• 제목/요약/키워드: output current

검색결과 4,013건 처리시간 0.032초

광범위 출력전압을 위한 고정밀 BiCMOS cascode 전류미러 (A Highly Accurate BiCMOS Cascode Current Mirror for Wide Output Voltage Range)

  • 양병도
    • 대한전자공학회논문지SD
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    • 제45권3호
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    • pp.54-59
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    • 2008
  • 본 논문에서는 광범위 출력전압을 위한 고정밀 BiCMOS cascode 전류미러를 제안하였다. 제안한 전류미러는 베이스 전류에러를 보상하는 BJT 전류미러를 기본으로 하고 있다. NMOS-NMOS cascode 구조 대신에 npn-NMOS cascode 구조를 사용하여, 출력저항과 출력전압 범위를 증가시켰다. npn 전류 복사 트랜지스터는 입력전류를 출력전류로 복사하고, NMOS 트랜지스터는 출력저항을 증가시켜 정밀한 전류 복사를 가능케 한다. 제안한 전류미러는 광범위 출력전압에서 정밀하게 전류를 복사한다. 5V/16V 0.5um BCD 공정을 이용하여 제작한 칩을 측정하여 검증하였고, $0.3V{\sim}16V$의 출력전압 범위에서 전류 에러는 $-2.5%{\sim}1.0%$이다.

단상 AC/DC 컨버터의 병렬 운전을 위한 출력 전류와 계통 전류를 이용한 DC 드룹 제어 (A DC droop control using an output current and a grid current for operating parallel-connected single-phase AC/DC converter)

  • 김정민;김범준;이강주;금호중;원충연
    • 전력전자학회:학술대회논문집
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    • 전력전자학회 2017년도 추계학술대회
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    • pp.51-52
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    • 2017
  • This paper presents an advanced DC droop using both an output current and a grid current. To control parallel-connected converters without communication, the DC droop control is conventionally used. The conventional DC droop control method droops output voltage using an output current. It cannot control the source current causing output voltage errors. This paper proposed the DC droop method using both an output current and a grid current to improve dynamic response of voltage droops. The simulation results with PSIM is provided.

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Fast-Response Load Regulation of DC-DC Converter By High-Current Clamp

  • Senanayake, Thilak Ananda;Ninomiya, Tamotsu
    • Journal of Power Electronics
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    • 제4권2호
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    • pp.87-95
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    • 2004
  • A new fast-response high-current clamp DC-DC converter circuit design is presented that will meet the requirements and features of the new generation of microprocessors and digital systems. The clamp in the proposed converter amplifies the current in case of severe load changes and is able to produce high slew rate of output current and capability to keep constant the output voltage. This proposed high-current clamp technique is theoretically loss less, low cost and easy to implement with simple control scheme. This is modified from a basic buck topology by replacing the output inductor with two magnetically coupled inductors. Inductors are difference in inductance, one has large inductance and other has small inductance. The inductor with small inductance will take over the output inductor during fast load transient. It speedup the output current slew rate and reduce the output voltage drop in the case of heavy burden load changes.

넓은 범위의 전류 출력을 갖는 고선형 전압-제어 전류원 회로 (High-linearity voltage-controlled current source circuits with wide range current output)

  • 차형우
    • 대한전자공학회:학술대회논문집
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    • 대한전자공학회 2004년도 하계종합학술대회 논문집(2)
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    • pp.395-398
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    • 2004
  • High-linearity voltage-controlled current sources (VCCSs) circuits for wide voltage-controlled oscillator and automatic gun control were proposed. The VCCS consists of emitter follower for voltage input, two common-base amplifier which their emitter connected for current output, and current mirror which connected the two amplifier for large output current. The VCCS used only five transistors and a resistor without an extra bias circuit. Simulation results show that the VCCS has current output range from 0mA to 300mA over the control voltage range from 1V to 4.8V at supply voltage 5V. The linearity error of output current has less than $1.4\%$ over the current range from 0A to 300mA.

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Design of a High-Precision Constant Current AC-DC Converter with Inductance Compensation

  • Chang, Changyuan;Xu, Yang;Bian, Bin;Chen, Yao;Hu, Junjie
    • Journal of Power Electronics
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    • 제16권3호
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    • pp.840-848
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    • 2016
  • A primary-side regulation AC-DC converter operating in the PFM (Pulse Frequency Modulation) mode with a high precision output current is designed, which applies a novel inductance compensation technique to improve the precision of the output current, which reduces the bad impact of the large tolerance of the transformer primary side inductance in the same batch. In this paper, the output current is regulated by the OSC charging current, which is controlled by a CC (constant current) controller. Meanwhile, for different primary inductors, the inductance compensation module adjusts the OSC charging current finely to improve the accuracy of the output current. The operation principle and design of the CC controller and the inductance compensation module are analyzed and illustrated herein. The control chip is implemented based on a TSMC 0.35μm 5V/40V BCD process, and a 12V/1.1A prototype has been built to verify the proposed control method. The deviation of the output current is within ±3% and the variation of the output current is less than 1% when the inductances of the primary windings vary by 10%.

