A Novel Noise Cancelling Technique for CMOS Low...
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A Novel Noise Cancelling Technique for CMOS Low Noise Amplifier
Thesis submitted in partial fulfillment
of the requirements for the degree of
Master of Science (by Research)
in
Electronics & Communication Engineering
by
Mohd Anwar
201132638 [email protected]
Center for VLSI & Embedded System Technologies (CVEST)
International Institute of Information Technology (IIIT-H)
Hyderabad-500 032, INDIA
January 2015
Copyright © 2015 by Mohd Anwar
All Rights Reserved
INTERNATIONAL INSTITUTE OF INFORMATION TECHNOLOGY
Hyderabad, India
CERTIFICATE
This is to certify that the work presented in this thesis, titled “A Novel Noise Cancelling
Technique for CMOS Low Noise Amplifier” by Mr. Mohd Anwar, Roll No. 201132638,
submitted in partial fulfillment for the award of the degree of Master of Science by Research,
jointly in “Center for VLSI and Embedded System Technologies (CVEST), International
Institute of Information Technology Hyderabad (IIIT-H)” and “Electrical Engineering
Department (EED), Indian Institute of Technology Hyderabad (IITH)”, has been carried out
under our supervision and is not submitted elsewhere for a degree.
Advisor:
Dr. Azeemuddin Syed
Assistant Professor
Center for VLSI & Embedded System Technologies
International Institute of Information Technology
Hyderabad, India
Co-Advisor:
Dr. Mohammed Zafar Ali Khan
Associate Professor & Head of the Dept.
Electrical Engineering Department
Indian Institute of Technology
Hyderabad, India
I
Acknowledgement
First of all thanks to “The Most Beneficent and The Most Merciful God” for blessing me
the abilities and ways to carry out my education. And, thanks to my parents and younger
brothers for their kind support and patience while I was engaged in my work.
I would like to express my deep gratitude to my research guide Dr. Azeemuddin Syed for
his time-to-time positive critiques, patient guidance, priceless education, encouragement
to improve needed skills and providing me the required funding as well as facilities
during this research. I would like to offer my special thanks to my co-guide Dr.
Mohammed Zafar Ali Khan for his regular advices, useful feedbacks, highlighting the
different approaches for this research, providing required funding and facilities in Indian
Institute of Technology Hyderabad.
I would also like to thank International Institute of Information Technology Hyderabad
for providing excellent infrastructure and facilities during my academics. Moreover,
thanks to faculty members of CVEST for their offering of necessary courses which have
provided me a good understanding related to this work.
Thanks to my colleagues Mr. Bhuvanan, Mr. Vasu, Mr. Anirban, Mr. Gopi, Mr. Ajinkya,
and others for many constructive discussions and their cooperation in arranging required
facilities and making a joyful study environment in campus. I would also like to
acknowledge industry experts Mr. Shiva and Mr. Mahboob from AMD Hyderabad, and
Mr. Avinash from Bangalore for their technical help in this work.
II
Abstract
Since FCC had authorized UWB frequency range from 3.1 GHz to 10.6 GHz for wireless
communication, several technologies developed for communication applications. And, demand
of low cost, high data rate wireless communication systems rapidly increased. Although, current
wireless design circuits built for cellular or non-cellular applications, trade-off with matching,
signal detection, linearity, gain and noise parameters.
In wireless receiver systems, effect of noise of all the subsequent stages is reduced by the gain of
low noise amplifier (LNA) and its noise injects directly into the receiver. Thus, it is necessary to
boost the desired signal power while adding as little noise and distortion as possible so that the
retrieval of this signal is possible in the later stages in the system. As LNA is first block in
receiver chain, it must provide high gain for the next blocks. Moreover, noise of LNA is critical,
since the received input signal is extremely weak and can be easily corrupted by even small
amount of thermal noise. Additionally, it is desirable to integrate the circuit with CMOS
technology to achieve low cost and chip area. This block has the job of matching the antenna
input with the rest of the circuitry and simultaneously amplifying it for further processing.
Recent demonstrations show that LNAs ranging from few MHz to 10 GHz are included in
wireless receivers which uses single LNA for contiguous broadband signal processing. And, there
are various techniques to design narrow band and wide band LNAs such as design using basic
common source and common gate configurations with few improvement methods such as using
noise cancellation techniques.
In contrast to existing LNA topologies implementing noise cancellation techniques which usually
do not consider much about gain improvement, this work proposes a design of common gate LNA
employing a noise cancelling technique which not only reduces the noise but also improves the
gain and is novel to best of our knowledge. In order to cancel the dominant thermal noise, we
have analyzed the noise contributions from both, active and passive components in an existing
CG LNA. The input matching device viz. first CG transistor was identified as the most dominant
noise source which contributes 42% of overall LNA noise and remains flat i.e. (2.8 ± 0.3) dB over
the entire range. However, second stage common source transistor contributes 22% in whole
range and is more near the corner frequencies which is due to the narrow band characteristics of
common source amplifiers. Hence, this work’s target is to cancel the most dominant thermal noise
through proposed noise cancelling technique.
The proposed technique is based on combining two paths one with reversed phase noise-signal
and the other with non-reversed phase noise-signal, simultaneously the RF-signals in the two
paths should be in-phase. The two parallel paths were designed by symmetrical cascade
combination of CG-CS and CS-CG stages. Moreover, theoretical model of noise cancellation is
presented along with the derived equations of overall noise figure. Finally, implementation is
done using TSMC 0.18 µm CMOSRF technology on Cadence Spectre RF tool. Significantly,
III
proposed LNA achieve a reduction of 22.49% in base noise figure and 31.48% improvement in
peak power gain when compared to LNA without noise cancelling technique. Ultimately, peak
power gain of 28.4 dB and base NF of 3.17 dB with good stability and linearity are achieved over
the spectrum from 2.5 GHz to 4.5 GHz.
Additionally, this work implement a design of UWB LNA which include interstage matching
network to carry forward desired signal with the stoppage of undesired signal. Also includes a
Chebyshev band pass filter for input matching and a shunt-series inductive peaking network to
compensate the gain roll-off at higher frequencies. This design provides a peak power gain of
17.12 dB and base noise figure 3.4 dB within the frequency range from 3.1 GHz to 10.6 GHz.
Also demonstrate a good input matching i.e. well below -10 dB in the desired frequency range.
The entire circuit consumes 11.2 mW with 1.8 V supply and occupies 1 mm x 0.9 mm of layout
area. Moreover, a detailed survey of various existing methodologies (basic and advanced) for
narrow band, wide band and noise cancelling LNAs are discussed with their pros and cons.
IV
Contents: Page No.
Acknowledgement
Abstract
List of Figures
List of Tables
Abbreviations
Award and Publications
1. Introduction
1.1. Motivation
1.2. Contributions of this thesis
1.3. Outline of this thesis
2. Background
2.1. Design methodologies of CMOS low noise amplifier
2.1.1. Narrow band and wideband design methods
2.1.2. Noise reduction and gain improvement methods
3. A CMOS LNA employing a novel noise cancelling technique
3.1. Introduction
3.2. Investigation for major noise sources in existing CG LNA
3.3. A novel noise cancelling technique for CG UWB LNAs
3.4. A high gain reduced NF CMOS LNA employing novel noise cancelling
technique
3.5. Results and analysis
3.5.1. Performance summary
3.6. Conclusion and limitations
4. Other Work on Low Noise Amplifier
4.1. Introduction
4.2. A CMOS LNA with Peaking and Inter-stage Matching
4.2.1. Input impedance matching stage
4.2.2. Inter-stage matching
4.2.3. Shunt-series inductive peaking and gain stage
4.2.4. Noise analysis
4.3. Simulation results
4.4. Conclusion and limitations
I
II
VI
VIII
IX
XI
1
2
3
5
5
8
12
12
14
16
18
23
24
25
25
26
27
29
30
32
34
V
5. Layout Techniques
6. Summary and Conclusions
6.1. Summary
6.2. Conclusions
6.3. Recommendations for future research
Appendix A
Appendix B
Bibliography
35
41
42
42
44
49
57
VI
List of Figures:
Figure No.
Page No.
Chapter 1
1.1 Block diagram of a UWB receiver 1
1.2 Improvement of receiver sensitivity due to LNA: (a) without LNA (b) with
noiseless LNA (c) with LNA noise (all values are in dB)
2
Chapter 2
2.1 (a) common gate configuration (b) cascode common gate configuration 6
2.2 Feed forward noise cancelling technique 9
2.3 CG-CS single ended to differential output configuration 9
2.4 Single ended noise cancelling LNA 10
2.5 Two stage noise canceling LNTA configuration 10
2.6 Composite type inductor less noise cancelling LNA (a) Simplified schematic
architecture (b) Half circuit model (c) Composite NMOS/PMOS transistors
11
Chapter 3
3.1 LNA without noise cancellation 13
3.2 Noise contribution by LNA components for entire range of 3.1 GHz to 10.6 GHz 13
3.3 Noise figure contribution of LNA major components at all frequencies 13
3.4 Noise cancellation concept for LNA 14
3.5 Major noise sources of LNA 15
3.6 Proposed LNA with noise cancellation technique (biasing not shown) 17
3.7 Two transistor analog RF adder and its simplified small signal equivalent circuit 17
3.8 Simulated noise figure plot for proposed LNA with noise cancellation 19
3.9 Simulated power gain plot for proposed LNA with noise cancellation 19
3.10 Simulated input reflection coefficient plot for proposed LNA with noise
cancellation
20
3.11 Simulated and theoretical noise figure plots for LNA with noise cancellation 20
3.12 Simulated stability factor plot for LNA with noise cancellation 21
3.13 Simulated IIP3 plot for proposed LNA 21
3.14 AC analysis of RF adder 21
3.15 Transient analysis of RF adder 22
3.16 Layout of the proposed LNA 22
VII
Chapter 4
4.1 Simplified schematic of UWB LNA 26
4.2 Equivalent circuit of input impedance matching network 27
4.3 Equivalent circuit of UWB LNA with matching networks 27
4.4 Equivalent circuit of input impedance of second stage 27
4.5 Load of first stage 29
4.6 Load of second stage 29
4.7 Noise model of the input matching network 31
4.8 Simulated noise figure of UWB LNA 32
4.9 Simulated input reflection coefficient of UWB LNA 33
4.10 Simulated forward transmission gain of UWB LNA 33
4.11 Layout of the UWB LNA 33
Chapter 5
5.1 Transistor fingering and poly routing with its response 38
5.2 Metal connection immediately after poly with its response 38
5.3 Array of capacitors connection 38
5.4 Single and multiple parallel vias with its response 39
5.5 Placing of M1 transistor near to input terminal 39
5.6 Supply wires routed with top metal layer 40
5.7 Wide wires connected to input transistor 40
Appendix A
A.1 Idea of noise cancellation with additional gain block 43
A.2 Proposed noise cancelling LNA with phases of noise signal and RF signal at
different nodes
44
A.3 Noise contributing components for noise figure calculation (a) left branch
containing CG-CS transistors (b) right branch containing CS-CG transistors
44
Appendix B
B.1 LNA with Inductor as an inter stage impedance network 48
B.2 Equivalent circuit for calculation of input and output impedances of two stages 49
B.3 Equivalent circuit for calculation of output impedance of first stage 49
B.4 Equivalent circuit for calculation of input impedance of second stage 51
B.5 LNA with LC network between two stages 53
B.6 Equivalent circuit for the calculation of input and output impedances of two stages 53
B.7 Equivalent circuit setup for the calculation of input impedance of second stage 53
VIII
List of Tables:
Table No. Page No.
