explored. Simulation and experimental results are provided to verify the effectiveness and advantages of the proposed system configuration, the switched-converter principle, and the control strategies. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
41. A Modified Closed-Loop Voltage Model Observer Based on Adaptive Direct Flux Magnitude Estimation in Sensorless Predictive Direct Voltage Control of an Induction Motor.
- Author
-
Aliaskari, Armaghan, Zarei, Bahareh, Davari, S. Alireza, Wang, Fengxiang, and Kennel, Ralph M.
- Subjects
- *
MAGNITUDE estimation , *INDUCTION motors , *VOLTAGE control , *TORQUE control , *FLUX (Energy) , *ELECTRIC potential , *REDUCED-order models - Abstract
Voltage model observer is a simple and economical technique for flux estimation in induction motor sensorless drives. However, it shows poor performance in low-speed regions. Therefore, in most cases, the use of this observer is limited. On the other hand, using a simple but accurate estimator is important when the control method is sophisticated and requires heavy computation. This issue will be important in predictive control more than the other methods because the accuracy of the prediction is dependent on the flux estimation. In this paper, a modified closed-loop technique based on voltage model observer is proposed for flux estimation. The feedback loop is supported by the proposed model reference adaptive system direct flux magnitude estimation technique. The dependence of the feedback loop on the stator resistance is eliminated. Therefore, the drift error will be avoided. This will allow the method to withstand the high stator resistance error even at low speeds. Also, a new Lyapunov-based technique for the stator resistance estimation via reduced-order model is proposed. By using the proposed observer, the predictive direct voltage control technique is used as the control method in order to achieve a control method that requires low computation. The proposed method is validated through the experimental results. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
42. Analysis of the Neutral-Point Voltage Self-Balance Mechanism in the Three-Level Full-Bridge DC−DC Converter by Introduction of Flying Capacitors.
- Author
-
Liu, Peng and Duan, Shanxu
- Subjects
- *
CAPACITORS , *CAPACITOR switching , *ELECTRIC potential , *POWER resources , *VOLTAGE control - Abstract
The three-level full-bridge (TLFB) dc−dc converter has been widely used in high-voltage, high-power applications. In the experimental test, the neutral-point voltage deviation appears; moreover, it has also been found out that if the flying capacitors are introduced, the input capacitor voltages could realize self-balance even if no active balancing solutions are adopted. In the previous publications, the role of flying capacitors is generally considered to extend the range of soft switching; however, the self-balance ability has not been mentioned or investigated in any publications thus far. In order to fill this gap, this paper provides the detailed mode operation analysis of the TLFB converter and reveals the cause of the imbalance. In addition, the mechanism of the self-balance ability provided by the flying capacitors is explained in detail, which gives a deep insight into the converter. At last, the influence factor of the voltage error in steady state has been analyzed, and the specific expression of the voltage error is also derived. The feasibility of the theoretical analysis is verified by the simulation and experimental results. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
43. A Neutral Point Voltage Balancing Scheme With Improved Transient Performance for 5-Level ANPC and TNPC Inverters.
- Author
-
Davis, Teenu Techela and Dey, Anubrata
- Subjects
- *
PULSE width modulation transformers , *ELECTRIC potential , *VOLTAGE control , *CAPACITORS , *ELECTRIC inverters - Abstract
In this paper, a neutral point (NP) voltage balancing scheme suitable for three phase 5-level active NP clamped and T-type NP clamped (TNPC) inverters is discussed. Carrier-based pulsewidth modulation is used for the balancing of dc-link capacitors and floating capacitors (FC) in the inverter. The FC voltages are regulated with the help of redundant switching states of pole voltage levels and the dc-link capacitor voltages are controlled using zero-sequence voltage injection. Though the balancing approaches are different for dc-link capacitors and FCs, they are not decoupled from each other. This is due to the effect of certain redundant switching states used for FC balancing causing NP voltage variation. To address this issue, the redundant state time ratio is estimated online every sample and based on this dynamic time ratio, an optimal relationship between neutral current and zero-sequence voltage is established. It is found that the use of dynamic time ratio helps in achieving better transient performance than that of generally adopted fixed time ratio. Simulation and experimental results prove that the proposed balancing scheme works well under all operating conditions and exhibits fast and stable transient performance. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
