The design and implementation of a high efficiency Class-J power amplifier (PA) for base station applications is reported. A commercially available 10 W GaN HEMT device was used, for which a large-signal model and an extrinsic parasitic model were available. Following Class-J theory, the needed harmonic terminations at the output of the transistor were defined and realised. Experimental results show good agreement with simulations verifying the class of operation. Efficiency above 70% is demonstrated with an output power of 39.7 dBm at an input drive of 29 dBm. High efficiency is sustained over a bandwidth of 140 MHz.The design and implementation of a high efficiency Class-J power amplifier (PA) for base station applications is reported. A commercially available 10 W GaN HEMT device was used, for which a large-signal model and an extrinsic parasitic model were available. Following Class-J theory, the needed harmonic terminations at the output of the transistor were defined and realised. Experimental results show good agreement with simulations verifying the class of operation. Efficiency above 70% is demonstrated with an output power of 39.7 dBm at an input drive of 29 dBm. High efficiency is sustained over a bandwidth of 140 MHz

McGeehan, JP

Mimis, K

Morris, KA

English

Explore Bristol Research

                          Mimis, K., Morris, K. A., & McGeehan, J. P. (2011). A 2GHz GaN Class-Jpower amplifier for base station applications. In 2011 IEEE TopicalConference on Power Amplifiers for Wireless and Radio Applications(PAWR). (pp. 5 - 8). Institute of Electrical and Electronics Engineers (IEEE).10.1109/PAWR.2011.5725378Link to published version (if available):10.1109/PAWR.2011.5725378Link to publication record in Explore Bristol ResearchPDF-documentUniversity of Bristol - Explore Bristol ResearchGeneral rightsThis document is made available in accordance with publisher policies. Please cite only the publishedversion using the reference above. Full terms of use are available:http://www.bristol.ac.uk/pure/about/ebr-terms.htmlTake down policyExplore Bristol Research is a digital archive and the intention is that deposited content should not beremoved. However, if you believe that this version of the work breaches copyright law please contactopen-access@bristol.ac.uk and include the following information in your message:• Your contact details• Bibliographic details for the item, including a URL• An outline of the nature of the complaintOn receipt of your message the Open Access Team will immediately investigate your claim, make aninitial judgement of the validity of the claim and, where appropriate, withdraw the item in questionfrom public view.Centre for Communications Research A 2GHz GaN Class-J Power Amplifier for Base Station Applications K Mimis, K.A. Morris and J.P. McGeehan University of Bristol, UK Need for reduction of base station power consumption while increasing QoS  Power Amplifier is a major power consumer  High order constellations are necessary  Channel bandwidths keep increasing   Class-J  Recently introduced (2006)  Complex fundamental impedance  Reactive 2nd harmonic Continuous “design space”  Multiple impedance pairs (Zfo, Z2fo)  Class-B-like output power and efficiency  Class-B / J / J* are specific sub-cases  Efficient Linear Wideband 1.Deep Class - AB biasing 2.Determine appropriate load-line 3. Intrinsic drain impedances based on theory 4.3rd output harmonic impedance  5.Source-pull for efficiency/gain 6.Observe intrinsic drain waveforms 7.Design matching networks    Large signal transistor model  Extrinsic parasitics and package model  Intrinsic drain impedances given from theory  No active harmonic load-pull  No RF waveform probing   3rd harmonic not defined by theory  3rd harmonic reflection coefficient angle swept  Affects efficiency / output power  Chose an insensitive/efficient case  Intrinsic drain waveforms  De-embedded in simulations to prove Class of operation  No “zero” voltage crossing  Similar to expected waveforms  Some 3rd harmonic present  Current “hump”  Distributed matching networks  2 harmonics controlled at the input, 3 at the output  RT/Duroid 8550 substrate  Er = 2.2, T = 787mm  Size : 13.5 x 6.5 cm  Higher Er will reduce size  65% maximum PAE  40dBm output power  Good back-off performance  Low asymmetry up to 20MHz  Low memory effects  Facilitates linearization  60%+ efficiency over 140MHz  39-40dBm output power over band  LTE and LTE-Advanced  More freedom in PA design / No need for specific impedances  Theory and extrinsic parasitic model is sufficient  3rd output harmonic impedance is important  65% PAE, over 70% drain efficiency, 40dBm output power  Low memory effects  Promising under ET/EER implementations 102103104-15-10-5051015Magnitude (dB)Frequency spacing (kHz)  main tonesIMD3IMD5IMD72.04 2.06 2.08 2.1 2.12 2.14 2.16 2.18 2.2 2.22 2.2401020304050Output Power (dBm)frequency (GHz)  020406080100Drain Efficiency (%)Output PowerDrain Efficiency15 20 25 3051015202530354045Output Power/Gain (dBm/dB)Input Power (dBm)  1020304050607080Efficiency (%)Output PowerDrain EfficiencyGainPAE

