23-06-2015, 04:57 PM
Introduction to
CMOS VLSI
Design
Slides adapted from:
N. Weste, D. Harris, CMOS VLSI Design, © Addison-Wesley, 3/e, 2004
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Introduction
Integrated Circuits:
many transistors on one chip
Very Large Scale Integration (VLSI): very many transistors on one chip
Complementary Metal Oxide Semiconductor (CMOS): fast, cheap, low power
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Outline
A Brief History
MOS transistors
CMOS Logic
CMOS Fabrication and Layout
Chip Design Challenges
System Design
Logic Design
Physical Design
Design Verification
Fabrication, Packaging and Testing
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A Brief History
T-R-A-N-S-I-S-T-O-R = TRANsfer resiSTOR
1947: John Bardeen, Walter Brattain and William Schokley at Bell laboratories built the first working point contact transistor (Nobel Prize in Physics in 1956)
1958: Jack Kylby built the first integrated circuit flip flop at Texas Instruments (Nobel Prize in Physics in 2000)
1925: Julius Lilienfield patents the original idea of field effect transistors
1935: Oskar Heil patents the first MOSFET
1963 : Frank Wanlass at Fairchild describes the first CMOS logic gate (nMOS and pMOS)
1970: Processes using nMOS became dominant
1980: Power consumption become a major issue. CMOS process are widely adopted.
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A Brief History
Integrated Circuits enabled today’s way of life 1018 transistors manufactured in 2003
100 million for every human on the planet
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Moore’s Law
In 1963 Gordon Moore predicted that as a result of continuous miniaturization transistor count would double every 18 months
53% compound annual growth rate over 45 years No other technology has grown so fast so long
Transistors become smaller, faster, consume less power, and are cheaper to manufacture
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Clock Frequencies of Intel Processors
Transistor count is not the only factor that has grown exponentially, e.g. clock frequencies have doubled roughly every 34 months
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Chip Integration Level
SSI = small-scale integration ( up to 10 gates)
MSI = medium-scale integration ( up to 1000 gates)
LSI = large-scale integration (up to 10000 gates)
VLSI = very large-scale integration (over 10000 gates)
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Technology Scaling
1971: Intel 4004
transistors with minimum dimension of 10um
2003: Pentium 4
transistors with minimum dimension of 130 nm
Scaling cannot go on forever because transistors cannot be smaller than atoms ☺
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The Productivity Gap
Designers rely increasingly on design automation software tools:
• to seek productivity gains
• to cope with increased complexity
Source: SEMATECH 10
Silicon Lattice
Silicon is a semiconductor
Transistors are built on a silicon substrate
Silicon is a Group IV material
Forms crystal lattice with bonds to four neighbors
Dopants
Pure silicon has no free carriers and conducts poorly
Adding dopants increases the conductivity
Group V: extra electron (n-type)
Group III: missing electron, called hole (p-type)
Si Si - Si Si Si+ Si
As+ B -
Si Si Si Si
Si Si Si Si Si Si
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Transistor Types
Bipolar transistors
npn or pnp silicon structure
Small current into very thin base layer controls large currents between emitter and collector
Base currents limit integration density
Metal Oxide Semiconductor Field Effect Transistors nMOS and pMOS MOSFETS
Voltage applied to insulated gate controls current between source and drain
Low power allows very high integration
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MOS Transistors
Four terminals: gate, source, drain, body (= bulk = substrate)
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nMOS Operation
Body is commonly tied to ground (0 V) When the gate is at a low voltage:
P-type body is at low voltage
Source-body and drain-body diodes are OFF No current flows, transistor is OFF
Source Gate Drain
Polysilicon
SiO2
n+ n+ 0
p S D
bulk Si 15
nMOS Operation Cont.
