lecture 7 amplifier design 1 - university of...
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ECE13712
Lecture PlanDate Lecture (Wednesday 2-4pm) Reference Homework
2020-01-07 1 MOD1 & MOD2 PST 2, 3, A 1: Matlab MOD1&22020-01-14 2 MODN + Toolbox PST 4, B
2: Toolbox2020-01-21 3 SC Circuits R 12, CCJM 142020-01-28 4 Comparator & Flash ADC CCJM 10
3: Comparator2020-02-04 5 Example Design 1 PST 7, CCJM 142020-02-11 6 Example Design 2 CCJM 18
4: SC MOD22020-02-18 Reading Week / ISSCC2020-02-25 7 Amplifier Design 1
Project
2020-03-03 8 Amplifier Design 22020-03-10 9 Noise in SC Circuits2020-03-17 10 Nyquist-Rate ADCs CCJM 15, 172020-03-24 11 Mismatch & MM-Shaping PST 62020-03-31 12 Continuous-Time PST 82020-04-07 Exam2020-04-21 Project Presentation (Project Report Due at start of class)
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ECE13713
Circuit of the Day: Cascode Current Mirror• How do we bias cascode
transistors to optimize signal swing?
• Standard cascodecurrent mirror wastes too much swing
VX = VEFF + VTVY = 2VEFF + 2VTMinimum VZ is 2VEFF + VT, which is VT larger than necessary
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ECE13714
What you will learn…• Choice of VEFF
Several trade-offs with Noise, Bandwidth, Power,…• Amplifier Topology• Amplifier Settling
Dominant Pole, Zero and Non-Dominant Pole• Gain-Boosting
Stability, Pole-Zero Doublet• Delaying vs. Non-Delaying stages
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ECE13715
Choice of Effective Voltage• Effective Voltage VEFF = VGS - VT
Assumes square-law modelIn weak-inversion, this relationship will not hold
• What are the trade-offs when choosing an appropriate effective voltage?
Noise PowerBandwidth MatchingLinearity Swing
D DEFF
m n ox
2I 2IV Wg C L
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ECE13716
Thermal Noise and VEFF
• Noise Current and Noise Voltage
• Ex. Common Source with transistor loadCS transistor has input referred noise voltage proportional to VEFF
Current source has input referred noise voltage inversely proportional to VEFF
2 4n mI kT g 2 4n
m
kTVg
2,1
42n EFF
D
kTV VI
2,12
,2
42
EFFn
D EFF
VkTVI V
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ECE13717
Thermal Noise and VEFF
• Total Noise
Use small VEFF for input transistor, large VEFF for load (current source) transistor
,12,1
,2
4 12
EFFn EFF
D EFF
VkTV VI V
B
IN
n,22
n,12
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ECE13718
Bandwidth and VEFF
• Bandwidth dependent on transistor unity gain frequency fT
If CGS dominates capacitance
Small L, large maximizes fTFor a given current, decreasing VEFF increases W, increases CGS, and slows down the transistor
• fT increases with VEFF
2 ( )m
TGS GD
gfC C
21.52
nT EFFf V
L
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ECE13719
Linearity and VEFF
• Look at distortion through a CS amplifierCompare amplitude of fundamental and second-order distortion term
• Linearity increases with VEFF
2
4HD A
F EFF
V VV V
2
2
1cos( ) 1 cos(2 )4n ox EFF A n ox A
F HD
W WI C V V t C V tL LV V
21 cos( )2D n ox EFF A
WI C V V tL
IN
OUT
D
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ECE137110
Power and VEFF
• Efficiency of a transistor is gm/IDTransconductance for a given current – high efficiency results in lower powerBipolar devices have gm=IC/Vt, while (square-law) MOS devices have gm=2ID/VEFF
• VEFF is inversely proportional to gm/ID
Increasing VEFF reduces efficiency of the transistorBiasing in weak inversion increases efficiency
-0.3 -0.2 -0.1 0 0.1 0.2 0.3 0.4 0.50
5
10
15
20
25
30
VGS-VT
g m/I D
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ECE137111
Matching and VEFF
• With low VEFF, transistor is in weak inversionWhat happens with mismatch in Vt?