Chapter 3
3.1 Aspect ratios and parameter values of proposed circuit 23
3.2 Performance summary of the noise cancelling LNA 23
Chapter 4
4.1 Performance summary of the UWB LNA 34
IX
Selected Symbols and Abbreviations:
Symbol Meaning
LNA Low noise amplifier
VGA Voltage gain amplifier
LO Local oscillator
LPF Low pass filter
BPF Band pass filter
DSP Digital signal processing
FCC Federal Communications Commission
CMOS Complementary metal oxide semiconductor
SNR Signal to noise ratio
SNRmin Minimum signal to noise ratio which receiver can sense
S Signal
NRX Noise of the receiver
RX Receiver
G Gain of low noise amplifier (used in receiver architecture)
dB Decibel
CS Common source
CG Common gate
RF Radio frequency
TSMC Taiwan Semiconductor Manufacturing Company
µm Micro meter
UWB Ultra wideband
NF Noise figure
MHz Mega hertz
GHz Giga hertz
Q Quality factor of inductor
NB Narrow band
WB Wide band
DC Direct current
Rf (or) RF Feedback resistance
Av Voltage gain
Zin Input impedance
gm Transconductance of MOSFET
mS Milli Semen’s
Ω Ohm
T Absolute temperature
X
k Boltzmann constant
γ Transistor parameter
fT Unity gain frequency
MOSFET Metal oxide semiconductor field effect transistor
VS Source voltage
RS Source resistance
Vn Noise voltage
Vout Output voltage
Vb Biasing voltage
IIP3 Third order input intercept point
LNTA Low noise transconductance amplifier
NMOS N type MOSFET transistor
PMOS P type MOSFET transistor
gm,n Transconductance of N type transistor
gm,p Transconductance of P type transistor
gm,eff Effective transconductance
Cgd Gate drain capacitance of MOSFET transistor
Cgs Gate source capacitance of MOSFET transistor
LM Inductor connected in between two stages of UWB LNA
Cby Bypass capacitance
Cpad Pad capacitance
LLD Load inductor
RLD Resistance of load inductor
LG2 Inductor connected at gate terminal of second stage transistor
Cg Capacitor connected at gate of transistor
LS Inductor connected at source terminal of first stage transistor
(Degeneration inductor )
W(s) Transfer function of band pass filter
Ct Total capacitance
Zo Characteristic impedance
ρ Ripple factor of band pass filter
Zin1 Input impedance of UWB LNA without gate inductor
Zin1' Input impedance of UWB LNA with gate inductor
Zin2 Second stage input impedance of UWB LNA with interstage LC passive
network
Zin2' Second stage input impedance of UWB LNA with interstage inductor
Zo1 Output impedance of first stage of UWB LNA
Vgs Gate source voltage
Icgs Current flowing through gate source capatance
Vx Test voltage for input or output impedance calculation
XI
Ix Test current for input or output impedance calculation
Xcgs Equivalent impedance of gate source capacitance
rds (or) ro Drain source resistance of MOSFET
M Mutual inductance
Award and Publications:
Award:
“Commendation Award” from “International Institute of Information Technology Hyderabad” for
commendable contributions and involvement in the campus life activity. (2014)
Publications related to this thesis:
M. Anwar, S. Azeemuddin, M.Z.A. Khan, “Design and Analysis of a Novel Noise Cancelling
Topology for Common Gate UWB LNAs”, International Symposium on VLSI Design & Testing
(VDAT), Springer CCIS 382, pp. 169-176, July 2013.
M. Anwar, S. Azeemuddin, M.Z.A. Khan, “A CMOS UWB LNA with Shunt-Series Inductive
Peaking and Interstage Matching”, IEEE Applied Electromagnetics Conference, Dec 2013.
Other publication:
S. Sharma, S. Azeemuddin, M. Anwar “A self learning VLSI Lab along with Web-based Platform to
design Schematics and Layouts”, IEEE International Conference on Technology for Education
(T4E), pp. 205-207 July-2011.
VLSI virtual lab on web: http://deploy.virtual-labs.ac.in/labs/cse14/final-build/index.php
- 1 -
Chapter-1
Introduction
1.1 Motivation
Low noise amplifier is an important block in wireless receiver system. This block has the job of
matching the antenna input with the rest of the circuitry and simultaneously amplifying it for
further processing. A simplified block diagram of wireless receiver is shown in Figure 1.1.
Figure 1.1: Block diagram of a UWB receiver
Since the international and national authorities in different parts of the world had allotted
frequency bands for wireless communication applications, such as, in North America, allotted
UWB range is 3.1-10.6 GHz, in Europe 6-8.5 GHz, in Japan 3.4-4.2 GHz or 7.25-10.25 GHz,
several technologies developed for communication market [1-3]. Although, demand of low cost
and high data rate wireless communication increased, however, matching, signal detection, gain
and noise challenges in current wireless design are yet to be confronted with. As LNA is first
block in receiver chain, it must provide high gain for the next blocks. Noise is critical in this
block since the input is extremely weak and can be easily corrupted by even small amounts of
thermal noise. Additionally, it is desirable to integrate with CMOS technology to achieve low
cost and chip area.
The need of low noise amplifier for the improvement of receiver sensitivity is discussed in this
part of the introduction section. Figure 1.2 shows three different cases of receiver in which
SNRa, SNRb and SNRc are signal to noise ratios for cases (a), (b) and (c) respectively. First,
when LNA is not placed at the front end of the receiver, the value of receiver noise, NRX, is
significantly comparable to signal strength, S, hence SNRa < SNRmin. Second, a noiseless LNA is
placed at the front end of the receiver, and due to the gain (G) of LNA, the signal to noise ratio
- 2 -
becomes much greater than the SNRmin, hence sensitivity of the receiver improves significantly.
However, practical LNA contributes an amount of noise to the receiver as represented in case
(c). In this case, the noise of LNA, NLNA, directly adds with the receiver noise and reduces the
SNR at the input than in case (b). Nevertheless, SNRc value is more than the SNRmin, and less
than SNRb. Hence, to maintain this condition, large LNA gain is an essential requirement.
Moreover, the noise contribution of large gain LNA is dominant in overall receiver noise at the
input which can be illustrated from the noise expression in case (c). Hence, the LNA noise
should be as less as possible to achieve better sensitivity.
RX
S
NRX
Signal = S
Noise =NRX
SNRa = (S-NRX)
RX
S
NRX
Signal = S
Noise =NRX-G
SNRb = S-(NRX - G)
= S+G-NRX
LNA
Gain= “G”
NRX-G
RX
S
NRX
Signal = S
Noise =(NRX-G)+ NLNA
SNRc = S-{(NRX - G)+NLNA}
= S+G-NRX-NLNA
LNA
Gain= “G”
NRX-G
NLNA
SNRa<SNRmin
SNRb>SNRmin
SNRb>SNRc>SNRmin>SNRa
(a)
(b)
(c)
Figure 1.2: Improvement of receiver sensitivity due to LNA: (a) without LNA (b) with noiseless LNA (c)
with LNA noise (all values are in dB)
1.2 Contributions of this thesis
This thesis proposes a noise cancelling technique for CMOS low noise amplifier which
not only reduces the noise but also improves the gain and is novel to best of our
- 3 -
knowledge. In order to cancel the dominant noise, we analyzed the noise contributions
from both active and passive components in an existing three stage CG LNA. The input
matching device viz. first CG transistor was identified as the most dominant noise source.
Theoretical model of noise cancellation is presented along with the derived equations
based on two port model of overall noise figure. The circuit implementation is done using
TSMC 0.18 µm CMOSRF technology on Cadence Spectre RF tool.
This thesis also implement a design of CMOS UWB LNA with shunt-series inductive
peaking and interstage matching. This design includes inductive source degeneration
cascode topology with interstage matching network. Additionally a Chebyshev band pass
filter at the input and shunt-series inductive peaking at the output are placed which
provide better impedance matching and improved power gain.
A detailed survey of various existing design techniques of low noise amplifier is also
presented. In this survey, the design methodologies (basic and advanced) for narrow
band, wide band and noise cancelling LNAs are discussed with their pros and cons.
1.3 Outline of this thesis
The outline of this thesis is described below.
Chapter 2 presents a detailed discussion of various existing design topologies of low noise
amplifiers. In this, the design methodologies (basic and advanced) for narrow band, wide band
and noise cancelling LNAs are discussed with their pros and cons. LNA design topologies such
as design using common source and common gate configurations along with their drawbacks
rectifications are discussed. The goal to achieve an LNA design with high gain and low noise
figure is pursued seeking radically different existing design approaches.
Chapter 3 starts with an investigation of major noise sources in a three stage common gate low
noise amplifier. Thereafter, a novel noise cancelling technique with theoretical analysis for
common gate low noise amplifiers is proposed. Moreover, design of common gate low noise
amplifier employing proposed noise cancelling technique is implemented which not only reduces
the noise but also increases the gain. Noise cancellation of the most dominating thermal noise
source viz. the input matching device with theoretical analysis is presented in this chapter. On
implementing this technique, significant reduction of noise figure (NF) was observed. At the end
of this chapter, simulation results and performance summary are discussed.
Chapter 4 focuses on a broadband design of low noise amplifier. In this chapter, a CMOS UWB
LNA is designed with shunt-series inductive peaking and interstage matching. Theoretical
analysis with small signal equivalent models of input impedance matching, interstage matching
- 4 -
and shunt-series inductive peaking stages are presented. Moreover, the gain and noise models
with derived equations of different stages are described. The design and analysis includes
inductive source degeneration cascode topology with interstage matching network. Additionally
a Chebyshev band pass filter at the input and shunt-series inductive peaking at the output are
placed which provide better impedance matching and improved power gain. Simulation results
and conclusions are available at the end of this chapter.
Chapter 5 draw conclusions and the original contributions are summarized. Finally few
recommendations for further research are given.
- 1 -
Chapter-1
Introduction
1.1 Motivation
Low noise amplifier is an important block in wireless receiver system. This block has the job of
matching the antenna input with the rest of the circuitry and simultaneously amplifying it for
further processing. A simplified block diagram of wireless receiver is shown in Figure 1.1.
Figure 1.1: Block diagram of a UWB receiver
Since the international and national authorities in different parts of the world had allotted
frequency bands for wireless communication applications, such as, in North America, allotted
UWB range is 3.1-10.6 GHz, in Europe 6-8.5 GHz, in Japan 3.4-4.2 GHz or 7.25-10.25 GHz,
several technologies developed for communication market [1-3]. Although, demand of low cost
and high data rate wireless communication increased, however, matching, signal detection, gain
and noise challenges in current wireless design are yet to be confronted with. As LNA is first
block in receiver chain, it must provide high gain for the next blocks. Noise is critical in this
block since the input is extremely weak and can be easily corrupted by even small amounts of
thermal noise. Additionally, it is desirable to integrate with CMOS technology to achieve low
cost and chip area.
