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Transcript of EE466: VLSI Design Lecture 7: Circuits & Layout. CMOS VLSI Design1: Circuits & LayoutSlide 2 Outline...
![Page 1: EE466: VLSI Design Lecture 7: Circuits & Layout. CMOS VLSI Design1: Circuits & LayoutSlide 2 Outline CMOS Gate Design Pass Transistors CMOS Latches &](https://reader033.fdocuments.us/reader033/viewer/2022061616/56649c4d5503460f948f2d4f/html5/thumbnails/1.jpg)
EE466: VLSIDesign
Lecture 7: Circuits & Layout
![Page 2: EE466: VLSI Design Lecture 7: Circuits & Layout. CMOS VLSI Design1: Circuits & LayoutSlide 2 Outline CMOS Gate Design Pass Transistors CMOS Latches &](https://reader033.fdocuments.us/reader033/viewer/2022061616/56649c4d5503460f948f2d4f/html5/thumbnails/2.jpg)
1: Circuits & Layout Slide 2CMOS VLSI Design
Outline CMOS Gate Design Pass Transistors CMOS Latches & Flip-Flops Standard Cell Layouts Stick Diagrams
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1: Circuits & Layout Slide 3CMOS VLSI Design
CMOS Gate Design Activity:
– Sketch a 4-input CMOS NAND gate
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1: Circuits & Layout Slide 4CMOS VLSI Design
CMOS Gate Design Activity:
– Sketch a 4-input CMOS NOR gate
A
B
C
DY
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1: Circuits & Layout Slide 5CMOS VLSI Design
Complementary CMOS Complementary CMOS logic gates
– nMOS pull-down network– pMOS pull-up network– a.k.a. static CMOS
pMOSpull-upnetwork
outputinputs
nMOSpull-downnetwork
Pull-up OFF Pull-up ON
Pull-down OFF Z (float) 1
Pull-down ON 0 X (crowbar)
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1: Circuits & Layout Slide 6CMOS VLSI Design
Series and Parallel nMOS: 1 = ON pMOS: 0 = ON Series: both must be ON Parallel: either can be ON
(a)
a
b
a
b
g1
g2
0
0
a
b
0
1
a
b
1
0
a
b
1
1
OFF OFF OFF ON
(b)
a
b
a
b
g1
g2
0
0
a
b
0
1
a
b
1
0
a
b
1
1
ON OFF OFF OFF
(c)
a
b
a
b
g1 g2 0 0
OFF ON ON ON
(d) ON ON ON OFF
a
b
0
a
b
1
a
b
11 0 1
a
b
0 0
a
b
0
a
b
1
a
b
11 0 1
a
b
g1 g2
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1: Circuits & Layout Slide 7CMOS VLSI Design
Conduction Complement Complementary CMOS gates always produce 0 or 1 Ex: NAND gate
– Series nMOS: Y=0 when both inputs are 1– Thus Y=1 when either input is 0– Requires parallel pMOS
Rule of Conduction Complements– Pull-up network is complement of pull-down– Parallel -> series, series -> parallel
A
B
Y
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1: Circuits & Layout Slide 8CMOS VLSI Design
Compound Gates Compound gates can do any inverting function Ex: (AND-AND-OR-INVERT, AOI22)Y A B C D
A
B
C
D
A
B
C
D
A B C DA B
C D
B
D
YA
CA
C
A
B
C
D
B
D
Y
(a)
(c)
(e)
(b)
(d)
(f)
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1: Circuits & Layout Slide 9CMOS VLSI Design
Example: O3AI Y A B C D
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1: Circuits & Layout Slide 10CMOS VLSI Design
Example: O3AI Y A B C D
A B
Y
C
D
DC
B
A
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1: Circuits & Layout Slide 11CMOS VLSI Design
Signal Strength Strength of signal
– How close it approximates ideal voltage source VDD and GND rails are strongest 1 and 0
nMOS pass strong 0– But degraded or weak 1
pMOS pass strong 1– But degraded or weak 0
Thus nMOS are best for pull-down network
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1: Circuits & Layout Slide 12CMOS VLSI Design
Pass Transistors Transistors can be used as switches
g
s d
g
s d
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1: Circuits & Layout Slide 13CMOS VLSI Design
Pass Transistors Transistors can be used as switches
g
s d
g = 0
s d
g = 1
s d
0 strong 0
Input Output
1 degraded 1
g
s d
g = 0
s d
g = 1
s d
0 degraded 0
Input Output
strong 1
g = 1
g = 1
g = 0
g = 0
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1: Circuits & Layout Slide 14CMOS VLSI Design
