Xilinx XC4000 FPGA devices - Mahanakorn University of

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Transcript Xilinx XC4000 FPGA devices - Mahanakorn University of 

Digital Integrated Circuit:
An Introduction
Theerayod Wiangtong
Electronic Department
Mahanakorn University of Technology
1
Outlines
• Introduction to Digital IC designs: History,
Evolutions, etc.
• Introduction to ASIC: CMOS IC designs
• Introduction to FPGA: Chips and Design Processs
2
Semiconductor: The Revolution
First transistor
Bell Labs, 1948
3
The First Integrated Circuits
Bipolar logic
1960’s
ECL 3-input Gate
Motorola 1966
4
Intel 4004 Micro-Processor
1971
1000 transistors
1 MHz operation
5
Intel Pentium (IV) processor
2001
42 M transistors
1.5 GHz operation
6
Moore’s law in Microprocessors
Transistors (MT)
1000
2X growth in 1.96 years!
100
10
486
1
386
286
0.1
0.01
P6
Pentium® proc
8086
8080
8008
4004
8085
0.001
1970
1980
1990
Year
2000
2010
Transistors on Lead Microprocessors double every 2 years
7
Courtesy, Intel
10,000
10,000,000
100,000
100,000,000
Logic Tr./Chip
Tr./Staff Month.
1,000
1,000,000
10,000
10,000,000
100
100,000
Productivity
(K) Trans./Staff - Mo.
Complexity
Logic Transistor per Chip (M)
Productivity Trends (ITRS)
1,000
1,000,000
58%/Yr. compounded
Complexity growth rate
10
10,000
100
100,000
1,0001
10
10,000
x
0.1
100
xx
0.01
10
xx
x
1
1,000
21%/Yr. compound
Productivity growth rate
x
x
0.1
100
0.01
10
2009
2007
2005
2003
2001
1999
1997
1995
1993
1991
1989
1987
1985
1983
1981
0.001
1
Source: Sematech
Complexity outpaces design productivity
8
Courtesy, ITRS Roadmap
Technology on Semiconductor
9
Design Methodology
10
Design Styles
•
•
•
•
Full-Custom Design
Standard Cell Design
Gate Array Design
Field Programmable Gate Array Design
(FPGA)
• … or mixtures of the above
11
Full-Custom Design
• No rigid restrictions on
layout.
• More compact design.
• Longer design time.
• Hierarchical: chip 
clusters  units 
functional units.
12
Standard Cell Design
• Rectangular cells of the
same height.
• Cell library (has 500 1200 cells).
• Cells placed in rows and
space between rolls are
called channels for routing.
• Feedthroughs
13
Gate Array Design
• Each chip is prefabricated
with an array of identical
gates or cells.
• The chip is “customized”
by fabricating routing
layers on top.
• For example, MPGA
14
Field Programmable Gate Array
• Chips are prefabricated with logic
blocks and interconnects.
• Logic and interconnects can be
programmed (erased and reprogrammed) by users. No
fabrication is needed.
• Interconnects are predefined wire
segments of fixed lengths with
switches in between.
• For example, FPGA, CPLD
15
What is this course all about?
• Digital integrated circuit design
– Cell-based: ASIC design, Primitive component,
Combinational and Sequential circuits, Arithmetic,
interconnect, and memories.
– Array based: Programmable logic arrays. FPGA,
HDL, Design methodologies.
16
The First Computer
The Babbage
Difference Engine
(1832)
25,000 parts
cost: £17,470
17
ENIAC - The first electronic computer (1946)
ENIAC contained 17,468 vacuum tubes, 7,200 crystal
diodes, 1,500 relays, 70,000 resistors, 10,000 capacitors
and around 5 million hand-soldered joints. It weighed 30
short tons (27 t), was roughly 8.5 feet (2.6 m) by 3 feet
(0.91 m) by 80 feet (2.6 m by 0.9 m by 26 m), took up
680 square feet (63 m²), and consumed 150 kW of
power.[6] Input was possible from an IBM card reader,
and an IBM card punch was used for output
18
Intel Pentium (IV) microprocessor
The Computer in 50
years later!
