The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
Copyrights notice
The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
본 논문에서는 새로운 관점에서 클래스 E 동기식 RF 정류기를 공식화합니다. 핵심은 행렬을 도입하고 DC 항을 RF 행렬로 컨벌루션하는 것입니다. 입력 임피던스의 명시적인 표현은 평면 기하학에서 보여집니다. 우리는 입력 임피던스가 ZVS 작동 하에서 쌍곡선 기하학에서 측지선 호를 나타내는 것을 발견했습니다. 여기서 이론적 RF-DC 변환 효율은 100%입니다. 개발된 이론을 수치적으로(회로 시뮬레이션) 검증하고 실험적으로(6.78MHz, 100W) 검증합니다. 우리는 입력 임피던스가 광범위한 DC 부하 저항에 대해 측지선 아크가 됨을 확인합니다. 제시된 이론은 행렬 기반 공식과 평면기하학 표현을 기반으로 하기 때문에 매우 우아합니다.
Ryoya HONDA
Toyohashi University of Technology
Minoru MIZUTANI
Toyohashi University of Technology
Masaya TAMURA
Toyohashi University of Technology
Takashi OHIRA
Toyohashi University of Technology
The copyright of the original papers published on this site belongs to IEICE. Unauthorized use of the original or translated papers is prohibited. See IEICE Provisions on Copyright for details.
부
Ryoya HONDA, Minoru MIZUTANI, Masaya TAMURA, Takashi OHIRA, "Class-E Synchronous RF Rectifier: Circuit Formulation, Geodesic Trajectory, Time-Domain Simulation, and Prototype Experiment" in IEICE TRANSACTIONS on Electronics,
vol. E106-C, no. 11, pp. 698-706, November 2023, doi: 10.1587/transele.2023MMP0004.
Abstract: This paper formulates a class-E synchronous RF rectifier from a new viewpoint. The key point is to introduce a matrix and convolute the DC terms into RF matrices. The explicit expression of input impedance is demonstrated in plane geometry. We find out their input impedance exhibits a geodesic arc in hyperbolic geometry under ZVS operation, where the theoretical RF-DC conversion efficiency results in 100%. We verify the developed theory both numerically (circuit simulation) and experimentally (6.78MHz, 100W). We confirm that the input impedance becomes a geodesic arc for a wide range of DC load resistance. The presented theory is quite elegant since it is based on a matrix-based formulation and plane-geometrical expression.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/transele.2023MMP0004/_p
부
@ARTICLE{e106-c_11_698,
author={Ryoya HONDA, Minoru MIZUTANI, Masaya TAMURA, Takashi OHIRA, },
journal={IEICE TRANSACTIONS on Electronics},
title={Class-E Synchronous RF Rectifier: Circuit Formulation, Geodesic Trajectory, Time-Domain Simulation, and Prototype Experiment},
year={2023},
volume={E106-C},
number={11},
pages={698-706},
abstract={This paper formulates a class-E synchronous RF rectifier from a new viewpoint. The key point is to introduce a matrix and convolute the DC terms into RF matrices. The explicit expression of input impedance is demonstrated in plane geometry. We find out their input impedance exhibits a geodesic arc in hyperbolic geometry under ZVS operation, where the theoretical RF-DC conversion efficiency results in 100%. We verify the developed theory both numerically (circuit simulation) and experimentally (6.78MHz, 100W). We confirm that the input impedance becomes a geodesic arc for a wide range of DC load resistance. The presented theory is quite elegant since it is based on a matrix-based formulation and plane-geometrical expression.},
keywords={},
doi={10.1587/transele.2023MMP0004},
ISSN={1745-1353},
month={November},}
부
TY - JOUR
TI - Class-E Synchronous RF Rectifier: Circuit Formulation, Geodesic Trajectory, Time-Domain Simulation, and Prototype Experiment
T2 - IEICE TRANSACTIONS on Electronics
SP - 698
EP - 706
AU - Ryoya HONDA
AU - Minoru MIZUTANI
AU - Masaya TAMURA
AU - Takashi OHIRA
PY - 2023
DO - 10.1587/transele.2023MMP0004
JO - IEICE TRANSACTIONS on Electronics
SN - 1745-1353
VL - E106-C
IS - 11
JA - IEICE TRANSACTIONS on Electronics
Y1 - November 2023
AB - This paper formulates a class-E synchronous RF rectifier from a new viewpoint. The key point is to introduce a matrix and convolute the DC terms into RF matrices. The explicit expression of input impedance is demonstrated in plane geometry. We find out their input impedance exhibits a geodesic arc in hyperbolic geometry under ZVS operation, where the theoretical RF-DC conversion efficiency results in 100%. We verify the developed theory both numerically (circuit simulation) and experimentally (6.78MHz, 100W). We confirm that the input impedance becomes a geodesic arc for a wide range of DC load resistance. The presented theory is quite elegant since it is based on a matrix-based formulation and plane-geometrical expression.
ER -