A Novel Control Strategy for Input-Parallel-Output-Series Inverter System

  • Song, Chun-Wei;Zhao, Rong-Xiang;Lin, Wang-Qing;Zeng, Zheng
    • Journal of international Conference on Electrical Machines and Systems
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    • 제1권2호
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    • pp.85-90
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    • 2012
  • This paper presents a topology structure and control method for an input-parallel-output-series(IPOS) inverter system which is suitable for high input current, high output voltage, and high power applications. In order to ensure the normal operation of the IPOS inverter system, the control method should achieve input current sharing(ICS) and output voltage sharing(OVS) among constituent modules. Through the analysis in this paper, ICS is automatically achieved as long as OVS is controlled. The IPOS inverter system is controlled by a three-loop control system which is composed of an outer common-output voltage loop, inner current loops and voltage sharing loops. Simulation results show that this control strategy can achieve low total harmonic distortion(THD) in the system output voltage, fast dynamic response, and good output voltage sharing performance.

Analysis of the Output Ripple of the DC-DC Boost Charger for Li-Ion Batteries

  • Nguyen, Van-Sang;Tran, Van-Long;Choi, Woojin;Kim, Dae-Wook
    • Journal of Power Electronics
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    • 제14권1호
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    • pp.135-142
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    • 2014
  • In the design of battery chargers, limiting the output ripple current according to the manufacturer's recommendation is important for reliable service and extended battery life. Ripple components can cause internal heating of the battery and thus reduce the service life of the battery. Care must be exerted in the design of the switching converter for the charge application through the accurate estimation of the output current ripple value. This study proposes a method to reduce the output current ripple of the converter and presents a detailed analysis of the output current ripple of the DC-DC boost converter to provide a guideline for the design of the battery charger.

The Output Ripple Current of Single-Stage Flyback Converter with High Power Factor in LED Driver

  • Park, In-Ki;Eom, Hyun-Chul
    • 전력전자학회:학술대회논문집
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    • 전력전자학회 2013년도 전력전자학술대회 논문집
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    • pp.347-349
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    • 2013
  • This paper describes analysis and calculation of line frequency ripple current according to output capacitor value and effects of LED connection in the single stage flyback converter with high power factor. The low frequency output ripple current delivered from single stage converter has been analyzed in detail and the method evaluating parasitic resistance included in LED has been provided. In order to verify the equation derived in this paper, the single stage flyback converter has been designed with constant output current regulation with DCM operation. Experiments were conducted with different LED load structures to analyze the effect of LED parasitic resistance on output ripple current. As test results, the calculation can provide guide line to select capacitor values depending on output ripple current and LED characteristics.

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무변압기형 태양광 인버터의 출력 전류 DC offset 제거 방법 (Output Current DC offset Removal Method for Trans-less PV Inverter)

  • 홍기남;최익;최주엽;이상철;이동하
    • 한국태양에너지학회 논문집
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    • 제32권spc3호
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    • pp.255-261
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    • 2012
  • Since PV PCS uses output current sensor for ac output current control, the sensor's sensing value includes unnecessary offset inevitably. If PV inverter is controlled by the included offset value, it's output current will generate DC offset. The DC offset of output current for trans-less PV inverter is fatal to grid, which results in saturating grid side transformer. Usually DSP controller of PV inverter reads several times sensing value during initial operation and, finally, it's average value is used for offset calibration. However, if temperature changes, the offset changes, too. And also, the switch device is not ideal, both each switching element of the voltage drop difference and on & off time delay difference generate DC offset. Thus, to compensate for deadtime and the switch voltage drop, feedback control by output current DC offset should be provided to compensate additional distortion of the output current. The validity of the proposed method is confirmed through PSIM simulation.

무정전 전원장치 효율 향상에 대한 연구 (Efficiency Improvement of Uninterruptible Power Supply Systems)

  • 오홍일;권종원;박용만;오드게럴;김희식
    • 대한전기학회:학술대회논문집
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    • 대한전기학회 2006년도 심포지엄 논문집 정보 및 제어부문
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    • pp.288-290
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    • 2006
  • An efficiency improving method for Uninterruptible Power Supply System(UPS) was developed by using OP-AMP based application circuits such as voltage detection device, current detection device and static switch control device. The efficiency improving algorithm was made by mixing the operating concepts of On-Line type UPS with the operating concepts of Off-Line type UPS. The UPS' inverter does not work if the UPS' output load current is not higher than the low load operating current which is about 0-30(%) of the UPS' output load capacity. The low load operating current is adjustable within the half of the UPS' output load capacity. If the UPS' output load current is rising over than the low load operating current, the UPS' inverter starts working and the inverter output power feeds to the loads of UPS. If UPS' input power breaks out while UPS' inverter does not operate because the load current is low, the inverter starts working within 4(ms) with excessive output voltage which is ${\pm}$8(%) of normal UPS' output voltage. Like these. UPS can continuously feeds power to it's load device and reduce power consumptions.

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