power amplifier design for ultra...
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POWER AMPLIFIER DESIGN FOR ULTRA-WIDEBAND APPLICATIONS
MUHAMMAD SYAHIR BIN YOSUF
This report is submitted in partial fulfillment of the requirements for the award of
Bachelor of Electronic Engineering (Telecommunication Electronics) With Honours
Faculty of Electronic and Computer Engineering
Universiti Teknikal Malaysia Melaka
May 2009
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UNIVERSTI TEKNIKAL MALAYSIA MELAKA
FAKULTI KEJURUTERAAN ELEKTRONIK DAN KEJURUTERAAN KOMPUTER
BORANG PENGESAHAN STATUS LAPORAN
PROJEK SARJANA MUDA II
Tajuk Projek : POWER AMPLIFIER DESIGN FOR UWB APPLICATIONS
Sesi Pengajian : 2008/2009
Saya MUHAMMAD SYAHIR BIN YOSUF mengaku membenarkan Laporan Projek Sarjana Muda ini disimpan di Perpustakaan dengan syarat-syarat kegunaan seperti berikut: 1. Laporan adalah hakmilik Universiti Teknikal Malaysia Melaka.
2. Perpustakaan dibenarkan membuat salinan untuk tujuan pengajian sahaja.
3. Perpustakaan dibenarkan membuat salinan laporan ini sebagai bahan pertukaran antara institusi pengajian
tinggi.
4. Sila tandakan ( √ ) :
SULIT* (Mengandungi maklumat yang berdarjah keselamatan atau kepentingan Malaysia seperti yang termaktub di dalam AKTA RAHSIA RASMI 1972)
TERHAD* (Mengandungi maklumat terhad yang telah ditentukan oleh organisasi/badan di mana penyelidikan dijalankan)
TIDAK TERHAD
Disahkan oleh:
__________________________ ___________________________________
(TANDATANGAN PENULIS) (COP DAN TANDATANGAN PENYELIA)
Alamat Tetap: LOT 2290/3B, KAMPUNG
PADANG BALANG, 51100 GOMBAK, KUALA LUMPUR.
Tarikh: May 6, 2009 Tarikh:
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“I hereby declare that this report is the result of my own work except for quotes as
cited in the references.”
Signature :………………………………………………….
Author : MUHAMMAD SYAHIR BIN YOSUF
Date : 6TH
MAY 2009
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“I hereby declare that I have read this report and in my opinion this report is
sufficient in terms of the scope and quality for the award of Bachelor of Electronic
Engineering (Telecommunication Electronics) With Honours.”
Signature :………………………………………………….
Supervisor Name : AZAHARI BIN SALLEH
Date : 6TH
MAY 2009
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ACKNOWLEDGEMENT
I would like to express my gratitude to these following persons for all their guidance
and support:
My supervisor; Mr. Azahari B. Salleh;
My parents; Yosuf B. Rejab and Che Satariah Bte. Abd. Kadir;
And all of my friends.
THANK YOU VERY MUCH
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ABSTRACT
Ever since the FCC allocated 7.5 GHz (from 3.1 GHz to 10.6 GHz) for ultra
wideband (UWB) technology, interest has been renewed in both academic and
industrial circles to exploit this vast spectrum for short range, high data rate wireless
applications. The great potential of UWB lies in the fact that it can co-exist with the
already licensed spectrum users and can still pave the way for a wide range of
applications. However, this wide bandwidth complicates the circuit level
implementation of key RF blocks like the power amplifier (PA), transmit/receive
switch, low noise amplifier (LNA) and mixers in an UWB transceiver. The inability
of Narrow-Band (NB) system likes Bluetooth to deal with some important topics in
nowadays technology such as security, high data rate, signal loss, and range
resolution makes UWB technology an important subject to be exploited and
explored. The ultimate goal is to design a Power Amplifier which covers whole
range of UWB frequency from 3.1 GHz to 10.6 GHz. The design will focus on
Distributed Amplifier (DA) technique which is knowingly as an easy technique for
Broadband Power Amplifier design to achieve high output power and flat high gain
through the UWB frequency range. The design based on simulation using
Microwave Office 2006 and the output gain is 12.8 dB ± 0.5 dB with single-stage PA
circuit while the output gain with two stages PA circuit is 26 dB ± 2 dB.
