High-linearity tunable low-Gm transconductor based on bootstrapping
Fecha
2021Versión
Acceso abierto / Sarbide irekia
Tipo
Artículo / Artikulua
Versión
Versión aceptada / Onetsi den bertsioa
Impacto
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10.1109/TCSII.2021.3090983
Resumen
In this brief, a novel pseudo-differential low-transconductance amplifier is proposed based on the bootstrapping technique. The transconductor is implemented using two voltage follower topologies as amplifiers with their outputs connected to both terminals of a resistor, thus bootstrapping the voltages at these terminals to increase the equivalent resistance value, and achieve a very low transcon ...
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In this brief, a novel pseudo-differential low-transconductance amplifier is proposed based on the bootstrapping technique. The transconductor is implemented using two voltage follower topologies as amplifiers with their outputs connected to both terminals of a resistor, thus bootstrapping the voltages at these terminals to increase the equivalent resistance value, and achieve a very low transconductance without the need for large passive components. In this way, a highly-linear compact structure is designed whose transconductance can be tuned by external current sources. The circuit was fabricated in a standard 0.18μm CMOS process. The experimental results show a tunable transconductance in the range of tens of nA/V, with a total harmonic distortion lower than -40dB at 350mVpp@1kHz. The power consumption of the amplifier is 4μW under a 1.8V supply voltage. [--]
Materias
Analog CMOS,
Bootstrapping,
Current mirrors,
Linearity,
Low Gm OTA.,
Power demand,
Resistance,
Resistors,
Transconductance,
Transistors
Editor
IEEE
Publicado en
IEEE Transactions on Circuits and Systems Ii: Express Briefs, may 2021
Departamento
Universidad Pública de Navarra. Departamento de Ingeniería Eléctrica, Electrónica y de Comunicación /
Nafarroako Unibertsitate Publikoa. Ingeniaritza Elektrikoa, Elektronikoa eta Telekomunikazio Ingeniaritza Saila
Versión del editor
Entidades Financiadoras
This work was supported by CONACYT through the Doctoral Grant 467255 and the Research Project CONACYT CB-2015-257985