Title :
An improved common-mode feedback loop for the differential-difference amplifier
Author :
Simonetti, Alessandro ; Trifiletti, A.
Author_Institution :
Dept. of Electron. Eng., Univ. of Rome La Sapienza, Rome, Italy
Abstract :
Unconditional stability of the high-gain amplifiers is a mandatory requirement for a reliable steady-state condition of time-discrete systems, especially for all blocks designed to sample-and-hold (S/H) circuits. Compared to differential path, the common-mode feedback loop is often affected by poles and zeros shifting that degrades the large signal response of the amplifiers. This drawback is made worse in some well-known topologies as the difference-differential amplifier (DDA) that shows non-constant transconductance and poor linearity. This work proposes a body-driven positive-feedback frequency compensation technique (BD-PFFC) to improve the linearity for precision DDA-based S/H applications. Theoretical calculations and circuit simulations carried out in a 0.13 um process are also given to demonstrate its validity.
Keywords :
circuit feedback; circuit simulation; differential amplifiers; poles and zeros; sample and hold circuits; body-driven positive-feedback frequency compensation technique; circuit simulation; common-mode feedback loop; differential-difference amplifier; high-gain amplifier; nonconstant transconductance; poles and zeros shifting; sample-and-hold circuit; size 0.13 mum; time-discrete system; unconditional stability; Bandwidth; CMOS integrated circuits; Capacitors; Gain; Logic gates; Topology; Transconductance; DifferentialDiftcrence Amplifier; Positive-feedback compensation; analog-to-digital converters; low-voltage; sample-and-hold circuits;
Conference_Titel :
NORCHIP, 2011
Conference_Location :
Lund
Print_ISBN :
978-1-4577-0514-4
Electronic_ISBN :
978-1-4577-0514-4
DOI :
10.1109/NORCHP.2011.6163991
