A Circuit Technique to Compensate PVT Variations in a 28nm CMOS Cascode Power Amplifier

Patrick Oßmann; Jörg Fuhrmann; José Moreira; Harald Pretl; Andreas Springer

A Circuit Technique to Compensate PVT Variations in a 28nm CMOS Cascode Power Amplifier

Patrick Oßmann, Jörg Fuhrmann, José Moreira, Harald Pretl, Andreas Springer

Department of Communications Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

This paper presents a method to compensate CMOS process-, voltage-, and temperature (PVT) variations in a linear two-stage RF power amplifier (PA). The proposed circuit technique mitigates bias point fluctuations caused by non-controllable uncertainties like wafer-dependent electron mobility, increasing die temperature due to substrate self-heating, or supply voltage deviations. A scaled PA replica cascode circuit and a controlled current mirror form a feedback loop which stabilizes the PA operation point over a wide range of PVT variations. As demonstrated by simulations and verified by measurements, the PA operating conditions have been stabilized over a temperature range of 90°C and more than 0.5V supply change. The proposed biasing scheme has been implemented using a 28nm standard CMOS process. The PA is able to deliver more than one Watt of RF output power at a peak power-added efficiency (PAE) of 33% at 1.8GHz center frequency operation.

Original language	English
Title of host publication	Microwave Conference (GeMIC), 2015 German
Pages	1-4
Number of pages	4
Publication status	Published - Mar 2015

Fields of science

202038 Telecommunications
202 Electrical Engineering, Electronics, Information Engineering
202030 Communication engineering

JKU Focus areas

Mechatronics and Information Processing

ACCM - Wireless Transceiver Technology
Brandstätter, S. (Researcher), Gebhard, A. (Researcher), Hoflehner, M. (Researcher), Huemer, M. (Researcher), Kanumalli, R. S. (Researcher), Li, J. (Researcher), Oßmann, P. (Researcher), Padmanabhan Madampu, S. (Researcher), Petit, M. (Researcher) & Springer, A. (PI)
01.01.2013 → 31.12.2017
Project: Funded research › FFG - Austrian Research Promotion Agency

Cite this

@inproceedings{f5e56e8aca0f460a976e3a72d1f178b7,

title = "A Circuit Technique to Compensate PVT Variations in a 28nm CMOS Cascode Power Amplifier",

abstract = "This paper presents a method to compensate CMOS process-, voltage-, and temperature (PVT) variations in a linear two-stage RF power amplifier (PA). The proposed circuit technique mitigates bias point fluctuations caused by non-controllable uncertainties like wafer-dependent electron mobility, increasing die temperature due to substrate self-heating, or supply voltage deviations. A scaled PA replica cascode circuit and a controlled current mirror form a feedback loop which stabilizes the PA operation point over a wide range of PVT variations. As demonstrated by simulations and verified by measurements, the PA operating conditions have been stabilized over a temperature range of 90°C and more than 0.5V supply change. The proposed biasing scheme has been implemented using a 28nm standard CMOS process. The PA is able to deliver more than one Watt of RF output power at a peak power-added efficiency (PAE) of 33% at 1.8GHz center frequency operation.",

author = "Patrick O{\ss}mann and J{\"o}rg Fuhrmann and Jos{\'e} Moreira and Harald Pretl and Andreas Springer",

year = "2015",

month = mar,

language = "English",

pages = "1--4",

booktitle = "Microwave Conference (GeMIC), 2015 German",

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TY - GEN

T1 - A Circuit Technique to Compensate PVT Variations in a 28nm CMOS Cascode Power Amplifier

AU - Oßmann, Patrick

AU - Fuhrmann, Jörg

AU - Moreira, José

AU - Pretl, Harald

AU - Springer, Andreas

PY - 2015/3

Y1 - 2015/3

N2 - This paper presents a method to compensate CMOS process-, voltage-, and temperature (PVT) variations in a linear two-stage RF power amplifier (PA). The proposed circuit technique mitigates bias point fluctuations caused by non-controllable uncertainties like wafer-dependent electron mobility, increasing die temperature due to substrate self-heating, or supply voltage deviations. A scaled PA replica cascode circuit and a controlled current mirror form a feedback loop which stabilizes the PA operation point over a wide range of PVT variations. As demonstrated by simulations and verified by measurements, the PA operating conditions have been stabilized over a temperature range of 90°C and more than 0.5V supply change. The proposed biasing scheme has been implemented using a 28nm standard CMOS process. The PA is able to deliver more than one Watt of RF output power at a peak power-added efficiency (PAE) of 33% at 1.8GHz center frequency operation.

AB - This paper presents a method to compensate CMOS process-, voltage-, and temperature (PVT) variations in a linear two-stage RF power amplifier (PA). The proposed circuit technique mitigates bias point fluctuations caused by non-controllable uncertainties like wafer-dependent electron mobility, increasing die temperature due to substrate self-heating, or supply voltage deviations. A scaled PA replica cascode circuit and a controlled current mirror form a feedback loop which stabilizes the PA operation point over a wide range of PVT variations. As demonstrated by simulations and verified by measurements, the PA operating conditions have been stabilized over a temperature range of 90°C and more than 0.5V supply change. The proposed biasing scheme has been implemented using a 28nm standard CMOS process. The PA is able to deliver more than one Watt of RF output power at a peak power-added efficiency (PAE) of 33% at 1.8GHz center frequency operation.

M3 - Conference proceedings

SP - 1

EP - 4

BT - Microwave Conference (GeMIC), 2015 German

ER -

A Circuit Technique to Compensate PVT Variations in a 28nm CMOS Cascode Power Amplifier

Abstract

Fields of science

JKU Focus areas

Projects

ACCM - Wireless Transceiver Technology

Cite this