When the gate is at a high voltage:
Positive charge on gate of MOS capacitor Negative charge attracted to body
channel under gate gets “inverted” to n-type
Now current can flow through n-type silicon from source through channel to drain, transistor is ON
Source Gate Drain
n+ n+
p bulk Si
Polysilicon
SiO2
1
S D
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pMOS Transistor
Similar, but doping and voltages reversed
Body tied to high voltage (VDD)
Gate low: transistor ON
Gate high: transistor OFF
Bubble indicates inverted behavior
Source Gate Drain
Polysilicon
SiO2
p+ p+
n bulk Si
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Power Supply Voltage
GND = 0 V
In 1980’s, VDD = 5V
VDD has decreased in modern processes
High VDD would damage modern tiny transistors
Lower VDD saves power
VDD = 3.3, 2.5, 1.8, 1.5, 1.2, 1.0, …
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MOS Transistors as switches
We can model MOS transistors as controlled switches Voltage at gate controls path from source to drain
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CMOS Technology
CMOS technology uses both nMOS and pMOS transistors. The transistors are arranged in a structure formed by two complementary networks
Pull-up network is complement of pull-down Parallel -> series, series -> parallel
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CMOS Logic Inverter
A Y
0 1
ON OFF 1 0
1 = 0 = = 1 = 0
OFF ON
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CMOS Logic NAND
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CMOS Logic NOR
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CMOS Logic Gates (a.k.a. Static CMOS)
Pull-up network is complement of pull-down
Parallel series, series parallel
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Compound Gates
Example: Y = (A+B+C) D
ABCD Y
---0 1
0001 1
1--1 0
-1-1 0
--11 0
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Compound Gates
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How good is the output signal ?
Signal Strength
Strength of signal
How close it approximates ideal voltage source VDD and GND rails are strongest 1 and 0 sources
nMOS and pMOS are not ideal switches
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 pMOS are best for pull-up network
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Pass Transistors
Transistors can be used as switches
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Transmission Gates
Pass transistors produce degraded outputs
Transmission gates pass both 0 and 1 well
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Static CMOS gates are fully restored
In static CMOS, the nMOS transistors only need to pass 0’s and the pMOS only pass 1’s, so the output is always strongly driven and the levels are never degraded
This is called a fully restored logic gate
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Static CMOS is inherently inverting
CMOS single stage gates must be inverting
To build non inverting functions we need multiple stages
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Tristates
Tristate buffer produces Z when not enabled
EN A Y
0 0 Z
0 1 Z
1 0 0
1 1 1
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Nonrestoring Tristates
Transmission gate acts as tristate buffer Only two transistors
But nonrestoring
A is passed on to Y as it is
(thus, Y is not always a strong 0’s or 1’s)
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Tristate Inverter
Tristate inverter produces restored output
For a non inverting tristate add an inverter in front
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Multiplexers
2:1 multiplexer chooses between two inputs
S D1 D0 Y S
0 X 0 0
0 X 1 1 D0 0
Y
1 0 X 0
D1 1
1 1 X 1
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Gate-Level Mux Design
Y = S D0 + S D1
How many transistors are needed? = 20 =
= Too Many !!
D1
S Y
D0
D1
S
D0
4 2 Y
4 2
2 4 2 36
Transmission Gate Mux
Nonrestoring mux uses two transmission gates
Only 4 transistors
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Inverting Mux
Inverting multiplexer
Use compound gate or pair of tristate inverters
Essentially the same thing
For noninverting multiplexer add an inverter
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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 Latch Q
CLK
D
Q
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D Latch Design
Multiplexer chooses D or hold Q
CLK CLK
D 1 Q Q
Q D Q
0
CLK
CLK
CLK
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D Latch Operation
Q D Q
CLK = 1
Q
D Q
CLK = 0
CLK
D
Q
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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
CLK
CLK
Flop D
D Q
Q
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D Flip-flop Design
Built from master and slave D latches
D
CLK
Latch
QM
CLK
Latch
Q
CLK
D
CLK CLK
CLK
CLK
QM Q
CLK CLK
CLK
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D Flip-flop Operation
D QM
CLK = 0
D QM
CLK = 1
CLK
D
Q
Q
Q
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Summary
“If the automobile had followed the same development cycle as the computer, a Rolls Royce would today cost $100, get one million miles per gallon, and explode once a year …”
Robert X. Cringely,
InfoWorld Magazine
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