Continuous-time common-mode feedback networks for fully-differential amplifiers: a comparative study

2002 ◽  
Author(s):  
J.F. Duque-Carrillo
Keyword(s):  
Comparative Study ◽  
Continuous Time ◽  
Common Mode ◽  
Differential Amplifiers ◽  
Fully Differential ◽  
Feedback Networks

Common Mode Feedback Circuits for Low Voltage Fully-Differential Amplifiers

2016 ◽  
Vol 25 (10) ◽  
pp. 1650124 ◽  
Author(s):  
S. Rekha ◽  
T. Laxminidhi
Keyword(s):  
Power Supply ◽  
Continuous Time ◽  
Efficient Solution ◽  
Low Voltage ◽  
Cmos Technology ◽  
Common Mode ◽  
Power Efficient ◽  
Differential Amplifiers ◽  
Fully Differential ◽  
Simulation Results

Continuous time common mode feedback (CMFB) circuits for low voltage, low power applications are proposed. Four circuits are proposed for gate/bulk-driven pseudo-differential transconductors operating on sub-1-V power supply. The circuits are validated for a bulk-driven pseudo-differential transconductor operating on 0.5[Formula: see text]V in 0.18[Formula: see text][Formula: see text]m standard CMOS technology. Simulation results reveal that the proposed CMFB circuits offer power efficient solution for setting the output common mode of the transconductors. They also load the transconductor capacitively offering capacitance of about 1[Formula: see text]fF to tens of femto farads.

Testing fully differential amplifiers using common mode feedback circuit: A case study

2015 ◽  
Author(s):  
Isis D. Bender ◽  
Guilherme S. Cardoso ◽  
Arthur C. de Oliveira ◽  
Lucas C. Severo ◽  
Alessandro Girardi ◽  
...  
Keyword(s):  
Feedback Circuit ◽  
Common Mode ◽  
Differential Amplifiers ◽  
Fully Differential

scholarly journals Compact Continuous Time Common-Mode Feedback Circuit for Low-Power, Area-Constrained Neural Recording Amplifiers

Electronics ◽  
2021 ◽  
Vol 10 (2) ◽  
pp. 145
Author(s):  
Joon Young Kwak ◽  
Sung-Yun Park
Keyword(s):  
Low Power ◽  
Continuous Time ◽  
Cmos Technology ◽  
Neural Recording ◽  
Low Noise ◽  
Common Mode ◽  
Passive Components ◽  
Fully Differential ◽  
Transconductance Amplifier ◽  
Differential Difference Amplifier

A continuous-time common-mode feedback (CMFB) circuit for low-power, area-constrained neural recording amplifiers is proposed. The proposed CMFB circuit is compact; it can be realized by simply replacing passive components with transistors in a low-noise folded cascode operational transconductance amplifier (FC-OTA) that is one of the most widely adopted OTAs for neural recording amplifiers. The proposed CMFB also consumes no additional power, i.e., no separate CMFB amplifier is required, thus, it fits well to low-power, area-constrained multichannel neural recording amplifiers. The proposed CMFB is analyzed in the implementation of a fully differential AC-coupled neural recording amplifier and compared with that of an identical neural recording amplifier using a conventional differential difference amplifier-based CMFB in 0.18 μm CMOS technology post-layout simulations. The AC-coupled neural recording amplifier with the proposed CMFB occupies ~37% less area and consumes ~11% smaller power, providing 2.67× larger output common mode (CM) range without CM bandwidth sacrifice in the comparison.

scholarly journals Simple Scheme for the Implementation of Low Voltage Fully Differential Amplifiers without Output Common-Mode Feedback Network

2020 ◽  
Vol 10 (4) ◽  
pp. 34
Author(s):  
Mario Renteria-Pinon ◽  
Jaime Ramirez-Angulo ◽  
Alejandro Diaz-Sanchez
Keyword(s):  
Figure Of Merit ◽  
Low Voltage ◽  
Cmos Process ◽  
Large Signal ◽  
Simple Scheme ◽  
Common Mode ◽  
Differential Amplifiers ◽  
Fully Differential ◽  
Feedback Network ◽  
Strong Inversion

A simple scheme to implement class AB low-voltage fully differential amplifiers that do not require an output common-mode feedback network (CMFN) is introduced. It has a rail to rail output signal swing and high rejection of common-mode input signals. It operates in strong inversion with ±300 mV supplies in a 180 nm CMOS process. It uses an auxiliary amplifier that minimizes supply requirements by setting the op-amp input terminals very close to one of the rails and also serves as a common-mode feedback network to generate complementary output signals. The scheme is verified with simulation results of an amplifier that consumes 25 µW, has a gain-bandwidth product (GBW) of 16.1 MHz, slew rate (SR) of 8.4 V/µs, the small signal figure of merit (FOMSS) of 6.49 MHz*pF/µW, the large signal figure of merit (FOMLS) of 3.39 V/µs*pF/µW, and current efficiency (CE) of 2.03 in strong inversion, with a 10 pF load capacitance.

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