The need of low noise amplifier for the improvement of receiver sensitivity is discussed in this
part of the introduction section. Figure 1.2 shows three different cases of receiver in which
SNRa, SNRb and SNRc are signal to noise ratios for cases (a), (b) and (c) respectively. First,
when LNA is not placed at the front end of the receiver, the value of receiver noise, NRX, is
significantly comparable to signal strength, S, hence SNRa < SNRmin. Second, a noiseless LNA is
placed at the front end of the receiver, and due to the gain (G) of LNA, the signal to noise ratio
- 2 -
becomes much greater than the SNRmin, hence sensitivity of the receiver improves significantly.
However, practical LNA contributes an amount of noise to the receiver as represented in case
(c). In this case, the noise of LNA, NLNA, directly adds with the receiver noise and reduces the
SNR at the input than in case (b). Nevertheless, SNRc value is more than the SNRmin, and less
than SNRb. Hence, to maintain this condition, large LNA gain is an essential requirement.
Moreover, the noise contribution of large gain LNA is dominant in overall receiver noise at the
input which can be illustrated from the noise expression in case (c). Hence, the LNA noise
should be as less as possible to achieve better sensitivity.
RX
S
NRX
Signal = S
Noise =NRX
SNRa = (S-NRX)
RX
S
NRX
Signal = S
Noise =NRX-G
SNRb = S-(NRX - G)
= S+G-NRX
LNA
Gain= “G”
NRX-G
RX
S
NRX
Signal = S
Noise =(NRX-G)+ NLNA
SNRc = S-{(NRX - G)+NLNA}
= S+G-NRX-NLNA
LNA
Gain= “G”
NRX-G
NLNA
SNRa<SNRmin
SNRb>SNRmin
SNRb>SNRc>SNRmin>SNRa
(a)
(b)
(c)
Figure 1.2: Improvement of receiver sensitivity due to LNA: (a) without LNA (b) with noiseless LNA (c)
with LNA noise (all values are in dB)
1.2 Contributions of this thesis
This thesis proposes a noise cancelling technique for CMOS low noise amplifier which
not only reduces the noise but also improves the gain and is novel to best of our
- 3 -
knowledge. In order to cancel the dominant noise, we analyzed the noise contributions
from both active and passive components in an existing three stage CG LNA. The input
matching device viz. first CG transistor was identified as the most dominant noise source.
Theoretical model of noise cancellation is presented along with the derived equations
based on two port model of overall noise figure. The circuit implementation is done using
TSMC 0.18 µm CMOSRF technology on Cadence Spectre RF tool.
This thesis also implement a design of CMOS UWB LNA with shunt-series inductive
peaking and interstage matching. This design includes inductive source degeneration
cascode topology with interstage matching network. Additionally a Chebyshev band pass
filter at the input and shunt-series inductive peaking at the output are placed which
provide better impedance matching and improved power gain.
A detailed survey of various existing design techniques of low noise amplifier is also
presented. In this survey, the design methodologies (basic and advanced) for narrow
band, wide band and noise cancelling LNAs are discussed with their pros and cons.
1.3 Outline of this thesis
The outline of this thesis is described below.
Chapter 2 presents a detailed discussion of various existing design topologies of low noise
amplifiers. In this, the design methodologies (basic and advanced) for narrow band, wide band
and noise cancelling LNAs are discussed with their pros and cons. LNA design topologies such
as design using common source and common gate configurations along with their drawbacks
rectifications are discussed. The goal to achieve an LNA design with high gain and low noise
figure is pursued seeking radically different existing design approaches.
Chapter 3 starts with an investigation of major noise sources in a three stage common gate low
noise amplifier. Thereafter, a novel noise cancelling technique with theoretical analysis for
common gate low noise amplifiers is proposed. Moreover, design of common gate low noise
amplifier employing proposed noise cancelling technique is implemented which not only reduces
the noise but also increases the gain. Noise cancellation of the most dominating thermal noise
source viz. the input matching device with theoretical analysis is presented in this chapter. On
implementing this technique, significant reduction of noise figure (NF) was observed. At the end
of this chapter, simulation results and performance summary are discussed.
Chapter 4 focuses on a broadband design of low noise amplifier. In this chapter, a CMOS UWB
LNA is designed with shunt-series inductive peaking and interstage matching. Theoretical
analysis with small signal equivalent models of input impedance matching, interstage matching
- 4 -
and shunt-series inductive peaking stages are presented. Moreover, the gain and noise models
with derived equations of different stages are described. The design and analysis includes
inductive source degeneration cascode topology with interstage matching network. Additionally
a Chebyshev band pass filter at the input and shunt-series inductive peaking at the output are
placed which provide better impedance matching and improved power gain. Simulation results
and conclusions are available at the end of this chapter.
Chapter 5 draw conclusions and the original contributions are summarized. Finally few
recommendations for further research are given.
- 5 -
Chapter 2
Background
Overview: This chapter presents a detailed survey of various existing design techniques of low noise
amplifier. In this survey, the design methodologies (basic and advanced) for narrow band, wide band and
noise cancelling LNAs are discussed with their pros and cons. Although, few methods are improved
versions of basic design topologies and achieve better performance in parameters than earlier, however,
trade-off remains with the other parameters.
2.1 Design methodologies of CMOS low noise amplifier In wireless receiver systems, effect of noise of all the subsequent stages is reduced by the gain of
LNA and its noise injects directly into the receiver. Thus, it is necessary to boost the desired
signal power while adding as little noise and distortion as possible, so that the retrieval of this
signal is possible in the later stages of the system. Recent demonstrations show that LNAs
ranging from few MHz to 10 GHz are included in wireless receivers which uses single LNA for
contiguous broadband signal processing [4-6]. There are various techniques to design narrow
band and wide band LNAs such as design using basic common source and common gate
configurations with few improvements. Common source configuration with inductive
degeneration LNA provides good input matching for wide band range but requires a passive
network at the input which consists large number of high Q inductors. Moreover, LNA of this
configuration shows good noise performance for narrow band (NB) applications but not at corner
frequencies for wide band applications [7]. In this section, we review various design topologies
of existing LNAs and noise cancelling methods.
2.1.1 Narrow band and wideband design methods
There are few well known basic design topologies of LNA which can achieve the minimum
performance with some drawbacks. First, common source amplifier with resistive load is a basic
and simple LNA topology. It does not provide proper impedance matching and time constant
(RC) at the output prohibits the operation at high frequencies; also resistive load consumes more
DC voltage [8].
In contrast, common source amplifier with inductive load consumes less DC voltage across
inductor (ideally zero DC voltage drop). Moreover, inductive load resonates with total
capacitance at the output node, affording much higher frequency than common source amplifier
with resistive load. However, this topology faces the performance degradation due to the
- 6 -
significant parasitic capacitances and not enough isolation between input and output, and so
rarely used in modern RF design. Cascode common source with inductive degeneration topology
provides isolation between input and output; also separates the inductive load with the input
resistance.
Another topology of common source amplifier is with the resistive feedback. In this
topology, the feedback resistance (Rf) senses the output voltage and returns a current to the input.
This topology does not suffer from a direct trade-off between gain and supply because Rf carries
no bias current and provides flat gain (Av = ½(1-Rf/Rs)). Moreover, this topology provides good
wideband input matching as, Zin=1/gm, if gm = 20 mS then Zin = 50 Ω. The approximate
expression for noise figure of this topology, (1+ γ + γgmRs), shows that noise figure exceeds 3
dB. However, this topology can be considered if the desired operation of frequency is less than
the fT of the transistor.
In addition, LNA design with common gate configuration as shown in Figure 2.1(a) provides
ultra wide band input matching due to its low input impedance (1/gm), resulting in an improved
reverse isolation and therefore provides better stability. Indeed, a 50 Ω input matching can be
obtained just by setting the gm of the input MOSFET at the value of 20 mS. Drawback of this
topology is that simultaneous power and noise performance is not possible. So if this LNA
architecture is used without additional techniques such as noise cancellation, the noise figure is
very high. Moreover, noise figure of CG LNA is considerably large when compared to CS LNA
but it can be improved by using gm boosting technique which trades off with gain [34]. The noise
figure of common gate LNA is given by equation (2.1 and 2.2).
NF = 1+ γ
gmRs+
Rs
R1(1+
1
gmRs)
2
=1+ γ+4Rs
R1
(2.1)
(2.2)
M1Vb1
Vout
R1
RSVS
C1
(a)
M1Vb1
Vout
R1
RSVS
CM2
Vb2
(b)
Figure 2.1: (a) common gate configuration (b) cascode common gate configuration
- 7 -
From equation (2.1), this can be observed that a higher gm yields a low NF but also a lower input
impedance. Therefore, NF can be lower if impedance mismatch is permitted at the input (a
tradeoff between Zin and NF).
Chen et al. has used the common gate topology to design an UWB LNA in a 0.18 µm CMOS
technology [9]. The first stage is a common gate stage with a bandwidth enhancing inductor, and
the second stage is a cascode stage with an inductive series peaking. As expected the noise figure
is high especially in the high frequency range.
In contrast to the common source LNA, the contribution of load resistance (R1) noise to the
NF in CG is more. We know for CG LNA that the voltage gain from input to the output node at
the resonance frequency is equal to R1/Rs. Equation for noise figure of CG LNA indicates that
R1’s noise contribution i.e. 4Rs/R1, is equal to 4 divided by the voltage gain from the input source
to the output. Thus, for a typical gain of 10, this contribution reaches 0.4, a significant amount.
For inductive degenerated CS LNA, the R1’s contribution is equal to 4Rs/R1 multiplied by
(ω0/ωT)2. Thus, for operating frequency well below the fT of the transistor, the noise contribution
of R1 becomes negligible.
An alternative approach to lowering the input impedance in CG LNAs is to add a cascode
transistor as shown in Figure 2.1(b), however, in approximation, input impedance remains 1/gm.
Although, the addition of cascode device entails two issues: the noise contribution of cascode
transistor and the voltage headroom limitation due to stacking two transistors.
Distributed Amplifiers: The principle of the distributed amplifier is to produce two artificial
transmission lines coupled by several elementary amplifiers. The input and output capacitor of
the elementary amplifiers are all or part of the capacitors constituting the transmission lines. The
inductive part of the artificial transmission lines is synthesized by either inductors or by sections
of transmission lines. In this topology the amplifier stages are not cascaded, but in parallel.
Therefore distributed amplifiers provide lower gains compared with other architectures, but
theirs main advantage is the ability to achieve very large bandwidths, lower boundary in MHz
and upper boundary in 10’s GHz with good linearity and input-output matching. The main
disadvantages are the silicon area used to synthesize artificial transmission lines, and a heavy DC
power consumption resulting from the numerous stages commonly required to obtain a high gain
value and occupying significant chip area.
