Committee |
Date Time |
Place |
Paper Title / Authors |
Abstract |
Paper # |
EMD |
2024-03-01 14:20 |
Chiba |
|
Break arc characteristics and arc behavior observations of AgSnO2 contacts in an inductive load circuit up to DC20V Reo Oikawa, Yuya Asari, Makoto Hasegawa (Chitose Inst. of Science and Technology) EMD2023-42 |
The authors’ research group has continued a series of observations of break arc behaviors and arc duration measurements ... [more] |
EMD2023-42 pp.19-24 |
WPT |
2023-06-30 15:30 |
Tokyo |
(Primary: On-site, Secondary: Online) |
[Invited Lecture]
Impedance Inversion Wireless Matching Circuit Using Qi Coils Ryoya Honda, Hiroki Ito, Minoru Mizutani (PW) WPT2023-13 |
We report on the matching circuit designed in the matching circuit contest (85 kHz category) held on March 17, 2023. Thi... [more] |
WPT2023-13 pp.13-17 |
WPT |
2023-03-17 12:35 |
Kyoto |
Kyoto-Univ. (Uji campus) (Primary: On-site, Secondary: Online) |
[Poster Presentation]
Impedance inversion wireless matching circuit using Qi coils Ryoya Honda, Hiroki Ito, Minoru Mizutani (PW) WPT2022-47 |
We report on the matching circuit designed in the matching circuit contest (85 kHz category) held on March 17, 2023. Thi... [more] |
WPT2022-47 pp.84-86 |
EMD |
2023-03-03 15:45 |
Saitama |
NIT and Online (Primary: On-site, Secondary: Online) |
Break arc characteristics of AgSnO2 contacts in an inductive load circuit up to DC20V Shota Kosugi, Makoto Hasegawa (Chitose Inst. of Science and Technology) EMD2022-29 |
The authors’ research group has continued a series of observations of break arc behaviors and arc duration measurements ... [more] |
EMD2022-29 pp.46-51 |
VLD, DC, RECONF, ICD, IPSJ-SLDM (Joint) [detail] |
2020-11-17 09:55 |
Online |
Online |
Efficient computation of inductive invariant through flipflop selection Fudong Wang, Masahiro Fujita (U-Tokyo) VLD2020-20 ICD2020-40 DC2020-40 RECONF2020-39 |
As we all know, verification plays more and more important role in VLSI design and manufacture. However, it always takes... [more] |
VLD2020-20 ICD2020-40 DC2020-40 RECONF2020-39 pp.54-59 |
RECONF |
2020-09-11 15:35 |
Online |
Online |
Inductive Invariant Generation Based on Binary Decision Diagram and its Application to Logic Synthesis Liu ZiHao, Miyasaka Yukio, Fujita Masahiro (UT) RECONF2020-28 |
In this paper, we mainly focus on inductive invariant generation using binary decision diagram (BDD), and its applicatio... [more] |
RECONF2020-28 pp.54-59 |
EMD, R |
2020-02-14 14:35 |
Shizuoka |
|
Observations of break arc behaviors of AgSnO2 contacts in a DC inductive load under application of an external magnetic field Makoto Hasegawa, Seika Tokumitsu (Chitose Inst. of Science & Technology) R2019-56 EMD2019-56 |
When AgSnO2 contacts were operated to break an inductive DC load circuit up to 20V-17A with an applied external magnetic... [more] |
R2019-56 EMD2019-56 pp.13-16 |
AP, WPT (Joint) |
2020-01-23 13:10 |
Kagawa |
Sunport Hall Takamatsu |
A study on Series Resonance Circuit for 2x2 MIMO-IPT Yugo Sakamaki, Quang-Thang Duong, Minoru Okada (NAIST) WPT2019-51 |
In an inductive power transfer (IPT) system consisting of one transmitting coil and one receiving coil, series resonant ... [more] |
WPT2019-51 pp.13-17 |
EMD |
2020-01-17 15:35 |
Kanagawa |
Rental hall Shonan Hiratsuka |
Arc movement observation of DC inductive break arcs of AgSnO2 contacts up to 20V-17A under external magnetic field application Makoto Hasegawa, Seika Tokumitsu (Chitose Inst. of Sci.&Tech.) EMD2019-51 |
AgSnO2 contacts were operated to break an inductive DC load circuit of 14V-7A, 14V-12A, 20V-7A, or 20V-17A with an appli... [more] |
EMD2019-51 pp.17-21 |
WPT (2nd) |
2019-10-31 - 2019-11-02 |
Overseas |
Xidian University |
Direct Induced Current Control for Inductive Coupling Wireless Charging System ShaoweiLiu, Kai Xie, Yue Xu, Bicheng Wu, Fan Zhu (Xidian Univ) |
This paper proposes a novel topology structure and control methodology for wireless charging, in which a constant curren... [more] |
|
WPT, AP (Joint) |
2019-01-18 15:00 |
Aichi |
Toyota Automobile Museum |
Performance Evaluation of a Receiver-side Compensation Circuit for IPT Systems Shogo Isogai, Quang-Thang Duong, Minoru Okada (NAIST) WPT2018-63 |