• Use a current-mirror as an example with mismatched threshold voltages
IN OUT
t,1 t,2
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ECE137112
Matching and VEFF
• In strong inversion with Vt mismatch there is a quadratic relationship
1mV error in Vt is ~1% error in IOUT (for VEFF~200mV)
• In weak inversion with Vt mismatch there is an exponential relationship
1mV error in Vt is ~4% error in IOUT
2,2
2,1
( )( )
GS tOUT
IN GS t
V VII V V
,1,2 ,1
,2
GS tt tT
T
GS t
T
V VV VnV
nVOUTV V
IN nV
I e eI
e
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ECE137113
Swing and VEFF
• Minimum VDS of a transistor to keep it in saturation is VEFF
Usually VDS is VEFF + 50mV or more to keep ro high (keep the transistor in the saturation region)With limited supply voltages, the larger the VEFF, the larger the VDS across the transistor, less room for signal swing
• With large VEFF…Can’t cascode – reduced OTA gainStage gain is smaller – input referred noise is larger (effectively the SNR at the stage output is less)
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ECE137114
Speed-Efficiency Product• What is the optimal VEFF using a figure of merit
defined as the product of fT and gm/IDOptimal point at VEFF = 130mV in 0.18m
-0.3 -0.2 -0.1 0 0.1 0.2 0.3 0.4 0.50
50
100
150
200
250
300
VGS-VT
g m/I D
*fT
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ECE137115
Summary of Trade-Offs• Benefits of larger VEFF
Larger bandwidthHigher linearityBetter device matchingLower noise for current-source transistors
• Benefits of smaller VEFFBetter efficiency – lower powerLarger signal swingsBetter noise performance for input transistors
Good starting point: VEFF ~ VDD/10
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ECE137116
Amplifier Design - Topology
Topology Gain Output Swing Speed Power
Dissipation Noise
Telescopic Medium Medium Highest Low Low
Folded-Cascode Medium Medium High Medium Medium
Two-Stage High Highest Low Medium Low
Gain-Boosted High Medium Medium High Medium
From Razavi Ch.9
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ECE137117
Amplifier Errors• Two errors: Dynamic and Static
• Static ErrorsLimit the final settling accuracy of the amplifierCapacitor Mismatch (C1/C2 error)Finite OTA gain
1 2 1 2
2
2 1 2
11 ( ) /( ) 1 1/
1 ( ) /
O
I
V C C C C Az AV C zC C C A
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ECE137118
Amplifier Errors
• Dynamic Errors: Occurs in the integration phase when a ‘step’ is applied to the OTA
SlewingFinite bandwidthFeedforward pathNon-dominant poles
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ECE137119
Static Amplifier Errors• First look at frequency independent response
Static error term 1/A
• Example: 0.1% error at output (Gain = 4)C1 = 4pF, C2 = 1pF, CIN = 1pF
A > 6000 for 0.1% error
1 1
2 2
1 111 1/
O
I
V C CV C A C A
2
1 2 IN
CC C C
64 1O
I
VV A
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ECE137120
Dynamic Amplifier Errors
• What is the transfer function of this circuit?By inspection…Gain is -C1/C2Zero when VXsC2 = VXGmPole at Gm/CL,eff where CL,eff = C2(1-) + CL
2
1
,2
1
1O m
L effI
m
sCV C G
sCV CG
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ECE137121
Single-Pole Settling Error• Step response of 1st-order (unity-gain) system
Unit step through system
Inverse Laplace transform of
Step response is
Error is
Settles to N-bit accuracy in
1s
11 / unitys
1(1 / )unitys s
1 unityte
unityte
ln2unity
Nt
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ECE137122
Pole and Zero Settling Error• Step response, 1st-order with feedforward zero
Unit step through system
Inverse Laplace transform of
Step response is
Error is
Settles to N-bit accuracy in
1 /1 /
z
unity
ss
1s
1 /(1 / )
z
unity
ss s
1 unity unityt tunity
z
e e
unity unityt tunity
z
e e
ln(1 / )ln2 unity z
unity unity
Nt
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ECE137123
Effect of Zero on Settling• Zero slows down settling time
Additional settling term
Coefficient a function of feedback factor
• To reduce impact of feedforward zero…Smaller (one of the few advantages of reducing )Larger CL
unitytunity
z
e
, 2
2 2
// (1 )
unity m L eff
z m L
G C CG C C C
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ECE137124
Effect of Zero on Settling• Example of settling behaviour
= 1/2, CL = C2/2
0 0.2 0.4 0.6 0.8 1
0
0.2
0.4
0.6
0.8
1
1.2
Time (ns)
Ampl
itude
No Zerow/ Zero
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ECE137125
Two-Pole Settling Error• Dominant and non-dominant pole, 2nd-order sys.
