Title :
High frequency self-compensation of current-feedback devices
Author :
Payne, Alison ; Toumazou, Chris
Author_Institution :
Imperial Coll., London, UK
Abstract :
The authors examine the performance of a current-feedback operational amplifier configured as a closed-loop voltage amplifier in two extremes of operation, unity gain and high gain, and suggest methods to extend the frequency response of each by self-compensating these circuits. Mechanisms for high-frequency self-compensation are evident within the transfer function of the device. The authors exploit this feature to achieve high-gain and high-bandwidth structures. The compensation at high gains is achieved by reducing the input impedance of the op-amp, thus reducing high-gain bandwidth roll-off. The frequency performance of an op-amp configured as a unity gain buffer is significantly improved by taking the output from the input side of the device
Keywords :
compensation; feedback; frequency response; nonlinear network synthesis; operational amplifiers; transfer functions; closed-loop voltage amplifier; current-feedback operational amplifier; frequency response; high gain; high-bandwidth structures; high-frequency self-compensation; high-gain bandwidth roll-off; input impedance; transfer function; unity gain; Bandwidth; Circuits; Equations; Feedback loop; Frequency response; Impedance; Performance gain; Resistors; Transfer functions; Voltage;
Conference_Titel :
Circuits and Systems, 1992. ISCAS '92. Proceedings., 1992 IEEE International Symposium on
Conference_Location :
San Diego, CA
Print_ISBN :
0-7803-0593-0
DOI :
10.1109/ISCAS.1992.230247