Zhang et al. has used a distributed amplifier architecture to design a UWB LNA in a 0.18 µm
CMOS technology [10]. The strength of this design is the power consumption which is below 10
mW. This low DC power consumption for a distributed amplifier has been obtained by using a
low number of stages and also by biasing the MOS transistors in a weak inversion mode. But, as
expected, the power gain is low (8 dB) and also the silicon area is high (1.16 mm2) because of
the great number of spiral inductors.
Heydari et al. has also used a distributed amplifier architecture in a 0.18 µm CMOS
technology [11]. The originality of this design is to use bandwidth enhancing inductors. So the
full FCC bandwidth is obtained with a good noise figure but with high power consumption (21
- 8 -
mW). However, the gain is low (8 dB) and the number of inductors very high (11 spiral
inductors).
Amplifiers with LC-Filters: In LC filter amplifier architecture the input matching cell is
designed with inductors and capacitors like in a standard band-pass filter. The strength of this
architecture is to provide a well-controlled band-pass response. This band-pass response reduces
the noise equivalent bandwidth and so the noise output voltage. The main drawback is to need of
more number of inductors and so low silicon area cannot be addressed with this architecture.
Bevilacqua et al. has implemented a third order band-pass input matching cell in a 0.18 µm
CMOS technology [12]. This LNA uses five spiral inductors and consequently consumes a large
silicon area. The power consumption is low (9 mW) but the noise figure is high especially in the
high frequency range.
2.1.2 Noise reduction and gain improvement methods
Recently, few topologies implementing noise cancellation techniques have reported. The
thermal noise cancellation technique which uses resistive feed forward CS configuration was
implemented for an LNA operating below 2 GHz [13, 14]. However, this technique was
extended to higher frequencies by using inductive peaking which shows reduction in noise figure
in 3.1-10.6 GHz frequency range [15]. In addition, various other noise cancellation techniques
[16-21] have been reported in literature such as simultaneous noise and third order distortion
cancellation technique in CG-CS cascade LNA operating till 2.1 GHz [16, 17] and resistive feed
forward noise cancellation technique in two stage differential transconductance LNA operating
till 4.5 GHz [18]. However, few reported topologies are based on trade-off optimization [22-26].
Hence it is evident that noise cancellation techniques usually do not consider much about gain
improvement.
Feed-forward noise cancelling Technique: Feed forward noise cancelling technique, shown
in Figure 2.2, lowers the noise figure within the targeted band and breaks the trade-off between
noise factor and input impedance. Feed forward configuration senses the desired signal and
cancel the thermal noise and distortion of the input transistor along with the noise of its biasing
circuit. The main advantage of this type of LNA is, it consume less power and occupy small chip
area with good stability. However, it operates below 2 GHz as reported in [13].
- 9 -
M1
RSVS
-Av
RF
X
Y
Z
Out
Figure 2.2: Feed forward noise cancelling technique
In this configuration, there is an auxiliary voltage-sensing amplifier and a matching
amplifier. These amplifiers are placed in such a way that the noise from the matching device
cancels at the output, while adding signal contributions. As shown in figure, thermal noise
current generated from the channel of the transistor flows through the feedback resistance and
have same polarity at node X and Y, but the signal, on the other hand, experiences inversion.
However, due to a voltage-sensing amplifier connected between input and output, the signal
becomes in phase and noise becomes out of phase, which, on combining, cancels the noise
components and adds the signal components at the output.
CG-CS noise cancelling technique: This topology of noise cancellation, shown in
Figure 2.3, is single-ended to differential output [8]. The noise of CG transistor i.e. Vn1 follows
common drain path to input node, X, and common source path to output path, Y, exhibit opposite
polarities at these two nodes. And, the signal follows CG path through X and Y, exhibiting the
same polarity. In a condition when input is matched, transistor M1 produces half of its noise
voltage at X. Common source transistor, a voltage sensing amplifier, connected between input
and output, senses this noise and amplifies it by a factor of –gm2R2. Hence, for the noise
cancellation, the two output should have equal noise voltages i.e. gm1R1Vn1/2 = gm2R2Vn1/2 and
reverse polarities.
M1Vb1
Vout
R1
RSVS
M2
R2
X Y
Figure 2.3: CG-CS single ended to differential output configuration
Niknejad et al. has presented an improved noise cancelling LNA design as shown in
Figure 2.4, which simultaneously exploits the noise and distortion cancellation [27]. This design
- 10 -
includes a cascaded common gate and common source configuration, the simplified topology is
shown in Figure 2.4. This LNA achieves, gain of 14.5 dB with NF 2.6 dB and a peak IIP3 +16
dB over a bandwidth from 800 MHz-2.1 GHz using 0.13 um CMOS technology.
M1Vb1
VoutR1
RSVS
M2
R2
M3
M4
Figure 2.4: Single ended noise cancelling LNA
Two stage noise cancelling LNTA: This technique includes two stages, first stage is
LNA which provides input matching in the frequency band of interest and the second stage
translates the voltage signal into current. The main noise contributor is transistor M1. The drain
noise current of M1 flows through RF and RS generating noise voltages at both nodes X and Y.
Noise voltages at nodes X and Y are in-phase but have different amplitudes which depend on the
values of R and Rs. First stage gain of the LNA is given in equation (2.3) where the noise voltage
Vn, Y is approximately “A” times of Vn,X.
A ≈ R/Rs ≈ Vn, Y/ Vn, X (2.3)
M1
RSVS
A
RF
X
Y
Z
Out-1
Second
Stage
Figure 2.5: Two stage noise canceling LNTA configuration
Therefore, if Vn, X is amplified by “A” and subtracted from Vn, Y, then it is possible to cancel
them out as depicted in Figure 2.5. In [18], it is reported that the LNTA achieves 14 dB first
- 11 -
stage gain and 115 mS for two stages, with 3.62 dB in band NF over 4.5 GHz 3 dB bandwidth.
However, LNTA consumes 40 mW of power.
Composite type noise cancelling LNA: The LNA architecture shown in Figure 2.6(a) is similar
to conventional broadband LNA with resistive matching, however, the overall NF is reduced due
to the composite configuration of NMOS and PMOS transistor which are connected in series
[28]. This configuration amplifies the differential voltage and rejects the common-mode one.
Due to series configuration of the two transistors, shown in Figure 2.6(c), the effective
transconductance, gm,eff, is represented by the series combination of the NMOS and PMOS
transistors. And, the value of effective transconductance is given by equation (2.5). As a result,
the output current is given by equation (2.4).
io = gm, eff(V1-V2) (2.4)
gm, eff = gm, n gm, p
gm, n + gm, p (2.5)
MP1
Vip
R1
RS VS
MN1
RF
Rb
Von
MP1
Vip
R1
MN1
Vin
RF
Rb
Von
MP1
Vin
R1
MN1
RF
Rb
Vop
(a) (b)
gmp
V1gmn
V2
gmeff(V1-V2)
(c)
Figure 2.6: Composite type inductorless noise cancelling LNA (a) Simplified schematic
architecture (b) Half circuit model (c) Composite NMOS/PMOS transistors
Where gm,n and gm,p are the transconductance of the NMOS and PMOS transistors, respectively.
The cross connection leads to partial noise cancellation of the noise generated by the NMOS and
PMOS transistors.
- 12 -
Chapter 3
A CMOS LNA employing a novel noise cancelling technique Overview: This chapter presents a design of common gate low noise amplifier (LNA) employing an
innovative noise cancelling technique which not only reduces the noise but also increases the gain. Noise
cancellation of the most dominating thermal noise source viz. the input matching device with theoretical
analysis is presented in this chapter. On implementing this technique, significant reduction of noise figure
(NF) was observed.
3.1 Introduction
In this work, we propose a design of common gate LNA employing a noise cancelling
technique which not only reduces the noise but also improves the gain and is novel to best of our
knowledge. In order to cancel the dominant noise, we analyzed the noise contributions from both
active and passive components in CG LNA reported in [29]. The input matching device viz. first
CG transistor was identified as the most dominant noise source. The technique is based on
combining two paths one with reversed phase noise signal and the other with non-reversed phase
noise signal, simultaneously the RF signals in the two paths will be in-phase. The two parallel
paths were designed by symmetrical cascade combination of CG-CS and CS-CG stages.
Theoretical model of noise cancellation is presented along with the derived equation based on
two port model of overall noise figure, and implementation is done using TSMC 0.18 µm
CMOSRF technology on Cadence Spectre RF tool.
3.2 Investigation for major noise sources in existing CG LNA
A three stage LNA as shown in Figure 3.1 is taken for detailed analysis and identification of
noise sources [29]. First stage is a CG stage followed by cascode CS stage and resistive feed
forward cascode CS stage with a buffer at the output. As expected, major noise contribution of
this LNA is from the CG transistor (M1) which is approximately 42% over the entire range of
3.1-10.6 GHz shown in Figure 3.2, extracted from noise simulation results. Second stage CS
transistor (M2) contributes 22% for the entire range and its noise contribution is more near the
corner frequencies. This is due to the restriction of narrow band characteristics of CS amplifier
while CG amplifier shows WB characteristics and its noise contribution is almost equal (2.8 ±
0.3) dB for the entire range as shown in Figure 3.3. Third stage noise contribution is negligible as
it receives the amplified signal from the earlier two stages. Therefore, it is desirable to suppress
the noise contribution of M1.
- 13 -
M1
M2
M3
M4
M5Vb1
Vb3Vb5
RF
Input
RF
Output
LoL1
LL
L2
M6
Rf
Figure 3.1: LNA without noise cancellation
Figure 3.2: Noise contribution by LNA components for entire range of 3.1 GHz to 10.6 GHz
Figure 3.3: Noise figure contribution of LNA major components at all frequencies
1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0 7.5 8.0 8.5 9.0 9.5 10.0 10.5 11.0 11.5 12.0
M1 5.47 5.18 4.16 3.39 3.01 2.82 2.72 2.68 2.67 2.69 2.73 2.77 2.82 2.88 2.90 2.98 3.06 3.14 3.20 3.28 3.37 3.47 3.57
M2 0.00 14.1 10.4 7.74 5.76 4.10 2.87 1.82 1.03 0.55 0.33 0.35 0.54 0.88 1.31 1.80 2.35 2.86 3.27 3.78 4.31 4.83 5.36
Lo 0.00 4.97 3.30 2.49 1.89 0.18 1.40 1.26 1.16 1.09 1.03 0.99 0.96 0.93 0.92 0.90 0.89 0.89 0.88 0.88 0.88 0.82 0.83
M3 0.00 0.00 0.42 0.30 0.23 0.19 0.15 0.12 0.10 0.09 0.09 0.11 0.16 0.23 0.33 0.48 0.67 0.88 1.08 1.36 1.71 2.10 2.55
0
2
4
6
8
10
12
No
ise
Fig
ure
(d
B)
f
NF
(d
B)
Frequency (GHz)
3.1 GHz - 10.6 GHz
M1
42%
M2
22%
M3
5%
M4
9%
Lo
11%L2
6%
M5
L1
other
5%
- 14 -
3.3 A novel noise cancelling technique for CG UWB LNAs
Hence, noise cancelling circuit was designed in order to cancel the noise generated by M1.