19
Moore’s Law
In
1965, Gordon Moore noted that the
number of transistors on a chip doubled
every 18 to 24 months.
He made a prediction that
semiconductor technology will double its
effectiveness every 18 months
20
Evolution in Complexity
21
Transistor Counts
1 Billion
Transistors
K
1,000,000
100,000
10,000
1,000
i486
i386
80286
100
10
Pentium® III
Pentium® II
Pentium® Pro
Pentium®
8086
Source: Intel
1
1975 1980 1985 1990 1995 2000 2005 2010
Projected
22
Courtesy, Intel
Moore’s law in Microprocessors
Transistors (MT)
1000
2X growth in 1.96 years!
100
10
486
1
386
286
0.1
0.01
P6
Pentium® proc
8086
8080
8008
4004
8085
0.001
1970
1980
1990
Year
2000
2010
Transistors on Lead Microprocessors double every 2 years
23
Courtesy, Intel
Die Size Growth
Die size (mm)
100
10
8080
8008
4004
1
1970
8086
8085
1980
286
386
P6
Pentium
® proc
486
~7% growth per year
~2X growth in 10 years
1990
Year
2000
2010
Die size grows by 14% to satisfy Moore’s Law
24
Courtesy, Intel
Frequency
Frequency (Mhz)
10000
Doubles every
2 years
1000
100
486
10
8085
1
0.1
1970
8086 286
P6
Pentium ® proc
386
8080
8008
4004
1980
1990
Year
2000
2010
Lead Microprocessors frequency doubles every 2 years
25
Courtesy, Intel
Power Dissipation
Power (Watts)
100
P6
Pentium ® proc
10
8086 286
1
8008
4004
486
386
8085
8080
0.1
1971
1974
1978
1985
1992
2000
Year
Lead Microprocessors power continues to increase
26
Courtesy, Intel
Power will be a major problem
100000
18KW
5KW
1.5KW
500W
Power (Watts)
10000
1000
100
Pentium® proc
286 486
8086 386
10
8085
8080
8008
1 4004
0.1
1971 1974 1978 1985 1992 2000 2004 2008
Year
Power delivery and dissipation will be prohibitive
27
Courtesy, Intel
Power density
Power Density (W/cm2)
10000
1000
100
Rocket
Nozzle
Nuclear
Reactor
8086
10 4004
Hot Plate
P6
8008 8085
Pentium® proc
386
286
486
8080
1
1970
1980
1990
2000
2010
Year
Power density too high to keep junctions at low temp
28
Courtesy, Intel
Challenges in Digital Design
•
•
•
•
•
•
“Microscopic Problems”
Ultra-high speed design
Interconnect
Noise, Crosstalk
Reliability, Manufacturability
Power Dissipation
Clock distribution.
Everything Looks a Little
Different
?
•
•
•
•
•
•
“Macroscopic Issues”
Time-to-Market
Millions of Gates
High-Level Abstractions
Reuse & IP: Portability
Predictability
etc.
…and There’s a Lot of Them!
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Design Abstraction Levels
SYSTEM
MODULE
+
GATE
CIRCUIT
DEVICE
G
S
n+
D
n+
30
Design Metrics
• How to evaluate performance of a digital circuit (gate,
block, …)?