(assumes p2 >> p1 = unity/A)
Unit step through system
Step response is dependent on relative values of unityand p2
3 Cases:Overdamped, p2 > 4unityCritically damped, p2 = 4unityUnderdamped, p2 < 4unity
2
2
1
1p unity unity
s s
1s
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ECE137126
Two-Pole Settling Error• Closed loop response of the amplifier
(ignoring zero, including 2nd pole)
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ECE137127
Two-Pole Settling Error• Overdamped, p2 > 4unity
2nd pole much larger than unity-gain frequencySimilar to 1st-order settling as 2nd pole approaches infinityStep response is
• Critically damped, p2 = 4unityNo overshootStep response is
1 At BtB Ae eB A A B
22 22 4
,2 2
p p unitypA B
2 21 2unity unityt tunitye te
𝝎𝒑𝟐,𝜷𝝎𝒖𝒏𝒊𝒕𝒚
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ECE137128
Two-Pole Settling Error• Underdamped, p2 < 4unity
Minimum settling time depending on desired SNR Increasing overshoot as p2 decreasesStep response is
2
2
222
2222
2
2
sin4
1 cos4 4
1
p
p
t punity p
t punity p
unity
p
e t
e t
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ECE137129
Two-Pole Settling• Example:
unity/2 = 1GHzp2/2 = 1GHz, 4GHz, 100GHz
0 0.2 0.4 0.6 0.8 10
0.2
0.4
0.6
0.8
1
1.2
Time (ns)
Ampl
itude
Critically DampedOverdampedUnderdamped
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ECE137130
Two-Pole Settling• Critically damped system settles faster than
single-pole system
0 1 2 3 4-120
-100
-80
-60
-40
-20
0
Time (ns)
Settl
ing
Erro
r (dB
)
Critically DampedOverdampedUnderdamped
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ECE137131
Two-Pole Settling• Underdamped system gives slightly better
settling time depending on the desired SNR
0 0.5 1 1.5 2-140
-120
-100
-80
-60
-40
-20
0
Time (ns)
Settl
ing
Erro
r (dB
)
p2=4unityp2=3.8unityp2=3.6unity
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ECE137132
Two-Pole Settling• For a two-pole system, phase margin can be
used equivalently
Critically damped: PM = 76 degreesUnderdamped: PM < 76 degrees
(45 degrees if p2 = unity)Overdamped: PM = 76 to 90 degrees
2118090 tan p
unity
PM
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ECE137133
Gain-Boosting• Increase output impedance of cascoded
transistorImpedance boosted by gain of amplifier AVOUT/VIN = -gmROUTROUT ~ Agmro
2
• Trade-offsDoes not require extra headroomAmplifier requires some power, but does not have to be very fast
IN
b
B
OUT
XL
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ECE137134
Gain-Boosting• Need to analyze gain-boosting loop to ensure
that it is stableCascade of amplifier A and source follower from node Y to node X
• Load capacitance at node YMay need extra capacitance CCto stabilize loop
IN
b
B
OUT
X
Y
CC
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ECE137135
Gain-BoostingAORIG: Original amplifier response without gain-boostingAADD: Frequency response of feedback amplifier AATOT: Gain-boosted amplifier frequency response
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ECE137136
Gain-Boosting• Stability of gain-boosted amplifier
For 1st-order roll-off, the unity-gain frequency of the additional amplifier must be greater than the 3dB frequency of the original stage
3dB < UG,A
(if 3dB > UG,A there will be a discontinuity in the 1st order roll-off between UG,A and 3dB)
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ECE137137
Gain-Boosting• 2nd pole of feedback loop is equivalent to 2nd
pole of main amplifierSet unity-gain frequency of additional amplifier lower than 2nd pole of main amplifier
UG,A < 2nd
• Only 45 degree phase margin if UG,A = 2ndUG,A ~ 2nd/3 for a phase margin of ~71 degreesUG,A ~ 2nd/4 for a phase margin of 76 degrees