Figure 3.4 shows simplified noise cancelling technique in which ��,��
� is thermally generated
channel noise current equal to 4kTγgm1Δf. Equivalent noise voltage ��,��
� at the gate of M1 is
4kTγΔf/gm1. And, we observe a phase shift of 180o in noise voltage at node ‘B’ with respect to
��,��
� at the gate of M1 because of CS stage (source of M1 is common terminal) while it is in-
phase at node ‘A’ because of source follower stage (drain of M1 is common terminal).
Therefore, noise voltage at node ‘A’ and at node ‘B’ becomes 180o out-of-phase. After that, there
is a phase shift of 180o between the noise voltages at node ‘A’ and node ‘C’ because of CS stage
(M2) and hence the noise voltage at node ‘B’ and node ‘C’ are in-phase. This CS amplifier (M2)
also amplifies the RF input signal Vs.
2
1M,nI
2
1M,nV
Figure 3.4: Noise cancellation concept for LNA
The noise voltage generated by M1 is observed to be in-phase at nodes ‘C’ and ‘D’ due to CG
stage (M3). While, the noise voltage at node ‘E’ is 180o out-of-phase with respect to noise
voltage at node ‘B’ due to CS stage (M4). This finally results in noise voltages at nodes ‘D’ and
‘E’ to be 180o out-of-phase and hence is cancelled by adding them at the output. Simultaneously,
RF input signal is amplified through paths A-C-D and A-B-E and the phase shift in both these
paths are identical. Finally, the amplified RF signal at node ‘D’ and ‘E’ are in-phase and hence
added at the output through an adder circuit. Hence this topology amplifies the RF input signal
and simultaneously cancels the noise of most dominating thermally generated noise source.
- 15 -
2
Xo,nV2
4X,nV
2
4M,nV
2
1M,nV
2
Rs,nV2
2X,nV
2
2M,nV
2
3M,nV
2
1X,nV
Figure 3.5: Major noise sources of LNA
For theoretical analysis of proposed design, noise sources of first two stage components are
shown in Figure 3.5. Theoretical values of noise voltages for transistors and resistors are
4kTγΔf/gmi andi
kTR4 . Where k is Boltzmann constant, T is absolute temperature, γ is transistor
parameter, g��
is transconductance of ith transistor, Ri, and Xi are equivalent resistor and
impedance associated with ith inductor respectively. In the analysis below, it is assumed that the
noise of M1 is being cancelled and remaining components of first two stages are contributing to
overall noise figure.
Let �� and ��� are noise factors at two different output nodes z and z' as shown in Figure 3.5.
Equations (3.3, 3.4 and 3.6) are derived for ��, ��� and overall noise factor of the circuit
considering first two stages are having major contribution in noise:
Fz=1+Noise power at node z due to R, R�, R, M
Noise power at node z due to R�
(3.1)
Fz'=1+Noise power at node z' due to R�, M�, M�, R�
Noise power at node z' due to R�
(3.2)
Fz = 1+R
�gm1
X�2Rs
+R2
4Rs
+R4
�gm1
gm4
XX4�2R�
+γ
�gm1
Xo�2gm4R�α1
2α42 (3.3)
- 16 -
Fz' = 1+R1
R��gm2
X1�2α22
+γ
gm2
R�α22
F = 1 + (Fz - 1) + (Fz' - 1)
(3.4)
(3.5)
F = 1+R2
4R�
+R
�gm1
Xo�2Rs
+R4
�gm1
gm4
XoX4�2R�
+γ
�gm1
Xo�2gm4R�α1
2α42
+R1
R��gm2
X1�2α22
(3.6)
Equations (3.7 and 3.8) describe the noise factors of M1 at z and z' respectively and a term r is
defined as the ratio of these two noise factors as given in equation (3.9). Moreover, term r
signifies the fraction of noise of M1 cancelled at the output and for the condition of complete
noise cancellation, the value of r should ideally be equal to one.
Noise factor of M1 at z = � ���
� �−�����
��������||��
���
�g���X||r���4kTR�
(3.7)
Noise factor of M1 at z' = � ���
� � X2||Rs
X2||Rs+1 gm1⁄��
4kTR�
(3.8)
r = Noise of M1 at z
Noise of M1 at z'
(3.9)
3.4 A high gain reduced NF CMOS LNA employing novel noise
cancelling technique
Figure 3.6 shows schematic of the proposed LNA topology. In addition to the conceptual design
shown in Figure 3.4, extra gain stages i.e. resistive feed forward cascode CS stage marked by ‘A’
are added to improve the overall signal gain and bandwidth of amplifier. Additionally, noise
cancellation is achieved by combining the outputs of these gain stages with an adder circuit.
- 17 -
Figure 3.6: Proposed LNA with noise cancellation technique (biasing not shown)
Realization of analog RF adder: Figure 3.7 shows schematic of an analog RF adder which is
realized with a pair of complementary transistors. In this circuit, small signal modulated currents
generated by the signals at the gate of the transistors flow through the load which results in
addition of signal voltages across load. Moreover, the addition of small signal transistor currents
results in addition of RF signal at the output. And, the voltage across the load is constituted by an
addition of signal voltages.
Mnv1
vo
Mpv2
ZL
vo
ZL
ron
ropip
in
Figure 3.7: Two transistor analog RF adder and its simplified small signal equivalent circuit
Let, v1 and v2 are the input signals applied to the gate terminal of the transistors, in and ip are
channel currents in NMOS and PMOS transistors respectively. From the small signal analysis of
adder circuit, the expression for output voltage (vo) is given in equations (3.10 – 3.12).
v = - (r�||r�||Z�)(i� + i�) (3.10)
- 18 -
v = - (r�
||r�||Z�)(g��
v��� + g��
v���) (3.11)
v = - (r�
||r�||Z�)(g��
v� + g��
v�) (3.12)
If ron || rop → high; ZL = 50 Ω and gmn = gmp = 20 mS then vo ≈ v1 + v2. But practical realization of
adder does not have gm1 ≠ gm2 ≠ 20 mS. So the output voltage of adder is not exact addition of
voltages from two branches which results in degeneration in amplifier gain and in noise figure as
well. Hence, there is a trade-off among impedance matching, gain and noise figure. Figure 3.14
and Figure 3.15 show AC and transient analysis results of designed adder which demonstrate the
addition phenomenon of two signals.
3.5 Results and analysis
The proposed noise cancelling LNA topology is designed for operating from frequency
range of 2.5 GHz to 4.5 GHz. Small size of M1 transistor demonstrates wideband input matching
characteristic. Transconductance (gm1) of M1 transistor is fixed at 20 mS for 50 Ω input
matching with bias current of 1.8 mA and L2 is 5.10 nH, which keeps input reflection coefficient
well below -10 dB over the entire range of 2.5 GHz to 4.5 GHz as shown in Figure 3.10. The gm
of M2 (43.53 mS), M3 (43.56 mS) and M4 (47.55 mS) are decided by considering the radio
frequency circuit design tradeoffs and cancellation of the noise of M1 at output. Simulated noise
figure plot is shown in Figure 3.8 and report minimum noise figures of 3.17 dB.
Figure 3.9 shows the circuit simulated power gain of 22.4 dB (average) in the frequency
range of 2.5 GHz to 4.5 GHz. Figure 3.11 compares simulated and theoretical noise figures
which shows a good agreement between both in range from 2.5 GHz to 4.5 GHz. However,
simulated noise figure value increases towards higher frequencies due to the noise contribution
of circuit and parasitic components that were not considered during NF analysis and are not
included in equation (3.6). The proposed circuit is unconditionally stable and stability plot is
shown in Figure 3.12. Third order intercept point (IIP3) is reported in Figure 3.13 which shows a
good linearity of -7.5 dB. Moreover, in this work an LNA is designed which exploits thermal
noise cancellation of its first stage CG transistor (M1). Equation (3.6) is used to get the plot for
theoretical noise figure as shown in Figure 3.11, which in turn is compared with the simulated
noise figure plot and they are found to be in close agreement near a frequency of 3 GHz. Table
3.1 and 3.2 present aspect ratios and performance comparison of LNA respectively.
- 19 -
Figure 3.8: Simulated noise figure plot for proposed LNA with noise cancellation
Figure 3.9: Simulated power gain plot for proposed LNA with noise cancellation
2
3
4
5
6
7
8
2 2.5 3 3.5 4 4.5 5 5.5 6 6.5
No
ise
Fig
ure
(d
B)
Frequency (GHz)
NF (dB)
3.17 dB
0
3
6
9
12
15
18
21
24
27
30
2 2.5 3 3.5 4 4.5 5 5.5 6 6.5
Fo
rwa
rd T
ran
smis
sio
n G
ain
(d
B)
Frequency (GHz)
S21 (dB)28.4 dB
- 20 -
Figure 3.10: Simulated input reflection coefficient plot for proposed LNA with noise cancellation
Figure 3.11: Simulated and theoretical noise figure plots for LNA with noise cancellation
-30
-25
-20
-15
-10
-5
0
2 2.5 3 3.5 4 4.5 5 5.5 6 6.5
Inp
ut
Ref
lect
ion
Co
effi
cien
t (d
B)
Frequency (GHz)
S11 (dB)
3
3.5
4
4.5
5
5.5
2 2.5 3 3.5 4 4.5 5 5.5 6
No
ise
Fig
ure
(d
B)
Frequency (GHz)
NF Simulation
NF Theory
3.3 dB
- 21 -
Figure 3.12: Simulated stability factor plot for LNA with noise cancellation
Figure 3.13: Simulated IIP3 plot for proposed LNA
Figure 3.14: AC analysis of RF adder
0
100
200
300
400
500
600
700
800
1 2 3 4 5 6 7 8 9 10 11 12
Sta
bil
ity
Fa
cto
r (K
)
Frequency (GHz)
Stability Factor (K)
19.4 18.1
-60
-50
-40
-30
-20
-10
0
10
20
30
-50 -45 -40 -35 -30 -25 -20 -15 -10 -5 0
Po
ut
(dB
m)
Pin (dBm)
Fundamental
Third Order
Input Referred IP3 = -7.5 dBm
0
1
2
3
4
1E+09 1E+10
Ou
tpu
t V
olt
ag
e (d
B)
Frequency (Hz)
Vout (dB)
- 22 -
Figure 3.15: Transient analysis of RF adder
Figure 3.16: Layout of the proposed LNA
-200
-150
-100
-50
0
50
100
150
200
0 200 400 600 800 1000 1200 1400 1600 1800 2000
Vo
lta
ge
(uV
)
Time (nS)
Vout V1, V22
00
uV
32
5uV
- 23 -
Table 3.1: Aspect ratios and parameter values of proposed circuit
Parameter Value Parameter Value Paramter Value
(W/L)1 80 µm/ 0.18 µm L1 3.88 nH Vdd 1.8 V
(W/L)2, 3, 4, 5, 7 120 µm/ 0.18 µm L2 5.10 nH Vb1 600 mV
(W/L)6, 8, n, p 100 µm/ 0.18 µm L4 3.88 nH
Rf 6 K L5 1.93 nH
Lo 9.13 nH L6 1.93 nH
3.5.1 Performance summary
Table 3.2: Performance summary of the noise cancelling LNA
Parameter Without Noise
Cancellation [21]
With Noise Cancellation
Pre Layout Post layout
Frequency (GHz) 3.1 ~ 10.6 2.4 ~ 9.0 2.4 ~ 4.5
S11 (dB) < -10 < -10 < -10
S21 (dB) 17.70 (av.)