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CONTENTS
CHAPTER TOPIC PAGES
PROJECT TOPIC i
CONFESSION ii
ACKNOWLEDGEMENT v
ABSTRACT vi
CONTENTS vii
LIST OF TABLES x
LIST OF FIGURES xi
LIST OF ABBREVIATIONS xiii
LIST OF APPENDICES xiv
Ι INTRODUCTION
1.1 Introduction of Project 1
1.2 Problem Statements 2
1.3 Objectives 3
1.4 Project Scope 4
1.5 Thesis Outline 4
ΙΙ UWB STUDY
2.1 UWB Basics 6
2.2 UWB Applications 8
2.3 UWB Power Amplifier 9
2.4 Specification of PA 10
2.4.1 Frequency Range of Operation 10
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2.4.2 Output Power 10
2.4.3 Efficiency 11
2.4.4 Power Gain/Voltage Gain 12
2.4.5 Gain Flatness 12
2.4.6 Linearity 12
2.4.6.1 1-dB Compression 12
2.4.7 Power Consumption 13
2.4.8 Power Control 14
2.4.9 Power Saving Mode 14
2.4.10 Noise Figure 14
2.4.11 Stability 15
2.5 Classes of Power Amplifier Operation 15
2.5.1 Linear Amplifiers 16
2.5.2 Switching Amplifiers 19
2.6 Principle of CRTSSDA 20
ΙΙΙ AMPLIFIER DESIGN
3.1 Two-port power gain 24
3.2 Single-stage amplifier 26
3.3 Stability Consideration 27
3.3.1 Consideration for stability in amplifier design 28
3.3.2 Decision formula 28
3.3.3 Stability Test 30
3.4 DC Biasing 30
3.5 Input and Output Matching 32
3.5.1 Quarter Wave Transformer Matching 33
3.5 Previous Work of Projects 36
ΙV METHODOLOGY
4.1 Literature Review 41
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4.2 Specification of Power Amplifier 41
4.3 Calculation / Simulation 41
4.4 Optimization and Analysis 42
V RESULT AND DISCUSSION
5.1 Selection of Transistor 44
5.2 Stability Consideration 44
5.3 Calculation 45
5.4 Simulation 50
5.4.1 DC Biasing Simulation Result 50
5.4.2 Matching Simulation Result 52
5.4.3 Single-Stage PA Design 53
5.4.3.1 S-Parameter Results for Single Stage PA 54
5.4.3.2 S-Parameter Results for Two Stages PA 63
VΙ CONCLUSION AND FUTURE WORK
6.1 Conclusion 72
6.2 Future Work 73
REFERENCES 74
APPENDICES 75
x
LIST OF TABLES
NO TITLE PAGES
2.1 Summary of power amplifier classes 20
xi
LIST OF FIGURES
NO TITLE PAGES
2.1 Acceptable power levels for indoor and outdoor emissions 7
2.2 Fractional bandwidth comparison of a narrowband and UWB signal 8
2.3 1-dB compression characteristics 13
2.4 Class A operations 17
2.5 Class-A amplifier waveforms 17
2.6 Conduction angle relations for linear amplifiers 18
2.7 Equivalent circuit diagram of the n stage CRTSSDA 21
2.8 Small signal gains of three-stage CRTSSDA and three-stage TWDA 22
2.9 Schematic Diagram of the optimized three-stage power CRTSSDA 23
3.1 Two-port networks with general source and load impedance. 25
3.2 General transistor amplifier circuits 27
3.3 Output stability circle 29
3.4 Input stability circles 29
3.5 Five Basic DC Biasing 31
3.6 Lossless network matching networks arbitrary load impedance to a
transmission line. 33
3.7 Matching with a single section quarter-wave transformer 35
3.8 Quarter-wave transformer solution 36
3.9 Power Amplifier Schematics 37
3.10 Top levels PA schematic 38
4.1 Project Expectation Work Flow 39
4.2 General Flow Chart of Designing UWB Amplifier 40
4.3 Equivalent Input Matching Circuit 42
4.4 Equivalent Output Matching Circuit 42
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5.1 Biasing Setup 50
5.2 Vgs value compared to Current (IDS) 51
5.3 DC biasing circuit type „A‟ 52
5.4 Inputs and Output Matching Network 53
5.5 Single-Stage Power Amplifier Circuit with DC Bias 53
5.6 S21 output graph 54
5.7 S21 after optimization 55
5.8 Input returns loss (S11) and output return loss (S22) before optimization 56
5.9 Input returns loss (S11) and output return loss (S22) after optimization 56
5.10 Insertion Loss 57
5.11 Available Gain 58
5.12 Maximum Available Gain 58
5.13 Maximum Stable Gain 59
5.14 Operating Power Gain 59
5.15 Transducer Gain 60
5.16 Current Gain 60
5.17 Voltage Gain 61
5.18 Peak Voltage 61
5.19 Input and Output Power 62
5.20 Noise Figure 62
5.21 Two stages Power Amplifier circuit 63
5.22 S21 output graph 64
5.23 Input returns loss (S11) and output return loss (S22) before optimization 65
5.24 Insertion Loss 66
5.25 Gain Available 66
5.26 Maximum Available Gain 67
5.27 Maximum Stable Gain 67
5.28 Operating Power Gain 68
5.29 Transducer Gain 68
5.30 Peak Voltage 69
5.31 Noise Figure 69
5.32 Input and Output Power 70
5.33 Current Gain 70
5.34 Voltage Gain 71
