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".
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The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
A técnica de baixa tensão para IC está se tornando um dos assuntos mais importantes. É muito difícil realizar um filtro que possa operar a 1 V ou menos porque a tensão base-emissor dos transistores dificilmente pode ser reduzida. Um projeto de um filtro de tempo contínuo de baixa tensão é apresentado neste artigo. O bloco de construção básico do filtro é um transcondutor pseudo-diferencial que não possui fonte de corrente de cauda. Portanto, a tensão operacional é inferior à de um par acoplado a emissor. Entretanto, o ganho de modo comum (CM) do transcondutor é bastante alto e o CMRR é baixo. Para reduzir o ganho CM, um circuito de feedback CM é empregado. A característica de transcondutância é expressa como a função do cosseno hiperbólico. O filtro projetado é um girador de quinta ordem.C filtro. O transcondutor e o filtro que possui uma característica passa-baixo Butterworth de quinta ordem são demonstrados pela simulação PSpice. A característica de transcondutância, CMRR e estabilidade do transcondutor são confirmadas através da simulação. Na análise do filtro, são examinadas a resposta em frequência e a tensão de deslocamento. É mostrado que o filtro que possui frequência de canto da ordem de megahertz pode operar com tensão de alimentação de 1 V.
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Fujihiko MATSUMOTO, Yasuaki NOGUCHI, "A 1-V Continuous-Time Filter Using Bipolar Pseudo-Differential Transconductors" in IEICE TRANSACTIONS on Fundamentals,
vol. E82-A, no. 6, pp. 973-980, June 1999, doi: .
Abstract: Low-voltage technique for IC is getting one of the most important matters. It is quite difficult to realize a filter which can operate at 1 V or less because the base-emitter voltage of transistors can hardly be reduced. A design of a low-voltage continuous-time filter is presented in this paper. The basic building block of the filter is a pseudo-differential transconductor which has no tail current source. Therefore, the operating voltage is lower than that of an emitter-coupled pair. However, the common-mode (CM) gain of the transconductor is quite high and the CMRR is low. In order to reduce the CM gain, a CM feedback circuit is employed. The transconductance characteristic is expressed as the function of hyperbolic cosine. The designed filter is a fifth-order gyrator-C filter. The transconductor and the filter which has a fifth-order Butterworth lowpass characteristic are demonstrated by PSpice simulation. Transconductance characteristic, CMRR and stability of the transconductor are confirmed through the simulation. In the analysis of the filter, frequency response and offset voltage are examined. It is shown that the filter which has corner frequency of the order of megahertz can operate at a 1 V supply voltage.
URL: https://global.ieice.org/en_transactions/fundamentals/10.1587/e82-a_6_973/_p
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@ARTICLE{e82-a_6_973,
author={Fujihiko MATSUMOTO, Yasuaki NOGUCHI, },
journal={IEICE TRANSACTIONS on Fundamentals},
title={A 1-V Continuous-Time Filter Using Bipolar Pseudo-Differential Transconductors},
year={1999},
volume={E82-A},
number={6},
pages={973-980},
abstract={Low-voltage technique for IC is getting one of the most important matters. It is quite difficult to realize a filter which can operate at 1 V or less because the base-emitter voltage of transistors can hardly be reduced. A design of a low-voltage continuous-time filter is presented in this paper. The basic building block of the filter is a pseudo-differential transconductor which has no tail current source. Therefore, the operating voltage is lower than that of an emitter-coupled pair. However, the common-mode (CM) gain of the transconductor is quite high and the CMRR is low. In order to reduce the CM gain, a CM feedback circuit is employed. The transconductance characteristic is expressed as the function of hyperbolic cosine. The designed filter is a fifth-order gyrator-C filter. The transconductor and the filter which has a fifth-order Butterworth lowpass characteristic are demonstrated by PSpice simulation. Transconductance characteristic, CMRR and stability of the transconductor are confirmed through the simulation. In the analysis of the filter, frequency response and offset voltage are examined. It is shown that the filter which has corner frequency of the order of megahertz can operate at a 1 V supply voltage.},
keywords={},
doi={},
ISSN={},
month={June},}
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TY - JOUR
TI - A 1-V Continuous-Time Filter Using Bipolar Pseudo-Differential Transconductors
T2 - IEICE TRANSACTIONS on Fundamentals
SP - 973
EP - 980
AU - Fujihiko MATSUMOTO
AU - Yasuaki NOGUCHI
PY - 1999
DO -
JO - IEICE TRANSACTIONS on Fundamentals
SN -
VL - E82-A
IS - 6
JA - IEICE TRANSACTIONS on Fundamentals
Y1 - June 1999
AB - Low-voltage technique for IC is getting one of the most important matters. It is quite difficult to realize a filter which can operate at 1 V or less because the base-emitter voltage of transistors can hardly be reduced. A design of a low-voltage continuous-time filter is presented in this paper. The basic building block of the filter is a pseudo-differential transconductor which has no tail current source. Therefore, the operating voltage is lower than that of an emitter-coupled pair. However, the common-mode (CM) gain of the transconductor is quite high and the CMRR is low. In order to reduce the CM gain, a CM feedback circuit is employed. The transconductance characteristic is expressed as the function of hyperbolic cosine. The designed filter is a fifth-order gyrator-C filter. The transconductor and the filter which has a fifth-order Butterworth lowpass characteristic are demonstrated by PSpice simulation. Transconductance characteristic, CMRR and stability of the transconductor are confirmed through the simulation. In the analysis of the filter, frequency response and offset voltage are examined. It is shown that the filter which has corner frequency of the order of megahertz can operate at a 1 V supply voltage.
ER -