21.60 (max) 24.24 (av.)
28.49 (max) 22.40 (av.)
28.40 (max)
NF (dB) 4.09 3.16 3.17
IIP3 (dBm) -7.32 -7.34 -7.50
Technology 0.18 µm CMOS 0.18 µm CMOS 0.18 µm CMOS
- 24 -
3.6 Conclusion and limitations
A CMOS CG LNA in 2.5-4.5 GHz range has been demonstrated in a standard TSMC 0.18 µm
CMOSRF technology and analysis of all noise contributing sources is performed. Moreover, a
noise cancelling technique is implemented in order to cancel the noise, contributed by major
noise source. This results significant reduction of 22.49% in noise figure with the proposed
topology when compared to LNA without noise cancelling technique. A peak power gain of 28.4
dB and base NF of 3.17 dB with good stability and linearity is achieved over the 2 GHz
spectrum.
- 25 -
Chapter 4
Other Work on Low Noise Amplifier
Overview: This part of the work focuses on a broadband design of low noise amplifier. Hence, a CMOS
UWB LNA is designed with shunt-series inductive peaking and interstage matching. This design includes
inductive source degeneration cascode topology with interstage matching network. Additionally a
Chebyshev band pass filter at the input and shunt-series inductive peaking at the output are placed which
provide better impedance matching and improved power gain.
4.1 Introduction
Inductive source degeneration with cascode transistor LNA is very popular architecture for
CMOS RF integrated circuit and microwave circuit design [30]. In this type of LNA architecture,
cascode transistor reduces the miller effect and improves reverse isolation. As in LNA design,
virtual gate drain capacitance of first stage i.e. miller capacitance [CM = Cgd (1+Av1)] limits the
bandwidth at high frequency to 1/RCM where CM gets amplified by its own gain (Av1). Therefore
cascode transistor protects from direct shorting of input and output through this capacitance.
Moreover, an inductor can be used for further isolation between two stages [31]. Inter-stage
inductor causes reduction of input impedance of second stage, resulting in more current pump
towards output [32]. This work implement a design of UWB LNA which include interstage
matching network to carry forward desired signal with the stoppage of undesired signal. And, also
includes a Chebyshev band pass filter for input matching and shunt-series inductive peaking
network at the output to boost the desired signal power. Simulation work is done with TSMC 0.18
µm CMOS technology using Cadence SpectreRF tool.
4.2 A CMOS LNA with Peaking and Interstage Matching
A simplified schematic design of the UWB LNA is shown in Figure 4.1. All components in the
figure are integrated on-chip with CMOS technology. A second order Chebyshev band pass filter
is used in this design for better input matching in the desired range. Inductor LG2 and capacitor Cg
are connected to couple the output of the first stage to the second stage. The inductance LM is
large enough in the frequency range of interest to block the path from M1 to M2. These passive
networks in between two stages are designed in such a way that desired signal can carry forward
- 26 -
towards output and undesired signal should bypass to ground. Inductors at the output show shunt-
series peaking and compensate the gain roll-off of the amplifier which improves the linearity as
well. A buffer stage is also added at the output.
L2
Vin
Cpad
C1
C2LS
Cp
Lg
Cg
LG2
M1
LM Cby
LLD
RLD
M3
M2
Vb1
Vb2Vout
ZO
CpadIm
L1
LP
VS
Figure 4.1: Simplified schematic of UWB LNA
4.2.1 Input impedance matching stage
Figure 4.2 shows the equivalent circuit for input impedance matching network. The inductors
and capacitors network form a second order Chebyshev filter whose pass band is 3.1 GHz to 10.6
GHz. The input impedance of matching network is given by equation (4.1).
Zin1' =
Zin1
W(s)=
ωTLs
W(s)
(4.1)
Where W(s) is the transfer function of the filter which is equal to Zin1/Z`in1. |W(s)| is
approximately unity in the pass band and tends to zero out of band. The input impedance of the
amplifier is equal to ωTLS in the pass band and it is very high out of band. Zin is input impedance
of amplifier without extra LC network at the input which follows relation Zin = ωTLS = Zo under
resonance condition ωo = 1 / [(Lg+LS)Ct]½. Here Lg and LS are inductors connected at the gate and
source of M1, Ct is total capacitance connected between gate and source terminals of M1; where Ct
is equal to Cgs1+Cp. Unity current gain frequency ωT is equal to gm/Cgs1 for M1. From equation
(4.1), matching of input impedance equal to Zo is obtained for entire band of interest. Assume that
the ripple in the pass band is ρ and then the input reflection coefficient can be expressed as (1-
1/ρ). To achieve the reflection coefficient less than -10 dB, equation yields ρ < 0.5 dB. We can
- 27 -
derive the component values for this second order Chebyshev filter using a standard filter
formulas tool.
L2C1
C2
Lg
ZO
LS
WT*LS
Ct=Cp+Cgs1
Cgd1
L1
Figure 4.2: Equivalent circuit of input impedance matching network
4.2.2 Interstage matching
Figure 4.3 and Figure 4.4 are small signal equivalent circuits for interstage impedance
calculation. Inductor LG2 and capacitor Cg are connected between drain of M1 and gate of M2
which couples output of first stage to input of second stage. The resonance circuit composed of
LG2, Cg, Cgs2 and bypass capacitor (Cby) present narrow band characteristics. Therefore second
stage gain is maximized at around resonance frequency which may affect the linearity of overall
gain and bandwidth.
Cgs1/gm2
Zin1 Zin2 Zo1
CgCby
Zin1'
rds1
Filter
Tr.Func.
= W(s)
gm1Vgs
LG2
LS
LM
VgsZO
Cgs2LC-Network
Figure 4.3: Equivalent circuit of UWB LNA with matching networks
Ix
Vx I1
Zin2
LM
Cby1/gm2
Cgs2
LG2
Cg
Ix-I1
Figure 4.4: Equivalent circuit of input impedance of second stage
- 28 -
Inductor LM value is fixed in such a way that it should provide a high impedance path for desired
signal from first stage and low impedance path for undesired signal. Resonance circuit formed by
LM and Cby resonates outside the frequency of interest. LG2 and Cg values can be selected
independent of LM when LM exceeds a certain value on which resonance started outside the
frequency of interest. Inductors LP, LLD and resistor RLD form shunt series peaking circuit which is
responsible to enhance the bandwidth and linearity of LNA. Charging of load capacitance speeds
up due to LLD and initially transistor has to drive its own output capacitance for some time
because LLD and LP delay the current [33]. Expression for output impedance (Zo1) of first stage
looking at the drain of M1 is given in equation (4.2) [32].
Zo1 = 2rds1 + jωo
ωT
Zo+ ωo
2
ωT
Ls (4.2)
Where resistive part (2rds1
+ ωo2 ωT⁄ Ls) is very high and reactive part is small when Cgd is
neglected. For the calculation of second stage input impedance Zin2, looking away from the drain
of M1 as shown in Figure 4.4. Let Vx, Ix be voltage and current at input of second stage and Ix is
divided into branches as I1 and (Ix ̶ I1). Voltage across Cg and LG2 is written in equation (4.3).
Vx = I1 (1
sC𝑔+sLG2) (4.3)
Voltage across LM, Cby, 1/gm2 and Cgs2 is written in equation (4.4). A simplified expression for
Zin2 is given in equation (4.5) which can be deduced by further solving equations (4.3 and 4.4).
Vx= (Ix-I1) (sLM+1
sCby
||1
gm2
||1
sCgs2
) (4.4)
Zin2 = 1
[y-1+ (1
sCg+sLG2)
-1
]
(4.5)
Where ωT2 = gm2 / Cgs2 and y = (sLM + 1
sCby||
1
gm2
||1
sCgs2)
In equation (4.5), Zin2 has only resistive value which can be calculated by substituting a proper
value of ωT2. The approximate value of Zin2 is less than 1/gm2 which causes more current
pumping into the second stage, thus improving forward transmission performance.
- 29 -
4.2.3 Shunt-series inductive peaking and gain stage
The total gain of the proposed LNA is equal to the product of the gain of the first and second
stages. Compared with the gm of the transistor, the effective transconductance (Gm) is more
suitable parameter to estimate the gain performance of the radio frequency amplifier. The
parameter Gm is defined as the amplitude of the output current (iout) flowing into the load, divided
by the input voltage (Vin) of the amplifier. The Gm is proportional to the gm of the input transistor
and the proportional coefficient depends on the input matching network. Gm of the second stage is
gm2 straightforwardly. From Figure 4.3, the gate-source voltage (Vgs) of M1 is equal to VinW(s) /
sCtωTLS. Therefore Gm of the first stage (Gm1) can be expressed as given in equation (4.6).
Gm1=im1
Vin
=g
m1W(s)
sCtω𝑇L𝑆=
gm1
W(s)
sCtRs
(4.6)
The equivalent circuits of the loads of first and second stages are shown in Figure 4.5 and Figure
4.6. From Figure 4.5, the load impedance of first stage (ZL1) is written in equations (4.7 - 4.9).
ZL1=Vout
im1
(4.7)
=[ (sLG2+1
sCg+
1
sCgs2) || {(sLM+RM)+
1
sCby}]||
1
sCpar
(4.8)
=RM+sLM
(RM+sLM)+(sLG2+1
sCg+
1
sCgs2)×
1
sCgs2
(4.9)
where RM is the parasitic resistor of inductor LM and Cpar is the total parasitic capacitance at the
drain of transistor M1.
Im1
CparLM
RLD
LG2 Cg
Cgs2
Cby
Im2
CX RLD
LLD
CLVout
Figure 4.5: Load of first stage Figure 4.6: Load of second stage
- 30 -
Practically, the capacitance Cby in Figure 4.1 is chosen to be large enough so that the source of
the transistor M2 can be seen as AC ground. If LM and RM exhibit higher impedance than LG2, Cg
and Cgs2 in series, the resonance frequency is mainly determined by the LG2 and Cg. Note that the
resonance presents a narrow band characteristic. Therefore, the gain is maximized near the
resonant frequency which is designed to enhance the gain at the middle of the desired band.
The staggered-compensation series peaking technique as in [34] is adopted for reference. This
work implements shunt-series peaking in the second stage to compensate for the high frequency
gain roll-off. The equivalent circuit of the load of second stage is shown in Figure 4.6. The load
impedance of the second stage can be written as in equation (4.10).
ZL2 = Vout
im2
=RLD
1+sRLD(Cx+CL)+s2LLDCL+s3LLDCxCLRLD
(4.10)
Where Cx is the total parasitic capacitor at the drain of the transistor M2, and CL is the total
capacitor at the input of the buffer. LLD and LP resonate with Cx, thus the response shows a peak at
resonance frequency which compensates the gain roll-off of the amplifier at high frequency.
Combining the gain versus frequency characteristic of the two stages, the gain flatness can be
achieved over the entire bandwidth.