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LIST OF ABBREVIATION
UWB - Ultra Wide-Band
FCC - Federal Communications Commission
PA - Power Amplifier
RF - Radio Frequency
CRTSSDA - Cascaded Reactively Terminated Single Stage Distributed
Amplifier
HJFET - Hetero Junction Field Effect Transistor
CSSDA - Cascaded Single Stage Distributed Amplifier
DA - Distributed Amplifier
xiv
LIST OF APPENDICES
NO TITLE PAGES
A Datasheet NE3210S01 75
B Input Matching Smith Chart 79
C Output Matching Smith Chart 80
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CHAPTER 1
INTRODUCTION
Over recent years, the interest for ultra wideband (UWB) in Malays ia has
grown tremendously due to the germination of researches and implementation
of UWB applications at local university and private sectors. It caused by the
modern re-incarnation of an old type of communication. The first cross Atlantic
wireless transmission by Guglielmo Marconi used spark-plug transmitters that
can be thought of as impulse based UWB transmission [1]. Today, the same
technology provided by Guglielmo Marconi is being revivified for its immense
potential in high data rate communications.
1.1 Introduction of Project
Ever since the FCC allocated for 3.1 GHz to 10.6 GHz for UWB
technology, the interest has been renewed in both academic and industrial
circles to exploit this huge spectrum for short range and high data rate wireless
applications [2]. It‟s a great potential of UWB to be widely applied because it
can co-exist with the licensed spectrum and can still open the path for a wide
range of applications such as high definition television (HDTV) and wireless
transmission at higher data rate compared to the data transfer rate in Bluetooth
communications technology so it can replace the Bluetooth technology in
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wireless personal area network (WPAN) devices likes mobile phones, laptops,
personal computers (PC), printers, GPS receivers, and video game consoles [3].
However, this wide bandwidth coverage makes the circuits design of key
RF blocks of front-end transceiver system such as power amplifier,
transmit/receive switch and low noise amplifier becomes more complicated. The
implementation of RF power amplifier (PA) is one of the challenging aspects in
emerging Ultra Wide-Band (UWB) radio frequency (RF) systems. The design of
broadband amplifier introduces new difficulties which require many considerations
such as linearity, efficiency, gain, insertion loss and return loss. Basically, the
design of amplifier over a broad frequency range is a matter of properly
designing the reactively matched circuit, traveling wave circuit, cascade single
stage distributed amplifier, feedback circuit or loss matched circuit in order to
compensate for the variation of frequency [6].
The Cascaded Reactively Terminated Single Stage Distributed Amplifier
(CRTSSDA) was one of the broadband amplifier techniques which are an
improvement from the CSSDA technique in order to functioned at large signal
operational and enhanced amplifier performance in term of output power and
power added efficiency (PAE). But, the CRTSSDA technique is complicated to
be designed because of it high power added efficiency (PAE). CRTSSDA
technique also provide an excellent performance because the input and output
capacitances of the active devices are absorbed in the distributed structures. As a
result, the amplifier can exhibits very low sensitivities in process variations when
designing and simulate. The simple and easy technique is a Distributed Amplifier
technique but it compensates the amplifier efficiency. The simulation works will
be done by using Microwave Office due to its ease of implementation.
1.2 Problem Statement
The UWB technology take place in short range communication system
instead of narrow-band (NB) due to NB inability to deal with some important topics
in nowadays technology such as security, high data rate, signal loss, and range
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resolution. Narrow-band technology such as Bluetooth confront with the problem of
multipath fading which is described as signal loss due to the destructive interference
of continuous wave (CW) signals [5]. Next, the problem in NB is that the signals
transmit are insecure because NB signals are easily detected and jammed [5].
