Lecture 1: Circuits & Layout

Introduction to CMOS VLSI Design

Lecture 1: Circuits & Layout David Harris

Harvey Mudd College Spring 2004

Outline q q q q q q

A Brief History CMOS Gate Design Pass Transistors CMOS Latches & Flip-Flops Standard Cell Layouts Stick Diagrams

1: Circuits & Layout

CMOS VLSI Design

Slide 2

A Brief History q 1958: First integrated circuit – Flip-flop using two transistors – Built by Jack Kilby at Texas Instruments q 2003 – Intel Pentium 4 µprocessor (55 million transistors) – 512 Mbit DRAM (> 0.5 billion transistors) q 53% compound annual growth rate over 45 years – No other technology has grown so fast so long q Driven by miniaturization of transistors – Smaller is cheaper, faster, lower in power! – Revolutionary effects on society 1: Circuits & Layout

CMOS VLSI Design

Slide 3

Annual Sales q 1018 transistors manufactured in 2003 – 100 million for every human on the planet Global Semiconductor Billings (Billions of US$)

200

150

100

50

0 1982

1984

1986

1988

1990

1992

1994

1996

1998

2000

2002

Year 1: Circuits & Layout

CMOS VLSI Design

Slide 4

Invention of the Transistor q Vacuum tubes ruled in first half of 20th century Large, expensive, power-hungry, unreliable q 1947: first point contact transistor – John Bardeen and Walter Brattain at Bell Labs – Read Crystal Fire By Riordan, Hoddeson

1: Circuits & Layout

CMOS VLSI Design

Slide 5

Transistor Types q 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 q 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 1: Circuits & Layout

CMOS VLSI Design

Slide 6

MOS Integrated Circuits q 1970’s processes usually had only nMOS transistors – Inexpensive, but consume power while idle

Intel 1101 256-bit SRAM Intel 4004 4-bit µProc q 1980s-present: CMOS processes for low idle power 1: Circuits & Layout

CMOS VLSI Design

Slide 7

Moore’s Law q 1965: Gordon Moore plotted transistor on each chip – Fit straight line on semilog scale – Transistor counts have doubled every 26 months 1,000,000,000

Integration Levels

100,000,000

10,000,000

Transistors

Intel486

1,000,000

Pentium 4 Pentium III Pentium II Pentium Pro Pentium

Intel386

10 gates

MSI: 1000 gates

80286

100,000

SSI:

8086 10,000

8080

LSI:

8008 4004 1,000

1970

1975

1980

1985

1990

1995

2000

10,000 gates

VLSI: > 10k gates

Year

1: Circuits & Layout

CMOS VLSI Design

Slide 8

Corollaries q Many other factors grow exponentially – Ex: clock frequency, processor performance 10,000

4004

1,000

8008

Clock Speed (MHz)

8080 8086

100

80286 Intel386 Intel486

10

Pentium Pentium Pro/II/III Pentium 4

1

1970

1975

1980

1985

1990

1995

2000

2005

Year

1: Circuits & Layout

CMOS VLSI Design

Slide 9

CMOS Gate Design q Activity: – Sketch a 4-input CMOS NAND gate

1: Circuits & Layout

CMOS VLSI Design

Slide 10

CMOS Gate Design q Activity: – Sketch a 4-input CMOS NOR gate

A B C D Y

1: Circuits & Layout

CMOS VLSI Design

Slide 11

Complementary CMOS q Complementary CMOS logic gates – nMOS pull-down network – pMOS pull-up network inputs – a.k.a. static CMOS

Pull-up OFF

Pull-up ON

Pull-down OFF Z (float)

1

Pull-down ON

X (crowbar)

1: Circuits & Layout

0

CMOS VLSI Design

pMOS pull-up network

output nMOS pull-down network

Slide 12

Series and Parallel q q q q

nMOS: 1 = ON pMOS: 0 = ON Series: both must be ON Parallel: either can be ON

a

a g1 g2

1

1

0

1

0

1

b

b

b

OFF

OFF

ON

a

a

a

a

0

(b)

a g1

g2

(c)

a g1

g2 b

1

1

1

0

1

b

b

b

b

ON

OFF

OFF

OFF

a

a

a

a

0

0

b

CMOS VLSI Design

0

0 b

1: Circuits & Layout

b OFF

a

g2

a

0

(a)

g1

a

0

b

(d)

a

1

0

0

1

1

1

b

b

b

b

OFF

ON

ON

ON

a

a

a

a

0

0

0

1

1

0

1

1

b

b

b

b

ON

ON

ON

OFF

Slide 13

Conduction Complement q Complementary CMOS gates always produce 0 or 1 q Ex: NAND gate – Series nMOS: Y=0 when both inputs are 1 – Thus Y=1 when either input is 0 Y – Requires parallel pMOS A