A 2GHz GaN Class-J power amplifier for base station applications

Mimis, K., Morris, KA., & McGeehan, JP. (2011). A 2GHz GaN Class-J power amplifier for base station applications. In 2011 IEEE TopicalConference on Power Amplifiers for Wireless and Radio Applications(PAWR) (pp. 5 - 8). Institute of Electrical and Electronics Engineers(IEEE). https://doi.org/10.1109/PAWR.2011.5725378Peer reviewed versionLink to published version (if available):10.1109/PAWR.2011.5725378Link to publication record on the Bristol Research PortalPDF-documentUniversity of Bristol – Bristol Research PortalGeneral rightsThis document is made available in accordance with publisher policies. Please cite only thepublished version using the reference above. Full terms of use are available:http://www.bristol.ac.uk/red/research-policy/pure/user-guides/brp-terms/Centre for Communications Research A 2GHz GaN Class-J Power Amplifier for Base Station Applications K. Mimis, K. A. Morris and J.P. McGeehan  Centre for Communication Research, University of Bristol   2 / 15 • Outline • PA designer targets • Traditional approaches • Introduction to Class-J • Design methodology • Realization and measurements • Conclusions 3 / 15 • Main drivers • GREEN • Environmental concerns • Operational expenses • SIMPLE • Deployment costs • Maintenance • FAST • User experience • Efficiency • Linearity • Bandwidth Which one is more important? 4 / 15 • Traditional approaches • Power Amplifier • Linear amplifiers • Switching amplifiers • Harmonically tuned • System level • Doherty • Envelope Elimination & Restoration (EER) • Envelope tracking (ET) • Digital Pre-distortion Combinations 5 / 15 • Class J theory (1) • Recently introduced – explains widely observed results • Under harmonically tuned category (up to second harmonic) • Better control of trade-offs • Highly efficient • Quasi-linear • Super-set of Class-B operation GREEN SIMPLE WIDEBAND 6 / 15 • Biased as Class-B, deep AB • Second harmonic not shorted (purely reactive) • Complex fundamental impedance • No “knee” voltage crossing occurs • Same efficiency/output power as Class-B • Large drain voltage swing almost 3x supply voltage • Class J theory (2) 7 / 15 • Design space is continuous • All cases have same efficiency/output power • Class J theory (3) 0.20.51.02.05.0+j0.2-j0.2+j0.5-j0.5+j1.0-j1.0+j2.0-j2.0+j5.0-j5.00.0   ZfoZ2fo000.511.522.53  Class Jmid case 1Class Bmid case 2Class J* 2 3 48 / 15 • Methodology • Large signal transistor model • 10W GaN HEMT device • Transistor extrinsic parasitics model • Linear output capacitance • Class J theory • Impedances at the intrinsic drain 1. Deep Class - AB biasing 2. Determine appropriate load-line 3. Intrinsic drain impedances based on theory 4. 3rd output harmonic impedance 5. Source-pull for efficiency/gain 6. Observe intrinsic drain waveforms 7. Design matching networks   9 / 15 • 3rd output harmonic • Class J theory defines fundamental and second harmonic terminations • Class B biasing assumed • Perfect half-rectified sine wave drain current (no 3rd harmonic) IN PRACTICE? 10 / 15 • PA realisation • Input stabilization network • Harmonic control • Two at the input • Three at the output • RT-Duroid 8550 substrate • Er = 2.2 • T = 0.787 mm • Fully distributed architecture • Size : 13.5 x 6.5 cm 11 / 15 • Input power sweep 12 / 15 • Over frequency 152025302.052.12.152.2020406080 Input power (dBm)frequency (GHz) Drain efficiency (%)20304050607013 / 15 • Two tone measurements • Typical measure of memory effects • Asymmetry between upper/lower channels • Each tone 24dBm • Variable spacing (100kHz-50MHz) • Low memory effects up to 20MHz 102103104-15-10-5051015Magnitude (dB)Frequency spacing (kHz)  main tonesIMD3IMD5IMD714 / 15 • Variable VDS 10 15 20 25 30 35 40 451020304050607080Drain Efficiency (%)Output Power (dBm)  Vds = 9V - 31VPeaks • Good potential under ET/EER • VDS can go lower  (approx. 4-5V) • 15dB output power back-off • Modulator efficiency  15 / 15 • Conclusions • New tool for management of efficiency/linearity/bandwidth tradeoffs • More freedom in PA design / no need for harmonic short • Theory and extrinsic parasitic model is sufficient • 3rd harmonic is important • Low memory effects • Very promising for ET/EER implementations Centre for Communications Research Thank You  QUESTIONS? 17 / 15 APPENDIX HEMTs • Current generator plane is of interest • Cds is important • An appreciation of parasitics is needed • Package contribution is dominant  18 / 15 APPENDIX simulation results 19 / 15 APPENDIX measured efficiency over Pout 20 / 15 APPENDIX two tone measurements (24dBm) 21 / 15 APPENDIX two tone measurements (4MHz spacing) 

A 2GHz GaN Class-J power amplifier for base station applications

Abstract

Similar works

Full text

Available Versions

Explore Bristol Research

Explore Bristol Research

Crossref