Narrow-band signals also facing a problem of poor range resolution for tracking
applications and limited data rate because narrow RF bandwidth means narrow data
bandwidth [5]. In general, the RF performance of the Power Amplifier is excellent if
it able to achieve the high gain, high output power, and high power added efficiency.
By designing only a single stage amplifier, we cannot provide a high gain, high
output power, high power added efficiency, and high stability amplifier as expected.
As for the different biasing circuit, active biasing does not offer much advantage
over the passive biasing circuit so the matching networks can be changed to either
lumped elements, shunt stub or quarter wave matching techniques for space
reduction and cost saving. The developing of amplifier based on Distributed
Amplifier technique will enhance performance in term of output power but affect the
power added efficiency. There is also a problem of some conventional power
amplifier design not support the whole range of UWB licensed bandwidth
from 3.1 GHz to 10.6 GHz.
1.3 Objectives
Ultra Wide-Band Power Amplifier (PA) is an integrated component of most
RF systems. The objectives of this UWB amplifier design are to design a broadband
Power Amplifier that can operate in whole UWB frequency range that is from 3.1
GHz to 10.6 GHz based on Distributed Amplifier technique and obtain the expected
gain about 10 dB and constant gain (flatness gain) as possible over the whole range
of UWB frequency.
The transistor type used in the design of Power Amplifier for this project is
Hetero Junction Field Effect Transistor (HJFET) NE3210S01 manufactured by NEC
Corporation. This project involving of familiarization and utilization of a RF
amplifier design technique using Microwave Office software.
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1.4 Project Scopes
The scope of works to design Power Amplifier which covers the frequency
range between 3.1 GHz – 10.6 GHz can be divided into three main parts; simulation,
testing and analyzing, and optimization. Simulation design of Power Amplifier will
be done by using Microwave Office software version 7.0 in order to get the required
results which are close to the theoretical results. The expected results should provide
an overall gain of 10 dB, output power of 20 dBm from input power 0 dBm, return
losses below -3 dB and gain flatness ± 1 dB. Next, it‟s about analyzing and
calculating of the maximum gain and return loss in S-Parameters analysis - S21 and
S11 parameter. Then, second part is the testing and analyzing which involving the
analysis of every part in the circuit, the effect of each components of the UWB
Amplifier. Last part for this project is optimization part which covers an optimization
of the circuit to get the expected results.
1.5 Thesis Outline
Chapter 1 is about an introduction of project which includes an explanation of
project background, a brief introduction of Ultra Wide-band (UWB) and Power
Amplifier (PA), method used in PA design, objectives of project, and project scopes.
Chapter 2 of background study defines in details about UWB and PA, and
also about method used in the design work.
Chapter 3 contains a details explanation of an amplifier design technique
which consist a single stage amplifier design, DC biasing design, and input output
matching design.
Chapter 4 contains a research methodology which includes the steps to design
Power Amplifier and a brief explanation of methodology flow chart.
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Chapter 5 discuss about the selection of transistor and the result from this
project; which is S-parameter analysis, and all gains analysis.
Chapter 6 reveals the conclusion of this project and future works suggestion
on this project.
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CHAPTER 2
UWB STUDY
Interest in Ultra-wideband (UWB) has surged since the FCC‟s approval of a
First Report and Order in February 2002 which provides spectrum for the use of
UWB in various application areas because of the extremely large bandwidth
available to be exploited and currently UWB technology being touted as a solution
for high data rate, short-range wireless networks.
2.1 UWB Basics
By traditional definition, ultra wideband technology employs very narrow
pulses, of the order of a few nano-seconds, in order to establish high data rate
communications [3]. These narrow pulses translates to energy spread over a wide
frequency band, and hence the name ultra-wideband (also called Impulse radio).
Very high data rates can be achieved over a short distance in devices employing the
UWB technology.
An integral part of designing systems for short-range wireless network
application or any application is an understanding of the statistical nature of the
wireless UWB channel. However, one of the important conditions is that the power
levels of the UWB signal in this spectrum must be low enough to avoid interference
with the already existing technologies. The FCC specifies the power emission levels
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suitable for co-existing with other technologies in the UWB allocated band [7]. The
spectrum mask for both indoor and outdoor emissions is shown in Fig. 2.1.
Figure 2.1 Acceptable power levels for indoor and outdoor emissions [12]
According to the FCC, a UWB system is classified using one of two different
measures of bandwidth. A system can either have an instantaneous bandwidth in
excess of 500 MHz or have a fractional bandwidth that exceeds 0.20 (by comparison
a narrowband signal typically has a fractional bandwidth which is less than 0.01).