–
–
–
–
–
–
Cost
Reliability
Scalability
Speed (delay, operating frequency)
Power dissipation
Energy to perform a function
31
Cost of Integrated Circuits
• NRE (non-recurrent engineering) costs
– design time and effort, mask generation
– one-time cost factor
• Recurrent costs
– silicon processing, packaging, test
– proportional to volume
– proportional to chip area
32
NRE Cost is Increasing
33
Die Cost
Single die
Wafer
Going up to 12” (30cm)
From http://www.amd.com
34
Cost per Transistor
cost:
¢-per-transistor
1
0.1
Fabrication capital cost per transistor (Moore’s law)
0.01
0.001
0.0001
0.00001
0.000001
0.0000001
1982
1985
1988
1991
1994
1997
2000
2003
2006
2009
2012
35
Yield
No. of good chips per wafer
Y
100%
T otalnumber of chips per wafer
Wafercost
Die cost 
Dies per wafer Die yield
  wafer diameter/22   wafer diameter
Dies per wafer

die area
2  die area
36
Some Examples
Chip
Metal
layers
Line
width
Wafer
cost
Def./
cm2
Area
mm2
Dies/w
afer
Yield
Die
cost
386DX
2
0.90
$900
1.0
43
360
71%
$4
486 DX2
3
0.80
$1200
1.0
81
181
54%
$12
Power PC 601
4
0.80
$1700
1.3
121
115
28%
$53
HP PA 7100
3
0.80
$1300
1.0
196
66
27%
$73
DEC Alpha
3
0.70
$1500
1.2
234
53
19%
$149
Super Sparc
3
0.70
$1700
1.6
256
48
13%
$272
Pentium
3
0.80
$1500
1.5
296
40
9%
$417
37
Impact of
Technology Scaling
38
Goals of Technology Scaling
• Make things cheaper:
– Want to sell more functions (transistors) per chip for the
same money
– Build same products cheaper, sell the same part for
less money
– Price of a transistor has to be reduced
• But also want to be faster, smaller, lower power
39
Technology Evolution (2000 data)
International Technology Roadmap for Semiconductors
Year of Introduction
1999
Technology node [nm]
180
Supply [V]
1.5-1.8
Wiring levels
2000
2001
2004
2008
2011
2014
130
90
60
40
30
1.5-1.8
1.2-1.5
0.9-1.2
0.6-0.9
0.5-0.6
0.3-0.6
6-7
6-7
7
8
9
9-10
10
Max frequency
[GHz],Local-Global
1.2
1.6-1.4
2.1-1.6
3.5-2
7.1-2.5
11-3
14.9
-3.6
Max mP power [W]
90
106
130
160
171
177
186
Bat. power [W]
1.4
1.7
2.0
2.4
2.1
2.3
2.5
Node years: 2007/65nm, 2010/45nm, 2013/33nm, 2016/23nm
40
ITRS Technology Roadmap
41
Terminology
• ITRS: International Technology Roadmap for Semiconductors. It is
devised and intended for technology assessment only and is without
regard to any commercial considerations pertaining to individual
products or equipment
• DRAM Half-pitch: The common measure of the technology generation
of a chip. It is half the distance between cells in a dynamic RAM
memory chip. For example, in 2002, the DRAM half pitch has been
reduced to 130 nm (.13 micron).
42
Half Pitch
DRAM ½ pitch
= DRAM metal pitch/2
MPU/ASIC M1 ½ pitch
= MPU/ASIC M1 pitch/2
Metal
pitch
Passivation
Dielectric
Wire
Etch Stop Layer
Via
Dielectric Capping Layer
Copper Conductor with
Barrier/Nucleation Layer
Global
Intermediate
Typical DRAM/MPU/ASIC
Metal Bit Line
Metal 1
Pre-Metal Dielectric
Tungsten Contact Plug
Metal 1 Pitch
43
Technology Scaling: To preserve Moore’s
Law
Number of components per chip
44
2010 Outlook
• Performance 2X/16 months
– 1 TIP (terra instructions/s)
– 30 GHz clock
• Size
– No of transistors: 2 Billion
– Die: 40*40 mm
• Power
– 10kW!!
– Leakage: 1/3 active Power
45
Wafer Size
Past   Future
200mm/1990a
300mm/2001a
450mm/2012f
675mm/>2021f?
(125/150mm ~1981)
46
NRE Cost: Example
http://www.mosis.org/prices.html
47
Some interesting questions
• What will cause this model to break?
• When will it break?
• Will the model gradually slow down?
–
–
–
–
–
–
Power and power density
Leakage
Process Variation
Delay
NRE Cost
Etc.
48
Summary
• Digital integrated circuits have come a long way and
still have quite some potential left for the coming
decades.
• Some interesting challenges ahead
– Getting a clear perspective on the challenges and potential
solutions is the purpose of this book
• Understanding the design metrics that govern digital
design is crucial
– Cost, reliability, speed, power and energy dissipation
49
QUESTIONS?
THANK YOU
50