analysis and design of analog integrated...
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Device-Level Noise Modeling(excerpts from Gray & Meyer text
Analysis and Design ofAnalog Integrated Circuits,
John Wiley)
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(ignore both of these)
“sho
t”
nois
e“Johnson”
noise
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Comments:•Voltage source representation is used for Series-connectedresistors•Current source representation is used for Parallel-connectedresistors…(discussion in class!)
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Z(frequency)
basically, input τRC of the circuit
Red=JohnsonBlue=Shot
Let’s look at just ONE TERM…
Basic gain expression (SQUARED)
Voltage divider expression at the input (SQUARED)
Johnson Noise for two resistorsin series (per unit BW)
Transfer Function for Johnson Noise
|Z|
RS rb
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Additional Noise Sources:•Bias Resistors (parallel)•Shunt-Shunt RF (parallel)
R1||R2 RFRF
Analysis: One needs to determine the transfer function for each noise source to the output and then SQUARE it in order to get the respective POWER relationship…
Typical numbers…IC, lowR’s, a bit high…
dominant term…IC and not resistors
If IC increases 10X,becomes 8.8x10-15
dominant term…resistors, not IB
![Page 6: Analysis and Design of Analog Integrated Circuitsstanford.edu/class/ee133/handouts/lecturenotes/lecture8_noise.pdf · 1 Device-Level Noise Modeling (excerpts from Gray & Meyer text](https://reader031.vdocuments.mx/reader031/viewer/2022022604/5b5e42d77f8b9af90c8b7972/html5/thumbnails/6.jpg)
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Determined by BW!
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Gain Expression (Transfer Function) SQUARED
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RS-eq+rb
R2eq
R2eq Req
Req
Rough Approximation of Open-Loop LNA (Shunt-Shunt Feedback):At output--Req=RL||RFAt input--make ONE equivalent noise resistor (RS-eq) that is in series with rbThe “transfer function” used to refer output noise to the input DOES NOT CHANGE…basically the parallel resistors (R1||R2||RF) are basically now part of new “ ”
Modified(per above discussion)
Z*
Z*
Z*
(see above comment about SQUARED)
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Mission Possible (in 1hr. +??)
1.5KΩand…(in your real design you’ll need to add C)
MI
MO
TL
50Ω −j122Ω(series connected)
SPAMReceiver
(a reminder that Mid-Term will ask you to do “Mission Possible” In-Class and in finite time)
RL_parallelL Cparallel
MI
50Ω −j122Ω
1.5KΩ
L
9V
CBIG
C
70K
Ω20
K Ω
140
Ω
(2V)
(1.4Vdc)
TL
MO
Q1 Equivalent Tank
MI
vs
AntennaLNA (equiv.)
Des
ign!
!
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Blocks for SPAM Receiver
BNC toANT
XO
LNAMixer
(SA 612)
IF Amp PLL(LM 565)
BNC toSpeaker
Antenna
Decoding
Lab 1
Lab 2
Lab 4
Lab 3