IC Technology PDF

Summary

This document provides a general overview of Integrated Circuits (ICs). It discusses the semiconductor market and various types of ICs. It also touches upon the applications of different IC types.

Full Transcript

IC Technology
hnologș
 TheI Market
The semiconductor industry is approaching $300B/yr in sales

296
Communications
24°4

Industrial

Consumer Electronics
B% 16%
Courtesy of Dr.Bill Flounders, UC Berkeley Micralab
e
I
Integrateö oreusUOlly called
ICS ond popufcirïy known zso SÌIICOR
Integrated
Integrated Circuits
Circuits (ICs)
(ICs)
Integrated Circuit are the tiny electronic circuits used to performa

specific electronic function, such as amplification, mathematic
operations, switching, mixing signals, computer memory, timer,
counter etc.

An IC
An is a collection
IC isa collection ofof electronic
electronic components
components -- --
resistors, transistors,
resistors, transistors, capacitors,
capacitors, etc. -- all
etc. -- all stuffed into
stuffed into
aa tiny
tiny chip,
chip, and
and connected together to
connected together to achieve
achieveaa
common
common goal.goal.
They
They come in all sorts
come inall sorts of flavors: single-circuit
of flavors: logic
single-circuit logic
gates, op
gates, op amps,
amps, 555 timers, voltage
555 timers, voltage regulators,
regulators, motor
motor
controllers, microcontrollers, microprocessors,
controllers, microcontrollers, microprocessors, FPGAs,
FPGAs,
etc.
etc.
Integrated
Integrated Circuits
Circuits (ICs)
(ICs) are
are also known as
also known microchips or
asmicrochips microelectronic circuit,
or microelectronic it isa
circuit, it is a
semiconductor wafer that
semiconductor wafer that holds
holds thousands
thousands and millions of
and millions resistors, capacitors,
of resistors, capacitors, and transistors. It
and transistors. is
It is
basically an
basically an assembly
assembly of electronic components
ofelectronic that’s fabricated
components that's fabricated as
asaa single unit.
single unit.
Integrated
Integrated Circuits
Circuits (ICs)
(ICs)
Several hundred identical integrated circuits
(ICs) are made ata time ona thin wafer which in
several centimeters wide, and the wafer is
subsequently sliced into individual ICs called
chips.
What advantages do ICs have over discrete components?
Y Size: Sub-micron vs. millimeter/centimeter.

S Speed and Power:Smaller si7.e of IC comRof2ents yields higher speed and
lower power consumption due to smaller parasitic resistances, capacitances
and inductances.

Switching between ‘0’ and 1 much faster on chip than between chips.

Lower power consumption => less heat => cheaper power supplies =>
reduced system cost.

¥ Integrated circuit manufacturing is versatile. Simply change themask to
change thedesign.

However, designing the layout (changing the masks) is usually the most
time consuming task in IC design.
Insi e
Inside
Integrated
rcuits (ICs)
Circuits ICs)

Ref: Hitachi-hightech
Hitachi-hiehtech
Insi e
Inside
Integrated
Integrated
Circuits (ICs)

The image above then shows how
The how an IC chip looks like under an X-ray through 3D
3D
rendering, it features complex structures with multiple layers that forms an IC
Cchip.
h'p- Ref: Physics
Phvsics world
Integrated
Integrated Circuits
Circuits (ICs)
(ICs)
555 TIMER ICAND ITSEQUIVALENT CIRCUIT
s
I
 vnn on
Early developments of the Integrated Circuit (IC) go
back to1949.

German engineer Werner Jacobi fileda patent for an IC
like semiconductor amplifying device showing five
transistors on a common substrate in a 2-stage
amplifier arrangement.

Jacobi disclosed small cheap of hearing aids.
 Integrated circuit invented
September 12th 1958 Jack Kilby at Tez¢as instrument had built a
simple oscillator IC with five integrated components (resistors,
capacitors, distributed capacitors and transistors)

’ In 2000 the importance of the IC was recognized when Kilby shared
the Nobel prize in physics with two others. Kilby was sited by the
Nobel committee "for his part in the invention of the integrated
circuit”
 1904.u‘iiiiiiit tilt, iliorlt; large expensive, power-
Fleming 1906 Vacuum triode hungry, unreliable
William Shockley 1945 Semiconductor replacing
(Bell labs) vacuum tube

Bardeen and 1947 Point Contact transfer Driving factor of growth
Brattain and resistance device “BJT” oftheVLSI technology
Shockley
(Bell labs)
\\ pi-ilc'i ,Jilclilii 1949 l*t IC containing No commercial use
(Siemens AG) amplifying Device reported
2stage amplifief
Shockley 1951 Junction Transistor “Practical form of
transistor”
Jack Kilby July 1958 Integrated Circuits FI Father of IC design
(Texas Instruments) With 2-T Germanium
slice and guld wires
 ICTechnolu›gy
Noyce Dec. 1958 Integrated “The Mayor of
Circuits Silicon Valley”
Silicon
Kahng 1960 First MOSFET Start of new era for
Bell Lab semiconductor
industry
1061 First Commercial
IC
And Texas
Frank Wanlass l9ó3 CMOS
(Fairchíld Semictinductor)

1968 Silicon gate IC Later Juined Intel to
technology lead first CPU Intel
(Fairchild Semiconductor) 4004 in 1970
2300T on 9mm2
Zarlink Recently M2A capsule for take photographs of
Semiconductors endoscopy digestive tract 2/sec.
 Poly

Pentium

Penñum 5O0—
III
1,400-
 How semiconductor industry have achieved
the complex integrated circuits?

1. Moore's Law.
2. Continuous technology Scaling.

Figure
Bigure 1. In 1962, four woccen
women programmers
prograccccers hold
hoIB parts
pads of
of
the first four Army computers.
thefirst coccputers. From
Frocc left is the
the ENIAC
board, EDVAC board, ORDVAC board, and anB the BRLESC-I
board.
boarB. Image courtesy
coui4esy of the US Army.
US Arccy.
 1965 M‹ ure's law
“Cramming more components onto integrated
circuits”.
Gordon E.Moore chairman Emeritus of’ Intel Corporation

7 1965 - observed trends in industry - of transistors on ICs vs.
release dates:
R Noticed number oftransistors doubling with release of
each new IC generation
R release dates (separate generations) were all 18-24
months apart
S Moore's Law:
R “The number oftransistors on an integrated circuit
will double every 18 months”
The level of integration of silicon technology as measured interms
ofnumber ofdevices per IC
7 Semiconductor industry has followed this prediction with surprising
accuracy.
 90zm 65nm
130nm

32nm 22nm
45nm
1. Increase device packing density-reduces area
2. Improve frequency response o l/L
3. Improve drive current
4. To improve power efficiency
 Full Scaling (Constant Electric Field Scaling)

S Inreality constant field scaling has not been observed strictly.
Since the transistor current is proportional to the gate
overdrive.

7 High performance demands have dictated the use of higher
supply voltage.

S However, higherVDD implies increased power dissipation.

S Improved performance is due to the reduced capacitance.
 Then >130nm Now