A New Stepwise Adiabatic Charging Circuit with a Smaller Capacitance in a Regenerator than a Load Capacitance

被引:0
|
作者
Nakata, Shunji [1 ]
Makino, Hiroshi [2 ]
Matsuda, Yoshio [3 ]
机构
[1] Kinki Univ, Fac Engn, Higashihiroshima, Japan
[2] Osaka Inst Technol, Fac Informat Sci & Technol, Osaka, Japan
[3] Kanazawa Univ, Coll Sci & Engn, Kanazawa, Ishikawa, Japan
来源
2014 IEEE 57TH INTERNATIONAL MIDWEST SYMPOSIUM ON CIRCUITS AND SYSTEMS (MWSCAS) | 2014年
关键词
D O I
暂无
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
A stepwise-voltage-generation circuit was devised that is based on a capacitor bank and that dissipates no energy when a stepwise voltage is generated. The stepwise voltage is generated spontaneously, and depends neither on the initial voltages to the capacitors nor on the switching order. A new adiabatic-charging circuit based on this circuit was also devised that increases the voltage in a stepwise fashion. The total capacitance of the capacitors in the regenerator is much smaller than a load capacitance, which enables construction of a very small adiabatic regenerator. This regenerator cannot be made with a conventional circuit, which uses a tank capacitor that is much larger than a load capacitor for adiabatic charging.
引用
收藏
页码:439 / 442
页数:4
相关论文
共 22 条
  • [1] Development of new capacitance/voltage converting circuit for capacitance tomography
    Zhao, J.C.
    Wang, S.
    Yang, G.
    Lu, Z.X.
    Yi Qi Yi Biao Xue Bao/Chinese Journal of Scientific Instrument, 2001, 22 (01):
  • [2] An adiabatic charging reversible circuit with stepwise voltage control method using a microprocessor
    Nakata, Shunji
    RESULTS IN PHYSICS, 2017, 7 : 2976 - 2978
  • [3] Development of a spark sustained by charging the stray capacitance of the external circuit in atmospheric-pressure nitrogen
    Yu. S. Akishev
    G. I. Aponin
    M. E. Grushin
    V. B. Karal’nik
    A. E. Monich
    M. V. Pan’kin
    N. I. Trushkin
    Plasma Physics Reports, 2007, 33 : 584 - 601
  • [4] Development of a spark sustained by charging the stray capacitance of the external circuit in atmospheric-pressure nitrogen
    Akishev, Yu. S.
    Aponin, G. I.
    Grushin, M. E.
    Karal'nik, V. B.
    Monich, A. E.
    Pan'kin, M. V.
    Trushkin, N. I.
    PLASMA PHYSICS REPORTS, 2007, 33 (07) : 584 - 601
  • [5] Design and Analysis of Self-Tanked Stepwise Charging Circuit for Four-Phase Adiabatic Logic
    Morell, William
    Choi, Jin-Woo
    JOURNAL OF LOW POWER ELECTRONICS AND APPLICATIONS, 2024, 14 (03)
  • [6] A PEEC with a new capacitance model for circuit simulation of interconnects and packaging structures
    Cao, Y
    Li, ZF
    Mao, JF
    Mao, JF
    IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES, 2000, 48 (02) : 281 - 287
  • [7] Low capacitance sensing circuit for fingerprint sensor integrated into display screen based on Charging and Extracting Process
    Yoo, Yena
    Na, Kyungmin
    Jang, Heedon
    Bien, Franklin
    2014 INTERNATIONAL SOC DESIGN CONFERENCE (ISOCC), 2014, : 100 - 101
  • [8] A new design of unsymmetrical shunt circuit with negative capacitance for enhanced vibration control
    Ji, Hongli
    Guo, Yufei
    Qiu, Jinhao
    Wu, Yipeng
    Zhang, Chao
    Tao, Chongcong
    MECHANICAL SYSTEMS AND SIGNAL PROCESSING, 2021, 155 (155)
  • [9] Coils' Current Distortion Due to Variable Series Compensation Capacitance in EV Wireless Charging for a Constant Optimum Load
    Grazian, Francesca
    Shi, Wenli
    Soeiro, Thiago Batista
    Dong, Jianning
    Bauer, Pavol
    2022 WIRELESS POWER WEEK (WPW), 2022, : 54 - 59
  • [10] Electric Vehicle Charging Based on Inductive Power Transfer Employing Variable Compensation Capacitance for Optimum Load Matching
    Grazian, Francesca
    Shi, Wenli
    Soeiro, Thiago Batista
    Dong, Jianning
    Bauer, Pavol
    IECON 2020: THE 46TH ANNUAL CONFERENCE OF THE IEEE INDUSTRIAL ELECTRONICS SOCIETY, 2020, : 5262 - 5267
123