In inductive power transfer systems with transmitter-side resonance, there is a problem that a large current flows in th... [more] |
WPT2018-63 pp.47-50 |
VLD, DC, CPSY, RECONF, CPM, ICD, IE, IPSJ-SLDM, IPSJ-EMB, IPSJ-ARC (Joint) [detail] |
2018-12-05 15:05 |
Hiroshima |
Satellite Campus Hiroshima |
Horizontal Wireless Bus for Free-Form SiP Junichiro Kadomoto, Hidetsugu Irie, Shuichi Sakai (The Univ. of Tokyo) VLD2018-46 DC2018-32 |
We propose a wireless bus interface which connects chips integrated side by side wirelessly. Implementing large coils an... [more] |
VLD2018-46 DC2018-32 pp.43-48 |
EST, MW, OPE, MWP, EMT, IEE-EMT, THz [detail] |
2018-07-19 15:50 |
Hokkaido |
|
Design of Narrowband Band-Pass Filters with Inductive Posts using Metallic Photonic Crystal Waveguide in Quasi-Millimeter-Wave Band Totomasa Satou, Chenglong Xie, Chun-Ping Chen, Zhejun Zhang, Tetsuo Anada (Kanagawa Univ.) EMT2018-31 MW2018-46 OPE2018-34 EST2018-29 MWP2018-30 |
The metallic photonic crystal (MPhC) structure has provided a very attractive platform to design of various filters with... [more] |
EMT2018-31 MW2018-46 OPE2018-34 EST2018-29 MWP2018-30 pp.131-136 |
EE, WPT (Joint) |
2017-10-17 09:55 |
Miyagi |
Tohoku Univ. |
Method of Reducing Leakage Inductance Focusing on Magnetic Coupling of Multi-Port Transformer for Wireless Power Transfer System Keita Furukawa, Keisuke Kusaka, Jun-ichi Itoh (Nagaoka Univ. of Tech.) WPT2017-37 |
This paper shows theoretical analysis of an inductive power transfer system attached canceling coils for reducing leakag... [more] |
WPT2017-37 pp.7-12 |
EMCJ, IEE-EMC, IEE-MAG |
2017-05-18 13:35 |
Overseas |
Nanyang Technological University |
Impact of LISN on EMI Filter Performance Kangrong Li, Kye Yak See (Nanyang Technological University) |
The performance of the electromagnetic interference (EMI) filter is usually evaluated with the presence of the line impe... [more] |
|
EE, WPT (Joint) |
2016-10-06 15:15 |
Kyoto |
|
[Special Talk]
Power Electronics for Wireless Power Transfar Jun-ichi Itoh, Keisuke Kusaka (Nagaoka univ. of Tech.) EE2016-21 WPT2016-27 |
Since 2007, wireless power transfer systems have been actively studied. The circuit configuration of the power converter... [more] |
EE2016-21 WPT2016-27 pp.13-18(EE), pp.43-48(WPT) |
EE, WPT, IEE-SPC (Joint) [detail] |
2015-07-07 13:00 |
Kyoto |
|
A Time-Sharing Principle-based A Time-Sharing Principle-based Frequency Doubler ZCS High Frequency-Resonant Inverter for Inductive Power Transfer
-- The First Report on the Experimental Evaluation -- Kyohei Konishi, Tomokazu Mishima (Kobe Univ.), Mutsuo Nakaoka (Univ. Malaya) EE2015-8 |
This paper presents an evaluation on a time-sharing principle-based frequency doubler zero current soft-switching (ZCS) ... [more] |
EE2015-8 pp.33-38 |
EE, WPT, IEE-SPC (Joint) [detail] |
2015-07-07 14:00 |
Kyoto |
|
A Comprehensive Design Method of Inductively Coupled Wireless PowerTransfer System for Maximizing Overall Efficiency Takumi Noda, Tomoharu Nagashima, Hiroo Sekiya (Chiba Univ.) WPT2015-41 |
For development of inductive coupling wireless power transfer (WPT) systems, it is important to consider a overall effic... [more] |
WPT2015-41 pp.31-36 |
ICD, SDM |
2014-08-05 15:45 |
Hokkaido |
Hokkaido Univ., Multimedia Education Bldg. |
A Low Power , Area Efficient Frequency Calibration Technique with Shared Array Oscillator for Inductive-Coupling Transceiver Naoki Kitazawa, Teruo Jyo, Hiroki Ishikuro (Keio Univ.) SDM2014-81 ICD2014-50 |
This paper presents a low power, small area Frequency Acquisition Circuit (FAC) for a pulse-based inductive coupling tra... [more] |
SDM2014-81 ICD2014-50 pp.105-108 |
MW (Workshop) |
2013-12-02 - 2013-12-04 |
Overseas |
King Mongkut's University of Technology North Bangkok, Thailand |
Design of Wireless Power Transfer Inductive Coil for Rechargeable Battery Implanted Medical Devices Tapakorn Roopngam, Thanaset Thosdeekor​aphat, Chanchai Thongsopa (Suranaree University of Technology) |
The objective of the study was Design inductive coil for rechargeable battery operated Implanted Medical
Devices applic... [more] |
|