4.2 Article

Five-stage CMOS OTA frequency compensated via nested differential feedback

Publisher

WILEY
DOI: 10.1002/jnm.3079

Keywords

CMOS multi-stage OTA; five-stage amplifier; frequency compensation; miller effect; symbolic transfer function

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Nowadays, cascode structures or vertical arrangements of MOSFETs are unable to meet the demands for high gain amplifiers. Therefore, multi-stage amplifiers via cascading gain stages have become the only promising choice. The challenge lies in stability issues and frequency compensation. In this work, a new and efficient frequency compensation technique is proposed for a five-stage amplifier, with the major contribution being the use of only two Miller capacitors and two differential active stages to intensify the Miller effect and allow for simultaneous sharing of the Miller capacitor.
Nowadays cascode structures or vertical arrangements of MOSFETs can not satisfy demands regarding high gain amplifiers. As a direct result, the only promising choice turns to Multi-stage amplifiers via cascading gain stages. The challenge here is stability issues which shows itself by different frequency compensation. All problem starts with increasing number of nodes and consequent poles. The poles degenerate phase of system and need to be controlled. In this work, a five-stage amplifier is targeted for a new and efficient frequency compensation technique. The major contribution of proposed approach is using only two Miller capacitors with considerable small values (10 pF) compared to load capacitor (500 pF). This achieved via exploiting two differential active stages which intensify Miller effect and provide capability to share Miller capacitor at multiple loops simultaneously. The proposed amplifier with corresponding frequency compensation is described symbolically while a circuit level implementation is performed via HSPICE circuit simulator and TSMC 0.18 mu m CMOS technology. Based on simulation results, the proposed amplifier expresses a DC gain of 195 dB, a gain bandwidth product of 15.2 MHz, a phase margin of 90 degrees, and a power dissipation of 570 mu W.

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