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A 30-GS/sec Track and Hold Amplifier in 0.13- µm CMOS Technology
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A 30-GS/sec Track and Hold Amplifier in 0.13-µm CMOS Technology Shahriar Shahramian Sorin P. Voinigescu Anthony Chan Carusone Department of Electrical & Computer Eng. University of Toronto Canada
description
A 30-GS/sec Track and Hold Amplifier in 0.13- µm CMOS Technology. Shahriar Shahramian Sorin P. Voinigescu Anthony Chan Carusone Department of Electrical & Computer Eng. University of Toronto Canada. Digital Equalizer. Photo Detector. ADC. Adaptive Equalizer. Equalized Data. T/H. - PowerPoint PPT Presentation
Transcript of A 30-GS/sec Track and Hold Amplifier in 0.13- µm CMOS Technology
A 30-GS/sec Track and Hold Amplifier in 0.13-µm CMOS
Technology
Shahriar ShahramianSorin P. Voinigescu
Anthony Chan Carusone
Department of Electrical & Computer Eng.University of Toronto
Canada
Introduction & Motivation I
Digital EqualizerPhoto
Detector
T/H
ADC
AdaptiveEqualizer
ClockRecovery
EqualizedData
• Equalization required at high bit rates
• Analog equalization up to 40 Gb/s
• Digital equalization is more robust and flexible
• Require full rate Track & Hold Amplifiers
Introduction & Motivation II• Demonstrated 40-GS/sec THA in SiGe BiCMOS
– fT and fMAX of 160 GHz
• CMOS technologies scaling to nanometre
– fT and fMAX exceed 200 GHz for in production CMOS
• CMOS is a serious contender for implementing
DSP based equalizers above 10 Gb/s
Introduction & Motivation III
• High speed
• Low dynamic range
• Requires diodes
• High speed
• Lower supply
• Isolation in hold mode
Diode Sampling Bridge Switched Emitter Follower
J. C. Jensen, et. al.CICC 02
S. Shahramian, et. al.CSICS 05
Introduction & Motivation IV
• Low supply
• Low speed due to
series CMOS RON
• Take advantage of
high speed CMOS
source follower
Series CMOS Sampler Switched Source Follower
I. H. Wang, et. al.Electronic Letters 06
This workCICC 06
0.13-µm CMOS Technology
• Simulated fT and
fMAX of 80 GHz
• 8 layer
metallization back
end with thick RF
top metal layers
• Available triple-well
CMOS transistors
• Available low
power (high VTH)
transistors
THA Block DiagramC
lock
TIACMLINV
CMLINV
CM
LIN
VClock Path
CS
CS
TIACS
Diff.Pair
Diff.Pair
Data Path
Inp
ut
Ou
tpu
t
T/HCS
DRV
DRV
Input Stage DesignTIA
Active loads
Improve open loop
Gain, T
Eliminating current
source transistor
reduces power
supply voltage
Input Stage DesignTIA
Signal matching
through resistive
feedback
Input Stage DesignTIA
50ΩT1
RZ F
in
Noise matching
through transistor
sizing
Input Stage DesignTIA
22C
o2oF
OPT
BGRG
R
Z
1
ω1R
1
ω
1W
Transistors biased
at J = 0.25 mA/µm,
increased noise
figure for higher
bandwidth
Input Stage DesignTIA
Simulated bandwidth: 30 GHzSimulated input integrated noise over 30 GHz: 0.5 mVrms
Inductors improve
bandwidth, input
matching and filter
high frequency
noise
Input Stage DesignTIA
Input Stage DesignTIA
CS
CS
Transistors Q1 and Q2 are diode-connected at DC and
therefore can bias the next CS stage
Switched source
follower for maximum
bandwidth
THA Stage DesignT/H
THA Stage DesignT/H
During Track, QSF acts
as a source follower
with current IT
THA Stage DesignT/H
During Hold, IT flows
through RL which turns
QSF off and isolates CH
THA Stage DesignT/H
QT and QH operate in
digital mode and
thus are biased at
J = 0.15mA/µm
High VTH devices are
used to drive QT further
into “OFF” region and
reduce leakage
THA Stage DesignT/H
QSF is implemented as a
triple well transistor to
reduce VEFF and lower
power supply voltage
THA Stage DesignT/H
A linear buffer drives the T/H block with 600mVPP
input and output swing
THA Stage DesignT/HDiff.
Pair
Capacitor Cfth is used to match QSF-CGS and thus cancel
input signal feedthrough during hold mode
THA Stage DesignT/HDiff.
Pair
A linear output driver provides signal to external
50Ω resistors and measurement equipment
THA Stage DesignT/HDiff.
Pair
DRV
DRV
Clock Distribution CMLINV
CMLINV
CMLINV
Converts a single-ended 30-GHz clock signal
to a differential signal with 750mVPP swing
Chip Micrograph
• Manufactured
using IBM’s
0.13µm CMOS
technology
• The circuit
operates from a
1.8V supply and
consumes 150mA.
1mm
1mm
TIA
CS
CML INV
TIA CS
DR
V
THA
Dif
f. P
air
Dif
f. P
air
CML INV
CML INV
Measurement Results: SP
Measurement Results: SP II
Time Domain
Frequency Domain I
Frequency Domain II
Frequency Domain III
Circuit Comparisonfsample
[GS/s]
Track BW
[GHz]
THD
[dB @ fin]
Supply
[V]
Power
[mW]
Process
[N / fT]
This Work 30 7 -30 @ 1GHz
-29 @ 7GHz
1.8 270 CMOS
0.13µm
I. H. Wang el. al.
Electronic Letters 06
10 N/A -24.7 @ 5GHz 1.8 200 CMOS
0.18µm
J. Lee et. al.
JSSC 03
12 14 -23.3 @ 12GHz -5.2 390 InP
120 GHz
S. Shahramian et al.
CSICS 05
40 43 -27 @ 20GHz
-29 @ 10GHz
3.6 540 SiGe
160 GHz
Y. Lu et. al.
BCTM 05
12 5.5 -52.4 @ 1.5GHz 3.5 700 SiGe
200 GHz
Conclusion• CMOS emerges as a contender for high speed
DSP based equalizers
• Discussed the design methodology for CMOS
switched source follower THA
• Demonstrated the first 30-GS/sec THA in CMOS
Acknowledgement• CMC for chip fabrication and providing CAD
tools
• NSERC for financial support
• OIT and CFI for equipment
• ECIT for providing the network analyzer
