• Title/Summary/Keyword: AC ground

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1.9-GHz CMOS Power Amplifier using Adaptive Biasing Technique at AC Ground

  • Kang, Inseong;Yoo, Jinho;Park, Changkun
    • Journal of information and communication convergence engineering
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    • v.17 no.4
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    • pp.285-289
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    • 2019
  • A 1.9-GHz linear CMOS power amplifier is presented. An adaptive bias circuit (ABC) that utilizes an AC ground to detect the power level of the input signal is proposed to enhance the linearity and efficiency of the power amplifier. The ABC utilizes the second harmonic component as the input to mitigate the distortion of the fundamental signal. The input power level of the ABC was detected at the AC ground located at the VDD node of the power amplifier. The output of the ABC was fed into the inputs of the power stage. The input signal distortion was mitigated by detecting the input power level at the AC ground. The power amplifier was designed using a 180 nm RFCMOS process to evaluate the feasibility of the application of the proposed ABC in the power amplifier. The measured output power and power-added efficiency were improved by 1.7 dB and 2.9%, respectively.

Effects of Ac Mutual Coupling According to Location of Auxiliary Electrodes In Measuring the Ground Impedance of Vertically or Horizontally Buried Ground Electrode (수직 또는 수평으로 매설된 접지전극의 접지임피던스 측정시 보조전극 위치에 따른 전자유도의 영향)

  • Choi, Young-Chul;Choi, Jong-Hyuk;Lee, Bok-Hee;Jeon, Duk-Kyu
    • Journal of the Korean Institute of Illuminating and Electrical Installation Engineers
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    • v.23 no.8
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    • pp.86-92
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    • 2009
  • In order to minimize ac mutual coupling, the auxiliary electrode are located at a right angle in measuring ground impedance. In case that the measurement space is limited, the alternative method is employed. At that time, it is necessary to investigate the measurement errors due to ac mutual coupling and earth mutual resistance in measuring the ground impedances. 'This paper presents the measurement accuracy according to the location of the current and potential auxiliary electrodes in measuring ground impedance of vertically or horizontally buried ground electrode. The measurement errors due to ac mutual coupling were evaluated Consequently, the effect of ac mutual coupling on the measurement accuracy for horizontally buried ground electrode is greater than that for vertically buried ground electrode. Measurement errors due to ac mutual coupling is the largest when the current and potential auxiliary electrodes are located in parallel. The 61.8[%] rule is inappropriate in measuring ground measurement. Theoretically, in case that the angle between the current and potential auxiliary electrodes is 90$[^{\circ}]$, there is no ac mutual coupling. If it is not possible to route the current and potential auxiliary electrodes at a right angle with limitation of measurement space, the location of these electrodes with an obtuse angle is preferred to that with an acute angle in reducing the measurement errors due to ac mutual coupling.

New Single-Phase AC-AC Converters With High-Reliability and Common-Ground Structure (새로운 공통접지 고신뢰성 AC-AC 전력변환기)

  • Kim, Jeonghun;Cha, Honnyong
    • The Transactions of the Korean Institute of Power Electronics
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    • v.26 no.6
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    • pp.446-453
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    • 2021
  • This paper proposes enhanced single-phase pulse width modulation buck, boost, and buck-boost type ac-ac converters. The proposed converters, where input and output voltages share a common ground, require no isolated voltage sensor and have no leakage current problem. The commutation problem is solved with series-connected switching cell structures without using an additional RC snubber. In addition, with the use of the polarity of input voltage, switching patterns are determined so that the inductor currents can flow through switching devices during all operational modes. Two switches are always turned on during a half-period of the input voltage; thus, the switching loss is significantly reduced. Detailed analysis and experimental results are provided to verify the performance of the proposed converter.