4.2.4 Noise Analysis
In the proposed LNA, the noise of the second stage is reduced by the gain of the former stage
and the overall noise performance of LNA is dominated by the first stage [35]. The two main
noise contributors of the first stage are the losses of the input matching network and the transistor
M1. The expression for noise factor F(w) of the amplifier is written in equation (4.11) and the
detail derivation can be seen in [12].
F(w)=1+P(w)γ
GmRsα (4.11)
Where
P(w)=(ραχ)2(1-|c|
2)
1+2|c|ραχ+(ραχ)2
+(wCtRs)2(1+ 2|c|ραχ+(ραχ)
2)
(4.12)
χ=δ
5γ; ρ=
Cgs
Ct; α=
gm
gd0
(4.13)
In equation (4.12), “c” is correlation coefficient between the gate noise and the drain noise, δ and
γ are the excess noise parameters and α accounts for short channel effects. For CMOS devices, δ ≈
- 31 -
4, γ ≈ 2, α ≈ 0.85 and c ≈ 0.4j [33]. Equation (4.11) shows that increasing the transconductance
improves the noise performance while keeping all other parameters constant. Simulation reveals
that, for a given current budget there is a value of M1’s width that yields the best noise figure over
the bandwidth. For further analysis, a noise model of the input matching network is shown in
Figure 4.7.
RL1
L1 C1
C2L2
RL2
Lg+LS RLgLs
ZO=WT*LS
Ct
enRLgLsenRL1
ens
ZO
enRL2
enin
Figure 4.7: Noise model of the input matching network
The L1 and C1 are components of the Chebyshev filter. RL1 is the parasitic resistor of L1, RL2 and
RLgLs are the parasitic resister of L2 and Lg + LS. Voltage source enRL1, enRL2 and enRLgLs represent
the thermal noise generated by resistors RL1, RL2 and RLgLs. Transfer Functions for these noise
sources are written in equations (4.14 – 4.16).
TFRL1=enin
enRL1=
W(s)
[W(s)+1]sCtRs
(4.14)
TFRL2=enin
enRL2=
(1
sC2) ||Zgs||Z1
Z2+ (1
sC2) ||Zgs||Z1
×1
Zgs(sCt)
(4.15)
TFRL2=enin
enRLgLs=
1
Zgs+ (1
sC2) ||Z1||Z2
×1
(sCt)
(4.16)
Where Z2=sL2+RL2; Zgs=s(Lg+Ls)+RLgLs+1
(sCt)+Zo; Z1=sL1+RL1+
1
(sC1)+Zo
Where W(s) is filter transfer function and Z1= Zo for the second order Chebyshev filter. The noise
contribution from the passive devices of the third order filter is much larger than that of their
second order counterpart, so a second order Chebyshev filter is more suitable to shoot for low
noise.
- 32 -
4.3 Simulation Results:
This section include simulation results of UWB LNA. Noise figure in Figure 4.8 shows an
excellent performance of 3.42 dB to 6.85 dB in frequency range of 3.1 GHz to 10.6 GHz. As
shown in Figure 4.10, the power gain ranges from 11.11 dB to 17.12 dB over the entire bandwidth
of interest. This result also shows a gain roll-off at higher frequencies which is due to the shunt-
series inductive peaking. Figure 4.9 presents input reflection coefficient, in which, well matched
S11 over the entire range of 3.1 GHz to 10.6 GHz demonstrate a successful design of input
matching network. Table 4.1 summarizes the performance of designed UWB LNA. Layout of the
UWB LNA is shown in Figure 3.11 which occupies 0.9 mm x 1 mm area. Simulations are done
with TSMC 0.18 µm CMOS technology.
Figure 4.8: Simulated noise figures of UWB LNA
2
3
4
5
6
7
8
2 3 4 5 6 7 8 9 10 11
Nois
e F
igu
re (
dB
)
Frequency (GHz)
- 33 -
Figure 4.9: Simulated input reflection coefficients
Figure 4.10: Simulated forward transmission gains
Figure 4.11: Layout of the UWB LNA
-30
-25
-20
-15
-10
-5
0
2 3 4 5 6 7 8 9 10 11
S1
1(d
B)
Frequency (GHz)
0
2
4
6
8
10
12
14
16
18
20
2 3 4 5 6 7 8 9 10 11 12
S2
1(d
B)
Frequency (GHz)
- 34 -
Table 4.1: Performance summary of the UWB LNA
Parameters Freq
(GHz)
Gain
(dB)
NF
(dB)
S11
(dB)
Power
(mW)
Values 3.1-10.6 11.11-17.12 3.4-6.7 < -10 11.2
4.4 Conclusion and limitations
The design and simulations of an ultra-wideband low noise amplifier for 3.1 GHz to 10.6 GHz
is presented. The design employs Chebyshev band pass filter for input matching and interstage
matching network to carry forward the desired signal with bypassing the undesired signal. Also a
shunt-series inductive peaking network is used to compensate the gain roll-off at higher
frequencies. The UWB LNA provides peak power gain 17.12 dB and minimum noise figure 4.4
dB within the bandwidth of 3.1 GHz to 10.6 GHz. This LNA also demonstrate a good input
matching i.e. well below -10 dB in entire bandwidth. LNA consumes 11.2 mW with 1.8 V supply
and occupies 1 mm x 0.9 mm of layout area.
- 35 -
Chapter 5
Layout Technique
Overview: This chapter highlights major layout techniques which was considered during the
implementation of low noise amplifier layout design. It is observed that the proper layout technique can
significantly change the post layout simulation results.
Following are some important and noticeable facts which are observed during my layout design
experience and should be considered by layout designers for effective layout outcome. Layout
examples are kept at the end of this chapter.
In initial floor planning of layout, large size components i.e. inductors are placed properly
because later it is most difficult to change place of such components.
While fixing inductors space it is necessary to keep in mind that power supply connection
wires should be thick and smaller in length. In this layout, power supply connection to
inductors are done with more thicker top layer metal and inductors are placed in such a way
that its suppl y terminals are near to supply pad which require lesser length of supply wire.
This way parasitic resistance caused by high current density wire can be reduced significantly.
Six metal layers are used for routing which is planned in the following ways:
Metal-6 for Vdd or supply
Metal-5 for Gnd
Metal-4 for RF Signal
Metal-3 for RF Signal
Metal-2 for Gnd
Metal-1 for Vdd or Supply
Poly should never be used for routing because it causes large resistance which can influence
overall result performance as it is shown in Figure 5.1 results large noise figure of 48dB.
There should be metal connection immediately after poly while routing gate terminal of the
transistors as shown in Figure 5.2.
Vias resistance can be reduced if multiple parallel vias are used instead of single via.
Improvement in result can be seen in Figure 5.4.
Isolate the large transistors with guard ring to avoid noise coupling with unwanted circuitry
and are placed around the transistor as shown in Figure 5.2. This can immobilize the
substrate/bulk/well potential when it is connected to ground. For n-channel, transistor guard
- 36 -
ring made of p-active (p+) material is used. For p-channel, transistor guard ring made of n-
active (n+) layer is used. These active materials are connected to metal-1 through multiple
vias, which is routed until ground.
Transistor fingering is done to avoid large gate parasitic as shown in Figure 5.1 and Figure
5.2.
During place and route it is observed that if we keep most dominating noise source i.e.
transistor M1 far from input terminal, connecting wire parasitic resistance adds significant
noise to overall circuit performance. Hence placing of M1 transistor near to input terminal is
better. Improvement in result can be seen in Figure 5.5.
A resistance connected to transistor M1can add significant parasitic resistance hence it should
be placed near to transistor as shown in Figure 5.5.
The width of the supply lines is based on the resistivity of the metal used for routing the
supply. In this layout, supply wires are connected by top metal layer as shown in Figure 5.6.
The convention in IC design for resistance (or parasitic resistance) calculation is to
characterize each conductor layer in terms of resistance per “square”. One “square” is defined
as the condition when the length of the conductor equals the width.
The formula for calculating the resistance of a conductor is R = ρL/W, where R is the
resistivity of the layer measured in Ω/□, L is the length, and W is the width of the conductor.
ρ is a material property and characteristic of the manufacturing process which cannot be
controlled by the layout designer.
From this formula it is apparent that there are two ways to minimize the resistance of a wire.
(i). Reduce the length of the wire.
(ii). Increase the width of the wire.
Above is important for good design practices which can reduce resistance for various layout
design styles.
A transistor in CMOS is made of source (active), gate (poly-silicon), and drain (active)
regions, but to make it work we need signals connected to all three terminals. Thus, contacts
to the source and drain are important to consider. From layout experiments, it is observed and
is interesting to note that the active resistance is dominant and is 1,000 times more resistive
than metal-1 and 10 times more resistive than a metal-1 contact. These numbers give us a
good starting point for minimizing the overall resistance from the two metal lines i.e. try to
minimize the active resistance.
The contacts are three-dimensional columns of metal or poly, and they add to the resistance of
paths. The number of contacts in any connection is important to consider, because for each
contact the resistance is reduced by introducing another parallel current path from the
conductor. This is especially important for high current carrying signals such as power
supplies. Transistor with more number of contacts can be consider as lowest resistance
- 37 -
configuration of transistor and achieves highest reliability. Performance and reliability in RF
circuits such as low noise amplifier is important, so to make use of fully contacted transistor
is preferable. In LNA layout design, fully contacted transistor model provided by TSMC is
used.
Selection of resistance depends on the layer used in it. An appropriate choice of layers
possible by considering the following factors:
• Resistivity of the various layers
• Variation in resistivity under different temperature conditions
• Variation in layer area under different process conditions
• Area of resistor for chosen layer
In most cases gate poly is chosen as the resistor material, as its resistance is relatively high,
the resistivity and width are tightly controlled, and the resulting area is reasonable. In this
layout typical poly resistors are used. Parasitic in it arises due to the effect of contact
resistance. These are more area efficient solutions, as they sometimes have to fit in the areas
of transistors without using too much space. The disadvantage of such resistors is that the
resistance is not easily calculated because of the corners in the poly layer. As a best
approximation, we can use the centerline of the poly divided by the width to calculate the
total resistance of the line. In RF layout designs, we may have to shield the resistor fingers
from itself to avoid coupling. In LNA layout such resistors are used.
Capacitance affects several different characteristics of a design. When two equivalent designs
are compared, the design with the higher capacitance will have a resulting increase in signal
delay, power consumption, coupling effect to and from neighboring structures. A review of
the definition of capacitance gives an understanding how good design practices reduce
capacitance for various layout design styles.
The general formula for the calculation of the capacitance of a conductor is C = ɛA/d,
where A is the surface area of the specific conductor layer, d is the physical distance between
the conductor layers, and ɛ is a constant representing the characteristics of the insulating layer
between the conductor layers. From this formula it is apparent that there are two ways to
minimize the capacitance of a signal: (1). Reduce the area of the capacitor, this means
reducing the overlapping regions of the two plates or wires. (2). Increase the distance
between the plates of the capacitor. An array of capacitors is good way of layout instead of
big size single capacitor as shown in Figure 5.3.