B

q Rule of Conduction Complements – Pull-up network is complement of pull-down – Parallel -> series, series -> parallel

1: Circuits & Layout

CMOS VLSI Design

Slide 14

Compound Gates q Compound gates can do any inverting function q Ex: Y = Ag B + C g D (AND-AND-OR-INVERT, AOI22) A

C

A

C

B

D

B

D

(a)

A

(b)

B C

D

(c)

C

D

A

B

(d)

C

D

A

B

A B C D

Y A

C

B

D

Y

(f)

(e)

1: Circuits & Layout

CMOS VLSI Design

Slide 15

Example: O3AI q Y = ( A + B + C )g D

1: Circuits & Layout

CMOS VLSI Design

Slide 16

Example: O3AI q Y = ( A + B + C )g D

A B C

D Y D

A

1: Circuits & Layout

B

C

CMOS VLSI Design

Slide 17

Signal Strength q Strength of signal – How close it approximates ideal voltage source q VDD and GND rails are strongest 1 and 0 q nMOS pass strong 0 – But degraded or weak 1 q pMOS pass strong 1 – But degraded or weak 0 q Thus nMOS are best for pull-down network

1: Circuits & Layout

CMOS VLSI Design

Slide 18

Pass Transistors q Transistors can be used as switches g s

d

g s

d

1: Circuits & Layout

CMOS VLSI Design

Slide 19

Pass Transistors q Transistors can be used as switches g=0

g s

d

s

d

Input g = 1 Output 0 strong 0

g=1 s

d

s

d

d g=1 s

1: Circuits & Layout

1 Input

g=0

g s

g=1

d

CMOS VLSI Design

degraded 1 g=0

0

Output degraded 0

g=0 strong 1

Slide 20

Transmission Gates q Pass transistors produce degraded outputs q Transmission gates pass both 0 and 1 well

1: Circuits & Layout

CMOS VLSI Design

Slide 21

Transmission Gates q Pass transistors produce degraded outputs q Transmission gates pass both 0 and 1 well Input g a

b gb

a

g = 0, gb = 1 a b

g = 1, gb = 0 0 strong 0

g = 1, gb = 0 a b

g = 1, gb = 0 strong 1 1

g

g b gb

1: Circuits & Layout

a

g b

gb

Output

a

b gb

CMOS VLSI Design

Slide 22

Tristates q Tristate buffer produces Z when not enabled EN

A

0

0

0

1

1

0

1

1

EN

Y

Y

A

EN Y

A EN

1: Circuits & Layout

CMOS VLSI Design

Slide 23

Tristates q Tristate buffer produces Z when not enabled EN

A

Y

0

0

Z

0

1

Z

1

0

0

1

1

1

EN Y

A

EN Y

A EN

1: Circuits & Layout

CMOS VLSI Design

Slide 24

Nonrestoring Tristate q Transmission gate acts as tristate buffer – Only two transistors – But nonrestoring • Noise on A is passed on to Y

EN A

Y EN

1: Circuits & Layout

CMOS VLSI Design

Slide 25

Tristate Inverter q Tristate inverter produces restored output – Violates conduction complement rule – Because we want a Z output A EN Y EN

1: Circuits & Layout

CMOS VLSI Design

Slide 26

Tristate Inverter q Tristate inverter produces restored output – Violates conduction complement rule – Because we want a Z output A

A

A EN Y

Y

Y

EN = 0 Y = 'Z'

EN = 1 Y=A

EN

1: Circuits & Layout

CMOS VLSI Design

Slide 27

Multiplexers q 2:1 multiplexer chooses between two inputs S S

D1

D0

0

X

0

0

X

1

1

0

X

1

1

X

1: Circuits & Layout

Y

D0

0 Y

D1

CMOS VLSI Design

1

Slide 28

Multiplexers q 2:1 multiplexer chooses between two inputs S S

D1

D0

Y

0

X

0

0

0

X

1

1

1

0

X

0

1

1

X

1

1: Circuits & Layout

CMOS VLSI Design

D0

0 Y

D1

1

Slide 29

Gate-Level Mux Design q Y = SD1 + SD0 (too many transistors) q How many transistors are needed?