PWM AC/DC Converter Using Wireless Voltage Sensor (무선 전압 센서를 이용한 PWM AC/DC 컨버터)

  • Joo, In-One;Kim, Jae-Hoon
    • Proceedings of the KIEE Conference
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    • 2003.10b
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    • pp.206-208
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    • 2003
  • PWM AC/DC 컨버터에서 입력 전원측에서 제어보드까지 거리가 상당히 멀리 떨어져 있는 경우, 입력 전압의 신호케이블은 매우 길고 복잡하게 설치되며 외부 노이즈에 노출되기 쉽다. 본 논문에서는 이러한 문제를 해결하기 위하여 무선 전압 센서를 제안한다. 무선 전압 센서는 전압 센서에서 측정된 신호를 제어보드까지 유선 케이블로 전송하지 않고, 무선 신호로 전송한다. 따라서 입력전원측이 원거리에 있더라도 쉽게 설치할 수 있고 외부 노이즈에 대한 면역성이 강한 PWM AC/DC 컨버터를 제공한다.

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Analysis of error factors of the Fall-of-potential test method in measurements of grounding impedance (전위강하법에 의한 접지임피던스 측정 시 오차요인 분석)

  • Jeon, Byung-Wook;Lee, Su-Bong;Jung, Dong-Cheol;Lee, Bok-Hee;Ahn, Chang-Hwan
    • Proceedings of the Korean Institute of IIIuminating and Electrical Installation Engineers Conference
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    • 2008.05a
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    • pp.313-316
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    • 2008
  • This paper presents the error factors of Fall-of-potential test method used in measurements of the grounding-system impedance. This test methods inherently can introduce two possible errors in the measurements of grounding-system impedance: (1) ground mutual resistance due to current flow through ground from the ground electrode to the current probe, (2) ac mutual coupling between the current test lead and the potential test lead. The errors of ground mutual resistances and ac mutual coupling are expressed by the equation in calculating grounding impedance. These equations were calculated by Matlab that is commercial tool using mathematical calculation. The results of calculation were applied to correct grounding impedance.

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KSLV-I Assembly Complex System Design (KSLV-I 조립콤플렉스 시스템 설계)

  • Jin, Seung Bo;Park, Jung Ju
    • Journal of the Korean Society of Systems Engineering
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    • v.2 no.1
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    • pp.37-41
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    • 2006
  • The KSLV-I satellite launch vehicle will be launched in a space center currently under construction. The Space Center which is an advance post base of space development of Korea is located on Oenaro island in Kohung, South Cholla Province. A Ground Complex of the Space Center consists of an AC(Assembly Complex), a LC(Launch Complex), and a MCC(Mission Control Center). Assembly and test facilities are located in the AC in which stage assembly, integrated assembly, check-up, certification test, and pre-launch test are made effectively. A launch pad, fuel supply facilities, a launch control center and associated supporting facilities are located in the LC, and the MCC has control over the space center. These ground complex facilities have diverse forms of an interface with mechanical device, electric device, and etc. These should also provide optimum condition and performance during launch operation processes of the launch vehicle. This paper introduces the result of R&D for the AC of the ground complex performed during system design period.

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I-V characteristics of ground electrode fabricated using an aluminium scrap (알루미늄 스크랩을 이용하여 제작한 접지 전극의 전압-전류 특성)

  • 이우선;정용호;박진성
    • Electrical & Electronic Materials
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    • v.9 no.8
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    • pp.806-812
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    • 1996
  • I-V characteristics of ground electrode fabricated using an aluminium scrap are presented. We fabricated several shapes of aluminium scraps and aluminium electrodes. The results show that the current of aluminium electrode increased linearly by the voltage increase. AC breakdown voltage of copper plate electrode was higher than that of aluminium electrode. AC breakdown current of aluminium electrode was higher than that of copper plate electrode. As applied voltage increased, grounding resistance of aluminum electrode decreased linearly.