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ECE137138
Gain-Boosting• Pole-zero doublet occurs at UG,A
Must ensure that this time constant does not dominate the settling behaviour
• Set 5 (3dB frequency of closed loop amplifier response) below UG,A
Ensures that time constant is dominated by 3dB frequency and not the pole-zero doublet
< UG,A
Final Constraint: 5 < UG,A < 2nd
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ECE137139
Pole-Zero DoubletZCL: Load CapacitanceZOUT: gain-boosted output impedance ~ (1+A)gmro
2
ZORIG: cascoded output impedance ~ gmro2
ZTOT: Total Output Impedance
1 2 3dB UG,A 5 2nd
ORIG
OUT
CL
pole-zero
TOT
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ECE137140
Pole-Zero Doublet• Why is this a problem?
Doublet introduces a slower settling component in the step responseStep response (where z and p are the doublet pole and zero locations, ~UG,A):
A higher-frequency doublet will always have an impact but will die away quicklyA lower-frequency doublet will not have as large an impact, but it will persist much longer
1 unity zt z p t
unity
e e
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ECE137141
Delaying vs. Non-Delaying Stage• Depending on the architecture and stage sizing,
this can be a power concernLarge CL reduces the power efficiency of an amplifierLarger amplifier results in a smaller feedback factor and reduced bandwidth
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ECE137142
Delaying Stage• Delaying
Following stage does not load the outputVery little CL on output of the amplifier
• Example:1st stage 4x larger than 2nd stage (C3 = 0 for delaying, C3 = C1/4 for non-delaying)Each stage has gain of 2 (C1/C2 = 2, C3/C4 = 2)
2 1, 3 1 3
1 2
( ) ( )INL eff IN
IN
C C CC C C C CC C C
, 1( ) m m
unity delayL eff IN
g gC C C
delay mP g
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ECE137143
Non-Delaying Stage• Non-Delaying
Following stage loads the outputApplicable in pipeline ADCs, sometimes (usually following stages much smaller, depending on OSR)Opamp is wasted during the non-amplifying stage (could power it down to save power)
• Example (continued):
Increase gm by 1.75 CIN increases by 1.75 (approximately the same bandwidth with 1.75x power)
for
, 1( )
1.75 1.5m m
unity non delayL eff IN
g gC C C
1.75non delay mP g ( ) ( )unity non delay unity delay
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ECE137144
Amplifier Stability• Both phases are important
Different loading on sampling and amplification phase
• Feedback factor is larger in sampling phase than amplification phase
Amplifier could potentially go unstable if it was originally sized for optimal phase margin in the amplification mode
• Non-Delaying stages are more susceptible to instability in sampling phase since a much smaller load capacitance is present
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ECE137145
Amplifier Stability• Example:
C1 = 2pF, C2 = 1pF, CIN = 1pFCL = 0.5pF (load of subsequent stage)
Delaying StageAmplification: unity = gm/3pFSampling: = 1/2, CL,eff = 1pF, unity = gm/2pFPhase Margin: 73 65 (assume same p2)
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ECE137146
Amplifier StabilityNon-Delaying Stage
Amplification: = 1/4, CL,eff = 1.25pF, unity = gm/5pFSampling: = 1/2, CL,eff = 0.5pF, unity = gm/1pFPhase Margin: 73 33 (assume same p2)
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ECE137147
Circuit of the Day: Cascode Current Mirror
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ECE137148
What You Learned Today• Choice of VEFF
Trade-offs with various parameters• Amplifier Topology• Amplifier Step Response• Gain-Boosting• Choice of Delaying/Non-Delaying Stages
Impact on stability of sampling/integrating phases