Both metrics are defined according to the -10 dB points of the signal‟s spectrum.
Fractional bandwidth is defined as the signal‟s bandwidth divided by its center
frequency or more precisely as
( 2.1)
where fH is the highest frequency and fL is the lowest frequency of the signal at the -
10 dB points [8]. These definitions specify that systems with a center frequency
greater than 2.5 GHz must have a bandwidth greater than 500 MHz and a system
with a center frequency less than 2.5 GHz must have a fractional bandwidth greater
than 0.20. Figure 2.2 below provides an illustration comparing the fractional
bandwidth of a narrowband signal and a UWB signal, BWNB is the narrowband
LH
LHf
ff
ffBW
2
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signal bandwidth, BWUWB is the UWB signal bandwidth, and fc is the signal‟s center
frequency. As Figure 2.2 demonstrates a UWB signal‟s bandwidth can cover a large
range of frequencies. It is therefore important that UWB devices use a low transmit
power spectral density in order to not interfere with existing narrowband
communications systems.
Figure 2.2 Fractional bandwidth comparison of a narrowband and UWB signal [12]
2.2 UWB Applications
The wide spectrum allocated to UWB directly translates into a wireless
channel with high spatial capacities. This is obtained from the famous Shannon‟s
channel capacity theorem
)1(log2
SNRBC (2.2)
where C is the channel capacity in bits/second, B is the bandwidth in Hertz and SNR
is the Signal-to-Noise Ratio.
Expression 2.2 shows a linear relation of the channel capacity with
bandwidth and logarithmic relation with the SNR. Unlike narrowband systems
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whose data rate is limited by the bandwidth and SNR, UWB systems can achieve
high data rates while operating below the noise floor. Nevertheless UWB is power
limited which indirectly limits the overall channel capacity.
With attractive features like excellent multi-path immunity and good
immunity to external interference, UWB technology is projected to revolutionize a
wide array of applications. The key for several applications is also the lower
frequency content involved. Some of the potential applications of UWB include:
• Military communications
• Short range covert communication devices
• Collision avoidance sensors
• Ground-penetrating Radar
• Through-the-wall Radar
• Emergency motion and imaging
• Security devices
• Home networking without physical connections
• Radio Frequency Identification (RFID) devices
2.3 UWB Power Amplifier
Power amplifiers (PA) are a part of the transmitter front-end used to amplify
the transmitted signal so the signal can be received and decoded within a fixed
geographical area. Power Amplifier boost the signal power high enough such that it
can propagate the required distance over the wireless medium. Typically, this power
is delivered to an antenna which acts like a 50 Ω load. The main PA performance
parameter is the output power level the PA can achieve, depending on the targeted
application, linearity, and efficiency. It can range from a few mili-watts for home
networks to hundreds of watts at base stations. Power amplifiers can be categorized
several ways depending on whether they are broadband or narrowband, and whether
they are intended for linear operation (Class A, B, AB and C) or constant-envelope
operation (Class D, E and F). This application note focuses on the design of
narrowband and linear PA‟s.
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In UWB systems, the power level from the UWB transmitter should be small
enough not to interfere with the already existing communication systems. The output
power levels need to achieve less than -41.25 dBm/MHz (as specified by the FCC).
As a result, UWB systems need not require large transistors as part of the power
amplifier circuit and this indirectly translates to lower power consumption.
However, achieving a high gain and good impedance match over the entire
frequency band makes the design a challenging task.
2.4 Specifications of the PA
The most important trade-off in PA design is between efficiency and
linearity. Most Power Amplifiers employ a two-stage configuration, with a matching
network placed at the input, between the stages, and at the output. In this section,
some of the important terms and specifications related to a PA are discussed.
2.4.1 Frequency range of operation
In a narrowband application, the PA is designed for a particular frequency
range and all the parameters are measured at that frequency. However, the frequency
range to be covered for UWB is wide range from 3.1 GHz to 10.6 GHz. So the
Power Amplifier considered in this thesis target the 3.1 to 10.6 GHz range.
2.4.2 Output power
This parameter determines the amount of power that needs to be delivered to
the load. As mentioned earlier, UWB transmitters are required to deliver very low
output power of the order of a few hundreds of micro-watts. The output power level
standard stated by FCC should be less than -41.25 dBm/MHz. It means that the
output power from 3.1GHz to 10.6GHz should be in the range of 23.66 dBm ~ 28.75
dBm.