Synthesis of High Gain Operational Transconductance Amplifiers for Closed-Loop Operation Using a Generalized Controller-Based Compensation Method

This paper presents a systematic procedure that can be used to create operational transconductance amplifiers (OTAs) for closed-loop operation using multiple low-gain stages to realize extremely high DC gain. Such devices are necessary to realize analog functions with demanding absolute accuracy requirements, e.g., high-resolution ADCs and DACs. The principle is based on the cascade of undamped integrators to realize large DC gains and a state-space derived controller to stabilize its operation in a closed-loop configuration. A programmable OTA fabricated in the IBM 130 nm CMOS process is used as a test vehicle to prove the design principle through its 2 to 5th-order realization. Measured data reveals DC gains ranging from 50 to 150 dB with a 3-dB bandwidth of 10 kHz and a unity gain frequency of 10 MHz. While this paper demonstrates the design principles using CMOS integrated circuits, the principle is general and can be applied to any type of circuit technology in integrated or discrete implementation. Moreover, the methods are easily automated as the principles are based on closed-form formulae as opposed to iterative numerical search techniques.

[1]  Ka Nang Leung,et al.  Three-stage large capacitive load amplifier with damping-factor-control frequency compensation , 2000, IEEE Journal of Solid-State Circuits.

[2]  Edinei Santin,et al.  A Two-Stage Fully Differential Inverter-Based Self-Biased CMOS Amplifier With High Efficiency , 2011, IEEE Transactions on Circuits and Systems I: Regular Papers.

[3]  W. Martin Snelgrove,et al.  Synthesis and analysis of state-space active filters using intermediate transfer functions , 1986 .

[4]  M. Kejariwal,et al.  A 250+dB open loop gain feedforward compensated high precision operational amplifier , 2002, Proceedings of the 28th European Solid-State Circuits Conference.

[5]  Jose Silva-Martinez,et al.  A robust feedforward compensation scheme for multistage operational transconductance amplifiers with no Miller capacitors , 2003, IEEE J. Solid State Circuits.

[6]  M. Hochberg,et al.  Control engineering , 1991, Nature.

[7]  P.R. Gray,et al.  MOS operational amplifier design-a tutorial overview , 1982, IEEE Journal of Solid-State Circuits.

[8]  Igor M. Filanovsky,et al.  Enhancing amplifiers/filters bandwidth by transfer function zeroes , 2015, 2015 IEEE International Symposium on Circuits and Systems (ISCAS).

[9]  Ligang Hou,et al.  Impedance Adapting Compensation for Low-Power Multistage Amplifiers , 2011, IEEE Journal of Solid-State Circuits.

[10]  Gordon W. Roberts,et al.  High-swing MOS current mirror with arbitrarily high output resistance , 1992 .

[11]  Pak Kwong Chan,et al.  Cross Feedforward Cascode Compensation for Low-Power Three-Stage Amplifier With Large Capacitive Load , 2012, IEEE Journal of Solid-State Circuits.

[12]  Francois Krummenacher,et al.  A 4-MHz CMOS Continuous-Time Filter with On-Chip Automatic Tuning , 1987, ESSCIRC '87: 13th European Solid-State Circuits Conference.

[13]  Horst Zimmermann,et al.  A low-voltage low-power fully differential rail-to-rail input/output opamp in 65-nm CMOS , 2008, 2008 IEEE International Symposium on Circuits and Systems.

[14]  B. Barmish A Generalization of Kharitonov's Four Polynomial Concept for Robust Stability Problems with Linearly Dependent Coefficient Perturbations , 1988 .