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Power-Scaling Output-Compensated Three-Stage OTAs for Wide Load Range Applications

Joseph Riad, Johan J. Estrada-López, Ivan Padilla-Cantoya, E. Sánchez‐Sinencio

2020IEEE Transactions on Circuits and Systems I Regular Papers32 citationsDOI

Abstract

With the aggressive scaling of transistor dimensions, intrinsic device gains are dropping but the need for high-gain amplifiers still exists, resulting in a great interest in multistage amplifiers. Most existing amplifier topologies rely on Miller capacitors which achieve stability at the expense of reduced speed. In this paper, a new state feedback compensation strategy with gain enhancement using partial positive feedback is proposed whereby a multistage amplifier can be made output-compensated, thereby requiring no Miller capacitance while being able to drive a wide range of load capacitances. After a thorough theoretical analysis, a topology prototype is fabricated in a standard 130 nm CMOS technology and is able to drive loads from 90 nF-50 nF (~ 555×) using three discrete modes. The amplifier's power and bandwidth are scalable depending on the expected capacitive load range, with a maximum power consumption of 185 μW from a 1 V supply. Comparison with state-of-the-art amplifiers shows superior small-signal performance and competitive large-signal performance while driving a significantly larger range of capacitive loads.

Topics & Concepts

AmplifierCapacitorElectronic engineeringOperational amplifierCapacitive sensingCapacitanceTransistorElectrical engineeringDirect-coupled amplifierCurrent sense amplifierCMOSEngineeringTopology (electrical circuits)Computer sciencePhysicsVoltageQuantum mechanicsElectrodeAnalog and Mixed-Signal Circuit DesignAdvancements in Semiconductor Devices and Circuit DesignNanowire Synthesis and Applications
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