Performance analysis of operational transconductance amplifier at 180nm technology

2016 Second International Innovative Applications of Computational Intelligence on Power, Energy and Controls with their Impact on Humanity (CIPECH) Pub Date : 2016-11-01 DOI:10.1109/CIPECH.2016.7918781

V. Bendre, A. K. Kureshi

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引用次数: 9

Abstract

This paper presents tutorial on performance analysis for the two-stage CMOS operational transconductance amplifier in conventional gate driven mode. Both the theoretical calculations and computer aided simulation analysis have been given in detail. Designs have been carried out using TSMC 180nm CMOS process. Schematic simulations have been carried out using ‘Pyxis Schematic’ and simulations have been done using simulator ‘Eldo’, version 11.2 of Mentor Graphics. Initially DC analysis is performed to find region of operation of all the transistors. Results shows that all the transistors are perfectly operating in saturation region. Further AC analysis demonstrates that Gain of the Op Amp is 75 dB, Phase Margin is 53.8°, & Unity Gain Bandwidth is 30.5MHz Also CMMR is 77.8dB & input referred noise voltage is 0.0fV/√Hz. From transient analysis, slew rate is obtained to be 0.37V/µs, settling time as 472ns. The output swings up to 1.25V and the op-amp dissipates power of 536.5µW under supply voltage of 1.8V. In order to have low power op-amp, supply voltage is scaled to 1.5V & further to 1.2V. The comparative analysis of the results shows that significant saving in power, 18% and 35% respectively, can be obtained without compromising for phase margin & slew rate and little compromise in few characteristics like gain, UGB, and CMRR with supply voltage scaling.

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180nm工艺下运算跨导放大器性能分析

本文介绍了两级CMOS运算跨导放大器在传统栅极驱动模式下的性能分析。给出了详细的理论计算和计算机辅助仿真分析。采用台积电180nm CMOS工艺进行了设计。使用“Pyxis Schematic”进行了原理图仿真，并使用Mentor Graphics的11.2版模拟器“Eldo”进行了仿真。首先进行直流分析，找出所有晶体管的工作区域。结果表明，所有晶体管都能在饱和区完美工作。进一步的交流分析表明，运算放大器的增益为75 dB，相位裕度为53.8°，单位增益带宽为30.5MHz, CMMR为77.8dB，输入参考噪声电压为0.0fV/√Hz。暂态分析结果表明，该器件的转换速率为0.37V/µs，稳定时间为472ns。输出振荡高达1.25V，在1.8V电源电压下，运算放大器的功耗为536.5µW。为了具有低功率运放，电源电压被缩放到1.5V和进一步到1.2V。对比分析结果表明，在不影响相位裕度和摆幅率的情况下，可以显著节省18%和35%的功率，并且在电源电压缩放时，对增益、UGB和CMRR等少数特性几乎没有影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 Second International Innovative Applications of Computational Intelligence on Power, Energy and Controls with their Impact on Humanity (CIPECH)

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