44. Online Parameter Adjustment Method for Arm Voltage Estimation of the Modular Multilevel Converter.
- Author
-
Taffese, Abel A., de Jong, Erik, D'Arco, Salvatore, and Tedeschi, Elisabetta
- Subjects
- *
ELECTRIC potential , *VOLTAGE control , *ARM , *ELECTRIC potential measurement , *CLOSED loop systems , *TIME delay systems - Abstract
The method used to calculate insertion indexes plays an important role in determining the overall performance of the modular multilevel converter. Direct voltage control, which is the simplest option, results in a large circulating current ripple because this modulation technique does not account for the arm voltage ripples. This led to the development of compensated modulation techniques that compensate for the arm voltage ripples thereby eliminating the circulating current ripple. There are two variants of compensated modulation—closed loop and open loop. The closed-loop version requires measurement of the arm voltages without distortion and delay, which is difficult to achieve in practice. The open-loop method overcomes this challenge by using estimated arm voltages. However, accurate knowledge of the system parameters is needed for effective removal of the circulating current ripples. This is a limitation because the parameters change with time and operating conditions. This paper presents a modified version of the open-loop method, which includes a scheme for correcting parameter errors online. The method estimates the parameters, arm capacitances, and time delay, by using feedback controllers acting on the circulating current ripples. Mathematical derivation of the method, together with its validation using simulation and experimental tests, is presented in detail. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
45. Capacitor Voltage Balancing and Stabilization for 4-Level Hybrid-Clamped Converter Using Selected Switching States.
- Author
-
Pan, Jianyu, Na, Risha, Yang, Yong, Cai, Haiwei, and Xu, Longya
- Subjects
- *
CAPACITOR switching , *CAPACITORS , *ELECTRIC potential , *VOLTAGE control - Abstract
Without active control, the voltage fluctuations of the dc-link and flying capacitors in a 4-level hybrid-clamped converter (4L-HCC) become excessively large in low-frequency operation. This paper studies the switching state redundancy inherent in a 4L-HCC and proposes a new capacitor voltage balancing and stabilizing method to minimize the dc-link and flying capacitor voltage fluctuations. A straightforward algorithm is developed based on a logic table to select the suitable switching states. Verified by simulation and experimental testing results, the new method and algorithm virtually eliminate all the big voltage fluctuations of capacitors at low and zero frequencies, greatly enhancing the robustness and reliability of a 4L-HCC. The capacitor size can be reduced by more than 80% compared with the conventional method. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
46. An Induction Generator System Based on Instantaneous Torque Impulse Balance Control (ITIBC).
- Author
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Wang, Yu, Gu, Hui, and Hao, Wenjuan
- Subjects
- *
INDUCTION generators , *ELECTROSTATIC induction , *TORQUE control , *VOLTAGE control , *ELECTRIC potential , *SYNCHRONOUS generators , *TORQUE - Abstract
The induction machine, offering the merits of robust machine structure, brushless construction, and good voltage regulation capability, is a good choice used as a generator in the dc power system. For the induction generator, the instantaneous torque control (ITC) can achieve stable regulation of the output voltage and excellent dynamic performance of the electromagnetic torque. However, the proportional-integral controller of the voltage loop in the ITC can hardly guarantee the optimal dynamic performance of the output voltage, that is, during the response to the load sudden change, the output voltage exhibits several adjustments, overshoot, and relatively long recovery time. To solve this problem, an instantaneous torque impulse balance control (ITIBC) method is investigated in this paper. In the dynamic process, a group of optimal switch vectors is obtained to achieve the shortest recovery time and the minimum number of adjustments of the output voltage without overshoot. Thus, the optimal dynamic performance of the voltage can be achieved for the induction generator system. Simulation and experimental results verify the correctness and effectiveness of the ITIBC method. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
47. A Minimum Switch Five-Level Unidirectional Rectifier Without Any Voltage Balancing and Pre-Charging Circuitry.
- Author
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Mukherjee, Debranjan and Kastha, Debaprasad
- Subjects
- *
ELECTRIC current rectifiers , *ELECTRIC potential , *SEMICONDUCTOR devices , *ELECTRICAL conductivity transitions , *SEMICONDUCTOR diodes , *VOLTAGE control , *THRESHOLD voltage - Abstract
This paper proposes a three-phase, five-level, non-regenerative pulsewidth modulated rectifier using only two active switches (minimum required) per phase, which drastically reduces gate driver requirement and hardware complexity. It draws sinusoidal input current at close to unity power factor. All the semiconductor devices are rated at only one fourth of the dc-link voltage, and none of them requires any transient voltage balancing snubber. A total of 8 out of the 14 diodes per phase undergo soft switching transition under all operating conditions, which increases its efficiency. No extra hardware circuitry for balancing the flying capacitors (FCs) or the dc-link mid-point voltage are required, which further reduces hardware complexity and increases the conversion efficiency. The proposed topology does not need any sophisticated startup procedure for charging the FCs either, which solves the problem of semiconductor overvoltage during starting. A 3-kW laboratory prototype is built to experimentally verify the proposed topology. The maximum efficiency obtained from the prototype is 98.7%, and it is always more than 96% for the load range from 15% to its rated. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
48. A Carrier-Based Fault-Tolerant Control Strategy for T-Type Rectifier With Neutral-Point Voltage Oscillations Suppression.