Transmission Gates Pass transistors produce degraded outputs Transmission gates pass both 0 and 1 well
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1: Circuits & Layout Slide 15CMOS VLSI Design
Transmission Gates Pass transistors produce degraded outputs Transmission gates pass both 0 and 1 well
g = 0, gb = 1
a b
g = 1, gb = 0
a b
0 strong 0
Input Output
1 strong 1
g
gb
a b
a b
g
gb
a b
g
gb
a b
g
gb
g = 1, gb = 0
g = 1, gb = 0
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1: Circuits & Layout Slide 16CMOS VLSI Design
Tristates Tristate buffer produces Z when not enabled
EN A Y
0 0
0 1
1 0
1 1
A Y
EN
A Y
EN
EN
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1: Circuits & Layout Slide 17CMOS VLSI Design
Tristates Tristate buffer produces Z when not enabled
EN A Y
0 0 Z
0 1 Z
1 0 0
1 1 1
A Y
EN
A Y
EN
EN
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1: Circuits & Layout Slide 18CMOS VLSI Design
Nonrestoring Tristate Transmission gate acts as tristate buffer
– Only two transistors– But nonrestoring
• Noise on A is passed on to Y
A Y
EN
EN
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1: Circuits & Layout Slide 19CMOS VLSI Design
Tristate Inverter Tristate inverter produces restored output
– Violates conduction complement rule– Because we want a Z output
A
YEN
EN
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1: Circuits & Layout Slide 20CMOS VLSI Design
Tristate Inverter Tristate inverter produces restored output
– Violates conduction complement rule– Because we want a Z output
A
YEN
A
Y
EN = 0Y = 'Z'
Y
EN = 1Y = A
A
EN
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1: Circuits & Layout Slide 21CMOS VLSI Design
Multiplexers 2:1 multiplexer chooses between two inputs
S D1 D0 Y
0 X 0
0 X 1
1 0 X
1 1 X
0
1
S
D0
D1Y
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1: Circuits & Layout Slide 22CMOS VLSI Design
Multiplexers 2:1 multiplexer chooses between two inputs
S D1 D0 Y
0 X 0 0
0 X 1 1
1 0 X 0
1 1 X 1
0
1
S
D0
D1Y
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1: Circuits & Layout Slide 23CMOS VLSI Design
Gate-Level Mux Design How many transistors are needed?
1 0 (too many transistors)Y SD SD
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1: Circuits & Layout Slide 24CMOS VLSI Design
Gate-Level Mux Design How many transistors are needed? 20
1 0 (too many transistors)Y SD SD
44
D1
D0S Y
4
2
2
2 Y2
D1
D0S
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1: Circuits & Layout Slide 25CMOS VLSI Design
Transmission Gate Mux Nonrestoring mux uses two transmission gates
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1: Circuits & Layout Slide 26CMOS VLSI Design
Transmission Gate Mux Nonrestoring mux uses two transmission gates
– Only 4 transistorsS
S
D0
D1
YS
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1: Circuits & Layout Slide 27CMOS VLSI Design
Inverting Mux Inverting multiplexer
– Use compound AOI22– Or pair of tristate inverters– Essentially the same thing
Noninverting multiplexer adds an inverter
S
D0 D1
Y
S
D0
D1Y
0
1S
Y
D0
D1
S
S
S
S
S
S
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1: Circuits & Layout Slide 28CMOS VLSI Design
4:1 Multiplexer 4:1 mux chooses one of 4 inputs using two selects
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1: Circuits & Layout Slide 29CMOS VLSI Design
4:1 Multiplexer 4:1 mux chooses one of 4 inputs using two selects
– Two levels of 2:1 muxes– Or four tristates
S0
D0
D1
0
1
0
1
0
1Y
S1
D2
D3
D0
D1
D2
D3
Y
S1S0 S1S0 S1S0 S1S0
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1: Circuits & Layout Slide 30CMOS VLSI Design
D Latch When CLK = 1, latch is transparent
– D flows through to Q like a buffer When CLK = 0, the latch is opaque
– Q holds its old value independent of D a.k.a. transparent latch or level-sensitive latch
CLK
D Q