Following are figures demonstrating different layout examples and response results:
- 38 -
Figure 5.1: Transistor fingering and poly routing with its response
Figure 5.2: Metal connection immediately after poly with its response
Figure 5.3: Array of capacitors connection
- 39 -
Figure 5.4: Single and multiple parallel vias with its response
Figure 5.5: Placing of M1 transistor near to input terminal
- 40 -
Figure 5.6: Supply wires routed with top metal layer
Figure 5.7: Wide wires connected to input transistor
- 41 -
Chapter 6
Summary and Conclusions
This chapter summarizes the content of this thesis and draws conclusions with few
recommendations for future research.
6.1 Summary
This thesis deals with the design and implementation of CMOS low noise amplifier for wireless
receiver with the aim of reduction in thermally generated noise and improvement in gain. A
detailed study of various existing design topologies of narrow band, wide band and noise
cancelling low noise amplifiers is done. The study includes, common source amplifier with
resistive load, inductive load, cascode configurations and resistive feedback configurations. And
for wideband applications, common gate, distributed and LC-filter amplifiers are discussed.
Moreover, few noise cancelling LNAs such as feed forward, common gate-common source,
inductor-less cross coupled amplifier are explored. It is observed that noise cancellation
techniques usually do not consider much about gain improvement.
There are active and passive components available in low noise amplifier circuits which can
contribute its thermally generated noise to the overall thermal noise in LNA. The contributions
of thermal noise vary with respect to the operating frequency. Hence, an investigation of major
noise sources is performed in a three stage common gate low noise amplifier. Thereafter, a novel
noise cancelling technique with theoretical analysis is proposed. This noise cancelling technique
is able to cancel the noise of most dominating thermal noise. A complete design of low noise
amplifier employing proposed noise cancelling technique is implemented which not only reduces
the noise but also increases the gain.
Additionally, an improvised design of LC-filter amplifier for UWB range is implemented. For
input impedance matching in the frequency range of 3.1 GHz to 10.6 GHz, a Chebyshev band
pass filter is designed with the help of filter design tool, thereafter, implemented on Cadence.
Interstage passive network is added which can pump more current towards output in the
frequency range of interest and bypass the undesired frequency band signals. So LNA is
designed with shunt-series inductive peaking and interstage matching. Theoretical analysis with
small signal equivalent models of input impedance matching, interstage matching and shunt-
series inductive peaking stages are presented. Moreover, the gain and noise models with derived
equations of different stages are described. The design and analysis includes inductive source
degeneration cascode topology with interstage matching network which provide better
- 42 -
impedance matching and improved gain.
6.2 Conclusions
During investigation of major noise sources, it is found that the thermal noise of
matching device is the most contributing source of noise. For the entire range of UWB,
the matching device contributes 42% of overall noise and approximately remains flat in
whole range. Second stage common source transistor contributes 22% for the entire range
and its noise contribution is more near the corner frequencies. This is due to the
restriction of narrow band characteristics of common source amplifier while common
gate amplifier shows wide band characteristics and its noise contribution is almost equal
(2.8 ± 0.3) dB for the entire range.
In order to cancel the noise generated by matching device, a novel noise cancelling LNA,
operating from 2.5 GHz to 4.5 GHz is designed which simultaneously amplifies the RF
signal. This results significant reduction of 22.49% in noise figure with the proposed
topology when compared to LNA without noise cancelling technique. Required equations
for overall noise factor and condition for noise cancellation are derived. Ultimately, peak
power gain of 28.4 dB and base NF of 3.17 dB with good stability and linearity is
achieved over the 2 GHz spectrum.
The design and simulation of an ultra-wideband low noise amplifier for 3.1 GHz to 10.6
GHz is presented. The design employs Chebyshev band pass filter for input matching and
interstage matching network to carry forward the desired signal with bypassing the
undesired signal. Also a shunt-series inductive peaking network is used to compensate
the gain roll-off at higher frequencies. The proposed LNA provides peak power gain
17.12 dB and minimum noise figure 3.4 dB within the bandwidth of 3.1 GHz to 10.6
GHz. This LNA also demonstrate a good input matching i.e. well below -10 dB in entire
bandwidth. LNA consumes 11.2 mW with 1.8 V supply and occupies 1 mm x 0.9 mm of
layout area.
Effective layout design techniques are described at the end of this thesis. These
techniques were followed during the layout deign of proposed low noise amplifier.
A survey of various LNA design topologies is also done.
6.3 Recommendations for future research
In this thesis, the noise cancellation of major noise contributing source i.e. matching
device is targeted. Additionally, a new and improved circuit is expected which can also
cancel the noise contribution by second major thermal noise source i.e. second stage
common source transistor’s noise. A new noise cancelling circuit can be proposed which
- 43 -
should target and cancel the noise of this device at lower and upper corner frequencies, as
common source transistor shows narrow band characteristic.
Future research can be done on investigation and cancellation of major noise sources
available in various other topologies of CMOS LNAs.
A detailed study is needed for other methodologies to reduce the contribution of major
noise sources in overall noise figure.
Fabrication and characterization of proposed LNA is also a targeted task.
- 44 -
Appendix A
Additional Details of Noise Cancelling Mechanism and Noise Factor
Equations:
Descriptions on noise cancellation mechanism with conceptual diagrams are presented in chapter
3. Here, additional figures are given which clearly illustrate the flow of signal and noise with
varying phase at each node of the circuit. Idea of noise cancellation is drawn in Figure A.1, where
an amplification block at third stage is also added. Figure A.2 shows the phase of noise signal (N)
and RF signal (S) at each stage by mentioning the positive and negative signs.
RF Out
M1
M2
M3
M4
A
C
B
D
ERS
VS
Vb
2
1M,nI
2
1M,nV
A
A
Figure A.1: Idea of noise cancellation with additional gain block
- 45 -
M1
M2
M3
M5
M6Vb1
Vb3 Vb6
RF
Input
RF Out1
LoL1 L5
L2
M7
M8Vb8RF Out2
L6
M4
L4
Rf Rf
RF Out1
RF Out2
RF
Output
‘A’ ‘A’
S+
N+
S+
N-S
- N
+
S+
N-
S- N
-
S+
N+
S+
N-
S+
N+
S+
2ni2
nv
Figure A.2: Proposed noise cancelling LNA with phases of noise signal and RF signal at different nodes
M1
Xo
M4
Rs
X4
Z
X2
(a)
M2
M3
Rs
X1
Z'
X2
1/gm1
(b)
Figure A.3: Noise contributing components for noise figure calculation (a) left branch containing CG-CS
transistors (b) right branch containing CS-CG transistors
Major noise contributing sources are from first two stages of the noise cancelling LNA. Figure 4.5
shows the noise voltages from first two stage components. In order to calculate the noise figure
equations for these two branches and overall noise figure of the circuit, separated branches of the
circuit are drawn which are shown in Figure A.3.
- 46 -
Noise factor equations at node z:
(a.1)
Fz =1+ F(X2)+ F(M1)+ F(Xo)+ F(M4)+ F(X4) ; where
(a.2)
(a.3)
(a.4)
(a.5)
(a.6)
(a.7)
Noise factor equations at node z:
(a.8)
Fz' =1+ F(X2)+ F(M2)+ F(X1)+ F(M3)+ F(M1) ; where
(a.9)
- 47 -
(a.10)
(a.11)
(a.12)
(a.13)
(a.14)
Where is the fraction of thermal noise of M1 from gate terminal to source terminal,
Attenuation factors are as follows
(a.15)
(a.16)
(a.17)
(a.18)
On M1’s noise cancelling condition, considering the main factors from the above equations, the
- 48 -
effective noise factor of proposed low noise amplifier is given by equation (a.20).
(a.19)
(a.20)
- 49 -
Appendix B
Interstage Impedances in UWB LNA:
Inter stage passive components network form impedance match between first stage and cascode
stage of LNA. This results gain improvements and noise figure reduction. Results (equations) are
derived for output impedance of first stage and input impedance of cascode stage with and without
passive components network. This shows that output impedance of first stage (Zo1) is very high
and approximately resistive (~2rds), while input impedance of cascode stage with passive network
(Zin2’) is less than 1/gm2 which is a notable outcome to carry forward the desired signal towards
output. This effect more current pump into the cascode stage thus improving efficiency.
Expressions for input impedance and output impedance are derived of first and cascode stage when
(i) only inductor is connected between two stages and (ii) LC filter network is connected between
two stages.
(i): Inductor as an inter stage impedance network:
VBM2
M1
LS
LG
ZO
LM
Figure B.1: LNA with Inductor as an interstage impedance network
- 50 -
LG
LS
LM
ZOCgs Vgs gmVgs rds Cgs21/gm2
Zin1Zo1Zin2'
Figure B.2: Equivalent circuit for calculation of input and output impedances of two stages
Calculation of output impedance of first stage ( ):
LG
LS
ZOCgs Vgs gmVgs rds Vx
Ix
Ix
Icgs(Ix – gmVgs)
Ix[sLs/(Zo+sLg+sLs+1/sCgs)]
Figure B.3: Equivalent circuit for calculation of output impedance of first stage
Voltage across the gate and source terminal of M1 is given by below expressions.
(b.1)
(b.2)
- 51 -
(b.3)
+
(b.4)
(b.5)
(b.6)
(b.7)
At resonance:
(b.8)
(b.9)
(b.10)
(b.11)
(b.12)
- 52 -
Where resistive part ( ) is very high value and reactive part is small while Cgd is
neglected.
Where ;
Calculation of input impedance of cascode stage including inductor ( ):
LG
LS
LM
ZOCgs Vgs gmVgs rds Cgs21/gm2
Zin2Zin2'
Vx
Ix
Figure B.4: Equivalent circuit for calculation of input impedance of second stage
Applying KVL at second stage:
(b.13)
(b.14)
(b.15)
- 53 -
(b.16)
(b.17)
(b.18)
(b.19)
At resonance:
(b.20)
(b.21)
(b.22)
- 54 -
(ii): LNA with LC network between two stages:
VBM2
M1
LS
LG
ZO
LM
BPF
Cby
Cg
LG2
Figure B.5: LNA with LC network between two stages
LG
LS
LM
ZOCgs Vgs Cgs21/gm2
Zin1 Zin2 Zo1
Cg
LG2
Cby
BPF
Zin1'
rds1
Filter Tr.Func.
= W(s)
gm1Vgs
Figure B.6: Equivalent circuit for the calculation of input and output impedances of two stages
LM
Cgs21/gm2
Zin2
Cg
LG2
Cby
Ix
VxI1
Ix-I1
Figure B.7: Equivalent circuit setup for the calculation of input impedance of second stage
- 55 -
We have
Transfer function of filter
In the above expression, the value of transfer function of interstage LC filter W(s) is equal to zero
for out of band signals and one for in band signals. Hence, becomes very high for undesired
signals and equal to for desired signals.
(b.23)
The equation of is derived in section (i) which remains the same for this circuit too.
Calculation for input impedance of second stage ( ):
From the figure 4(b),
(b.24)
(b.25)
(b.26)
- 56 -
(b.27)
(b.28)
(b.29)
Let
(b.30)
(b.31)
(b.32)
- 57 -
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