1: Circuits & Layout

CMOS VLSI Design

Slide 30

Gate-Level Mux Design q Y = SD1 + SD0 (too many transistors) q How many transistors are needed? 20

D1 S D0

D1 S D0 1: Circuits & Layout

Y

4

2 4

2

4

2

Y

2

CMOS VLSI Design

Slide 31

Transmission Gate Mux q Nonrestoring mux uses two transmission gates

1: Circuits & Layout

CMOS VLSI Design

Slide 32

Transmission Gate Mux q Nonrestoring mux uses two transmission gates – Only 4 transistors

S D0 Y

S D1 S 1: Circuits & Layout

CMOS VLSI Design

Slide 33

Inverting Mux q Inverting multiplexer – Use compound AOI22 – Or pair of tristate inverters – Essentially the same thing q Noninverting multiplexer adds an inverter D0 S

S D1

D0

D1

S

S

Y S

S

S Y

S

D0

Y

S D1

1: Circuits & Layout

CMOS VLSI Design

0 1

Slide 34

4:1 Multiplexer q 4:1 mux chooses one of 4 inputs using two selects

1: Circuits & Layout

CMOS VLSI Design

Slide 35

4:1 Multiplexer q 4:1 mux chooses one of 4 inputs using two selects – Two levels of 2:1 muxes – Or four tristates S1S0 S1S0 S1S0 S1S0 D0 S0 D0

0

D1

1

S1 D1 0 Y

Y D2

0

D3

1

1 D2

D3

1: Circuits & Layout

CMOS VLSI Design

Slide 36

D Latch q When CLK = 1, latch is transparent – D flows through to Q like a buffer q When CLK = 0, the latch is opaque – Q holds its old value independent of D q a.k.a. transparent latch or level-sensitive latch

D

Latch

CLK

1: Circuits & Layout

CLK D

Q Q

CMOS VLSI Design

Slide 37

D Latch Design q Multiplexer chooses D or old Q CLK D

1

CLK

Q Q

Q

D

Q

0 CLK

CLK

CLK

1: Circuits & Layout

CMOS VLSI Design

Slide 38

D Latch Operation Q D

CLK = 1

Q

Q D

Q

CLK = 0

CLK D Q 1: Circuits & Layout

CMOS VLSI Design

Slide 39

D Flip-flop q When CLK rises, D is copied to Q q At all other times, Q holds its value q a.k.a. positive edge-triggered flip-flop, master-slave flip-flop

CLK

CLK D

Flop

D

Q Q

1: Circuits & Layout

CMOS VLSI Design

Slide 40

D Flip-flop Design q Built from master and slave D latches CLK

CLK CLK

QM

D CLK QM

Latch

D

Latch

CLK

CLK

CLK

CLK

Q CLK

1: Circuits & Layout

Q

CMOS VLSI Design

CLK

Slide 41

D Flip-flop Operation D

QM

Q

CLK = 0

D

QM

Q

CLK = 1

CLK D Q

1: Circuits & Layout

CMOS VLSI Design

Slide 42

Race Condition q 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 CLK2 Q1

Flop

D

Flop

CLK1

CLK2 Q2

Q1 Q2

1: Circuits & Layout

CMOS VLSI Design

Slide 43

Nonoverlapping Clocks q Nonoverlapping clocks can prevent races – As long as nonoverlap exceeds clock skew q We will use them in this class for safe design – Industry manages skew more carefully instead φ2

φ1 QM

D φ2

φ2

φ2

Q φ1

φ1

φ1

φ1 φ2

1: Circuits & Layout

CMOS VLSI Design

Slide 44

Gate Layout q Layout can be very time consuming – Design gates to fit together nicely – Build a library of standard cells q 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

1: Circuits & Layout

CMOS VLSI Design

Slide 45

Example: Inverter

1: Circuits & Layout

CMOS VLSI Design

Slide 46

Example: NAND3 q q q q q

Horizontal N-diffusion and p-diffusion strips Vertical polysilicon gates Metal1 VDD rail at top Metal1 GND rail at bottom 32 λ by 40 λ

1: Circuits & Layout

CMOS VLSI Design

Slide 47

Stick Diagrams q Stick diagrams help plan layout quickly – Need not be to scale – Draw with color pencils or dry-erase markers

1: Circuits & Layout

CMOS VLSI Design

Slide 48

Wiring Tracks q A wiring track is the space required for a wire – 4 λ width, 4 λ spacing from neighbor = 8 λ pitch q Transistors also consume one wiring track

1: Circuits & Layout

CMOS VLSI Design

Slide 49

Well spacing q Wells must surround transistors by 6 λ – Implies 12 λ between opposite transistor flavors – Leaves room for one wire track

1: Circuits & Layout

CMOS VLSI Design

Slide 50

Area Estimation q Estimate area by counting wiring tracks – Multiply by 8 to express in λ

1: Circuits & Layout

CMOS VLSI Design

Slide 51

Example: O3AI q Sketch a stick diagram for O3AI and estimate area – Y = ( A + B + C )g D

1: Circuits & Layout

CMOS VLSI Design

Slide 52

Example: O3AI q Sketch a stick diagram for O3AI and estimate area – Y = ( A + B + C )g D

1: Circuits & Layout

CMOS VLSI Design

Slide 53

Example: O3AI q Sketch a stick diagram for O3AI and estimate area – Y = ( A + B + C )g D

1: Circuits & Layout

CMOS VLSI Design

Slide 54