Latc
h D
CLK
Q
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1: Circuits & Layout Slide 31CMOS VLSI Design
D Latch Design Multiplexer chooses D or old Q
1
0
D
CLK
QCLK
CLKCLK
CLK
DQ Q
Q
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1: Circuits & Layout Slide 32CMOS VLSI Design
D Latch Operation
CLK = 1
D Q
Q
CLK = 0
D Q
Q
D
CLK
Q
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1: Circuits & Layout Slide 33CMOS VLSI Design
D Flip-flop When CLK rises, D is copied to Q At all other times, Q holds its value a.k.a. positive edge-triggered flip-flop, master-slave
flip-flop
Flo
p
CLK
D Q
D
CLK
Q
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1: Circuits & Layout Slide 34CMOS VLSI Design
D Flip-flop Design Built from master and slave D latches
QM
CLK
CLKCLK
CLK
Q
CLK
CLK
CLK
CLK
D
Latc
h
Latc
h
D QQM
CLK
CLK
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1: Circuits & Layout Slide 35CMOS VLSI Design
D Flip-flop Operation
CLK = 1
D
CLK = 0
Q
D
QM
QMQ
D
CLK
Q
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1: Circuits & Layout Slide 36CMOS VLSI Design
Race Condition Back-to-back flops can malfunction from clock skew
– Second flip-flop fires late– Sees first flip-flop change and captures its result– Called hold-time failure or race condition
CLK1
D Q1
Flo
p
Flo
p
CLK2
Q2
CLK1
CLK2
Q1
Q2
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1: Circuits & Layout Slide 37CMOS VLSI Design
Nonoverlapping Clocks Nonoverlapping clocks can prevent races
– As long as nonoverlap exceeds clock skew We will use them in this class for safe design
– Industry manages skew more carefully instead 1
11
1
2
22
2
2
1
QMQD
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1: Circuits & Layout Slide 38CMOS VLSI Design
Gate Layout Layout can be very time consuming
– Design gates to fit together nicely– Build a library of standard cells
Standard cell design methodology
– VDD and GND should abut (standard height)
– Adjacent gates should satisfy design rules– nMOS at bottom and pMOS at top– All gates include well and substrate contacts
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1: Circuits & Layout Slide 39CMOS VLSI Design
Example: Inverter
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1: Circuits & Layout Slide 40CMOS VLSI Design
Example: NAND3 Horizontal N-diffusion and p-diffusion strips Vertical polysilicon gates Metal1 VDD rail at top
Metal1 GND rail at bottom 32 by 40
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1: Circuits & Layout Slide 41CMOS VLSI Design
Stick Diagrams Stick diagrams help plan layout quickly
– Need not be to scale– Draw with color pencils or dry-erase markers
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1: Circuits & Layout Slide 42CMOS VLSI Design
Wiring Tracks A wiring track is the space required for a wire
– 4 width, 4 spacing from neighbor = 8 pitch Transistors also consume one wiring track
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1: Circuits & Layout Slide 43CMOS VLSI Design
Well spacing Wells must surround transistors by 6
– Implies 12 between opposite transistor flavors– Leaves room for one wire track
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1: Circuits & Layout Slide 44CMOS VLSI Design
Area Estimation Estimate area by counting wiring tracks
– Multiply by 8 to express in
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1: Circuits & Layout Slide 45CMOS VLSI Design
Example: O3AI Sketch a stick diagram for O3AI and estimate area
– Y A B C D
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1: Circuits & Layout Slide 46CMOS VLSI Design
Example: O3AI Sketch a stick diagram for O3AI and estimate area
– Y A B C D
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1: Circuits & Layout Slide 47CMOS VLSI Design
Example: O3AI Sketch a stick diagram for O3AI and estimate area
– Y A B C D