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This paper presents frequency response compensation technique, and a self-oscillation circuit for capacitive microresonator with the compensation technique using programmable capacitor array, to compensate for the frequency response distorted by paras...
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RISS 인기검색어
용량형 마이크로 공진기의 주파수 응답 보상 기법 = Frequency Response Compensation Technique for Capacitive Microresonator
한글로보기https://www.riss.kr/link?id=A103745380
- 저자
- 발행기관
- 학술지명
- 권호사항
-
발행연도
2012
-
작성언어
Korean
- 주제어
-
등재정보
KCI등재
-
자료형태
학술저널
- 발행기관 URL
-
수록면
235-239(5쪽)
-
KCI 피인용횟수
0
- DOI식별코드
- 제공처
- 소장기관
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
This paper presents frequency response compensation technique, and a self-oscillation circuit for capacitive microresonator with the compensation technique using programmable capacitor array, to compensate for the frequency response distorted by parasitic capacitances, and to obtain stable oscillation condition. The parasitic capacitances between the actuation input port and capacitive output port distort the frequency response of the microresonator. The distorted non-ideal frequency response can be compensated using two programmable capacitor arrays, which are connected between anti-phased actuation input port and capacitive output port. The simulation model includes the whole microresonator system, which consists of mechanical structure, transimpedance amplifier with automatic gain control, actuation driver and compensation circuit. The compensation operation and oscillation output of the system is verified with the simulation results.
This paper presents frequency response compensation technique, and a self-oscillation circuit for capacitive microresonator with the compensation technique using programmable capacitor array, to compensate for the frequency response distorted by parasitic capacitances, and to obtain stable oscillation condition. The parasitic capacitances between the actuation input port and capacitive output port distort the frequency response of the microresonator. The distorted non-ideal frequency response can be compensated using two programmable capacitor arrays, which are connected between anti-phased actuation input port and capacitive output port. The simulation model includes the whole microresonator system, which consists of mechanical structure, transimpedance amplifier with automatic gain control, actuation driver and compensation circuit. The compensation operation and oscillation output of the system is verified with the simulation results.
참고문헌 (Reference)
1 고형호, "정전 용량형 MEMS 공진기의 비이상적 주파수 응답 모델링" 한국센서학회 19 (19): 191-196, 2010
2 M. Abdelsalam, "Supporting circuitry for a fully integrated micro electro mechanical(MEMS)oscillator in 45 nm CMOS technology" 259-263, 2010
3 S. Tabatabaei, "Silicon MEMS oscillators for high-speed digital systems" 30 (30): 80-89, 2010
4 Y. Lin, "Series-resonant VHF micromechanical resonator reference oscillators" 39 (39): 2477-2491, 2004
5 S. Li, "Optimization, simulation, and fabrication of a microgyroscope" 36-42, 2001
6 A. Lee, "Non-ideal behavior of a driving resonator loop in a vibratory capacitive microgyroscope" 39 (39): 1-6, 2008
7 S. Lee, "Influence of automatic level control on micromechanical resonator oscillator phase noise" 341-349, 2003
8 A. Uranga, "Fully CMOS integrated low voltage 100 MHz MEMS resonator" 41 (41): 1327-1328, 2005
9 K. Sundaresan, "Electronically temperature compensated silicon bulk acoustic resonator reference oscillators" 42 (42): 1425-1434, 2007
10 H. M. Lavasani, "A 76 dBOhm 1. 7 GHz 0. 18 um CMOS tunable TIA using broadband current pre-amplifier for high frequency lateral MEMS oscillators" 46 (46): 224-235, 2011
1 고형호, "정전 용량형 MEMS 공진기의 비이상적 주파수 응답 모델링" 한국센서학회 19 (19): 191-196, 2010
2 M. Abdelsalam, "Supporting circuitry for a fully integrated micro electro mechanical(MEMS)oscillator in 45 nm CMOS technology" 259-263, 2010
3 S. Tabatabaei, "Silicon MEMS oscillators for high-speed digital systems" 30 (30): 80-89, 2010
4 Y. Lin, "Series-resonant VHF micromechanical resonator reference oscillators" 39 (39): 2477-2491, 2004
5 S. Li, "Optimization, simulation, and fabrication of a microgyroscope" 36-42, 2001
6 A. Lee, "Non-ideal behavior of a driving resonator loop in a vibratory capacitive microgyroscope" 39 (39): 1-6, 2008
7 S. Lee, "Influence of automatic level control on micromechanical resonator oscillator phase noise" 341-349, 2003
8 A. Uranga, "Fully CMOS integrated low voltage 100 MHz MEMS resonator" 41 (41): 1327-1328, 2005
9 K. Sundaresan, "Electronically temperature compensated silicon bulk acoustic resonator reference oscillators" 42 (42): 1425-1434, 2007
10 H. M. Lavasani, "A 76 dBOhm 1. 7 GHz 0. 18 um CMOS tunable TIA using broadband current pre-amplifier for high frequency lateral MEMS oscillators" 46 (46): 224-235, 2011
11 J. Salvia, "A 56 MΩ CMOS TIA for MEMS applications" 199-202, 2009
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분석정보
인용정보 인용지수 설명보기
학술지 이력
| 연월일 | 이력구분 | 이력상세 | 등재구분 |
|---|---|---|---|
| 2022 | 평가예정 | 계속평가 신청대상 (계속평가) | |
| 2021-12-01 | 평가 | 등재후보로 하락 (재인증) |  |
| 2018-01-01 | 평가 | 등재학술지 선정 (계속평가) | |
| 2017-12-01 | 평가 | 등재후보로 하락 (계속평가) | |
| 2013-01-01 | 평가 | 등재 1차 FAIL (등재유지) | |
| 2010-01-01 | 평가 | 등재학술지 유지 (등재유지) | |
| 2008-01-01 | 평가 | 등재학술지 유지 (등재유지) | |
| 2005-01-01 | 평가 | 등재학술지 선정 (등재후보2차) | |
| 2004-01-01 | 평가 | 등재후보 1차 PASS (등재후보1차) | |
| 2002-07-01 | 평가 | 등재후보학술지 선정 (신규평가) | |
학술지 인용정보
| 기준연도 | WOS-KCI 통합IF(2년) | KCIF(2년) | KCIF(3년) |
|---|---|---|---|
| 2016 | 0.22 | 0.22 | 0.16 |
| KCIF(4년) | KCIF(5년) | 중심성지수(3년) | 즉시성지수 |
| 0.15 | 0.13 | 0.319 | 0.07 |
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