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Analysis on the Characteristics of the Superconducting Electrodynamic Suspension According to the Variation of the Ground Conductor (지상도체 변화에 따른 초전도 반발식 자기부상 특성 해석)

  • Bae, Duck-Kweon;Cho, Han-Wook;Lee, Jong-Min;Han, Hyung-Suk;Lee, Chang-Young;Ko, Tae-Kuk
    • Proceedings of the KIEE Conference
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    • 2009.07a
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    • pp.1159_1160
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    • 2009
  • This paper presents the numerical simulation results on the supercodnucting electrodynamic suspension (EDS) simulator according to the variation of the ground conductor. The levitation force of the EDS system is formed by the reaction between the moving magnet and the fixed ground conductor. The possible way to simulate the EDS system were simulated in this paper by using finite element method (FEM). The static type simulator which consists of the fixed magnet, the fixed ground conductor and the ac current supply system. To verify the characteristics of high speed EDS system with the moving type simulator heavy, large and fast moving ground conductor is needed. The static type simulator can get the characteristics of the high speed EDS system by applying equivalent ac current to velocity, therefore it does not need large moving part. The static type EDS simulator, which can consist of an HTS magnet, the fixed ground conductor(s), an AC power supply and the measuring devices, also test the effect of the shape of the ground conductor easily. The plate type ground conductor made stronger levitation force than ring type ground conductor. Although the outer diameter 335 mm ring type ground conductor (Ring3) was larger than the outer diameter 235 mm ground conductor (Ring2), the levitation force by Ring2 was stronger than that by Ring3. From the calculation results on this paper, the consideration of the magnetic flux distribution according to the levitation height should be included in the process of the ground conductor design.

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Numerical Analysis of Moving Type and Static Type Electrodynamic Suspension Simulator with Superconducting Levitation Magnet (초전도 부상자석을 이용한 동적 및 정지형 반발식 자기부상 시험기의 수치해석)

  • Lee, E.R.;Bae, D.K.;Chung, Y.D.;Yoon, Y.S.;Ko, T.K.
    • Progress in Superconductivity and Cryogenics
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    • v.11 no.1
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    • pp.49-54
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    • 2009
  • This paper presents the numerical simulation results on the moving type electrodynamic suspension (EDS) simulator and static type EDS simulator using high-Tc superconducting (HTS) levitation magnet. The levitation force of the EDS system is formed by the reaction between the moving magnet and the fixed ground conductor. The possible two ways to simulate the EDS system were simulated in this paper by using finite element method (FEM). The first way was the moving type simulator which consists of the fixed HTS magnet and the moving ground conductor. The second way was the static type simulator which consists of the fixed magnet, the fixed ground conductor and the ac current supply system. To verify the characteristics of high speed EDS system with the moving type simulator heavy, large and fast moving ground conductor is needed. The static type simulator can get the characteristics of the high speed EDS system by applying equivalent ac current to velocity, therefore it does not need large moving part. The static type EDS simulator, which can consist of an HTS magnet, the fixed ground conductor(s), an AC power supply and the measuring devices, also test the effect of the shape of the ground conductor easily. The plate type ground conductor made stronger levitation force than ring type ground conductor. Although the outer diameter 335 mm ring type ground conductor (Ring3) was larger than the outer diameter 235 mm ground conductor (Ring2), the levitation force by Ring2 was stronger than that by Ring3. From the calculation results on this paper, the consideration of the magnetic flux distribution according to the levitation height should be included in the process of the ground conductor design.

Ground Potential Distribution Associated with the Buried Depth of Ground Rod (봉형 접지전극의 시설깊이에 따른 대지전위분포)

  • Lee, B.H.;Eom, J.H.;Ahn, C.H.
    • Proceedings of the KIEE Conference
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    • 2000.07c
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    • pp.2068-2070
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    • 2000
  • Ground potential rise is a vital part of personal safety, this paper presents the ground potential rise distribution induced by a ground rod. The experiments were conducted with the AC square wave currents according to the buried depth of ground rod. The ground potential is significantly varied in the vicinity of ground rod and the ground potential distribution is flat and few with increasing the buried depth of ground rod.

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