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

Abteilung für Nachrichtentechnik

Publikation: Beitrag in Buch/Bericht/Konferenzband › Konferenzbeitrag › Begutachtung

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.

Originalsprache	Englisch
Titel	Microwave Conference (GeMIC), 2015 German
Seiten	1-4
Seitenumfang	4
Publikationsstatus	Veröffentlicht - März 2015

Wissenschaftszweige

202038 Telekommunikation
202 Elektrotechnik, Elektronik, Informationstechnik
202030 Nachrichtentechnik

JKU-Schwerpunkte

Mechatronics and Information Processing

ACCM - Wireless Transceiver Technology
Brandstätter, S. (Forscher*in), Gebhard, A. (Forscher*in), Hoflehner, M. (Forscher*in), Huemer, M. (Forscher*in), Kanumalli, R. S. (Forscher*in), Li, J. (Forscher*in), Oßmann, P. (Forscher*in), Padmanabhan Madampu, S. (Forscher*in), Petit, M. (Forscher*in) & Springer, A. (Projektleiter*in)
01.01.2013 → 31.12.2017
Projekt: Geförderte Forschung › FFG - Österreichische Forschungsförderungsgesellschaft

Dieses zitieren

@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",

}

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

Wissenschaftszweige

JKU-Schwerpunkte

Projekte

ACCM - Wireless Transceiver Technology

Dieses zitieren