- Author
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Chen, Jie, Zhang, Chenghui, Chen, Alian, Xing, Xiangyang, and Gao, Feng
- Subjects
- *
VOLTAGE control , *VOLTAGE references , *OPEN-circuit voltage , *ELECTRIC potential , *OSCILLATIONS , *ELECTRIC current rectifiers , *REFERENCE values - Abstract
This paper proposes a carrier-based fault-tolerant control strategy for T-type three-level rectifier with neutral-point (NP) voltage oscillations suppression when an open-circuit fault occurs. The proposed fault-tolerant control is demonstrated by dividing fault into two conditions: the faulty condition of outer switches and inner switches. In the case of outer switches open-circuit fault, the requirement to maintain the normal operation with sinusoidal currents is demonstrated. Meanwhile, in order to suppress the NP voltage oscillations, a hybrid NP voltage control strategy, which is implemented by adding a compensation value to the reference voltage, and a dc bias are used. In the case of inner switches open-circuit fault, the fundamental period of the input current is divided into two areas: normal half-cycle and abnormal half-cycle. In the abnormal half-cycle, the reference voltage of the faulty leg is compared with a single carrier. In addition, a compensation value is added to the reference voltage to suppress the NP voltage oscillations. While in the normal half-cycle, the hybrid NP voltage control strategy and the dc bias are applied. The feasibility and performance of the proposed tolerant control are illustrated and verified through the simulation and experimental results. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
49. Near-Unity Power Factor, Voltage Step-Up/Down Conversion Pulse-Width Modulated Switching Rectification for Wireless Power Transfer Receiver.
- Author
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Fan, Philex Ming-Yan and bin Mohd Daut, Mohamad Hazwan
- Subjects
- *
WIRELESS power transmission , *ELECTRIC current rectifiers , *AC DC transformers , *ELECTRIC potential , *VOLTAGE control , *ENERGY transfer , *PULSE width modulation , *THERMOELECTRIC power - Abstract
The pulse-width modulated (PWM) switching rectification that can achieve a high power factor (PF) for increasing the energy transfer efficiency between an LC resonator and a rectifier and voltage step-up and -down conversion is proposed for a wireless power transfer (WPT) receiver. The proposed method can emulate the switching rectifier as a resistive load by using an inductor and integrated phase synchronizers. Additionally, similar to a switched-inductor converter that controls the duty cycle ratio (D), the proposed PWM rectifier can control the output voltage VOUT when the input is a rectified, wirelessly coupled voltage instead of a constant voltage. Thus, unlike a conventional PWM switching rectifier for ac mains, an additional voltage conditioning circuit would not be needed after the proposed rectifier for WPT. The proposed PWM switching rectification is implemented in the AMS 0.18 μm 1.8 V/5 V CMOS process. PF = 1 is measured, indicating the most efficient energy transfer, compared to only 0.55–0.65 in a peak detection rectifier. Additionally, 88.2% of peak power conversion efficiency of the switching rectifier is achieved, and the maximum output power is 80.3 mW at 500 kHz of the WPT frequency. Moreover, the measured voltage conversion ratios ranging between 0.73× and 2× are demonstrated in this paper. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
50. Instantaneous Pulse Power Compensator for High-Density Single-Phase Inverters.
- Author
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Lyu, Xiaofeng, Ren, Na, and Cao, Dong
- Subjects
- *
PULSE width modulation transformers , *VOLTAGE control , *POWER density , *CAPACITORS , *ELECTRIC capacity , *ELECTRIC potential - Abstract
In this paper, instantaneous pulse power compensator (IPPC) method is proposed to achieve power pulsation decoupling function for single-phase inverter applications. A smaller capacitor is placed in series with the traditional dc-link capacitor, and this smaller capacitor voltage is controlled using pulse currents to cancel out the dc-link voltage ripple. Unlike twice-line-frequency power decoupling method, the proposed IPPC method can compensate the pulsating power with all the orders harmonics on the dc-link line, not only the second-order component. Both modeling and simulation results show that IPPC method can achieve nearly zero voltage ripple for the dc-link capacitor since the pulse current is fully compensated. Whereas twice-line-frequency power decoupling method has limit in voltage ripple reduction, especially in small dc-link capacitance conditions. The experimental results based on a full-bridge topology decoupling circuit and a single-phase inverter application show consistent results with simulation results. A 16% reduction of the prototype size, i.e., 16% higher power density with only ∼1% efficiency penalty can be achieved by the proposed IPPC method when compared to the second-order power decoupling method. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
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