lec0_Introduction_to_cmos_vlsi_design.ppt
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Oct 14, 2025
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About This Presentation
Analyze the operation and design of digital cmos vlsi design using logic gates and integrated circuits.
Slide Content
Introduction Slide 1CMOS VLSI Design
Introduction to CMOS
VLSI Design
Adnan Aziz
The University of Texas at Austin
Introduction to CMOS
VLSI Design
Adnan Aziz
The University of Texas at Austin
Introduction Slide 2CMOS VLSI Design
Organization
Prerequisites: logic design, basic computer organization
–See sample questions
Architecture design versus chip design
–Example: innovative processor
Overview of material
–Bottom-up approach, CAD tools
–See syllabus for individual topics
Course organization
–Website, TA, office hours, HW, projects
Acknowledgements
–J. Abraham (UT), D. Harris (HMC), R. Tupuri (AMD)
Organization
Prerequisites: logic design, basic computer organization
–See sample questions
Architecture design versus chip design
–Example: innovative processor
Overview of material
–Bottom-up approach, CAD tools
–See syllabus for individual topics
Course organization
–Website, TA, office hours, HW, projects
Acknowledgements
–J. Abraham (UT), D. Harris (HMC), R. Tupuri (AMD)
Introduction Slide 3CMOS VLSI Design
Course relevance
2007 world wide sales of chips: ~250B$
–Primarily digital
–High-margin business
–Basis for systems
Most CE graduates work in
–VLSI design: Intel, Qualcomm
–System design: HP, Cisco
–Software: Microsoft, Google
Course relevance
2007 world wide sales of chips: ~250B$
–Primarily digital
–High-margin business
–Basis for systems
Most CE graduates work in
–VLSI design: Intel, Qualcomm
–System design: HP, Cisco
–Software: Microsoft, Google
Introduction Slide 4CMOS VLSI Design
Systems and Chips
This course: designing ICs
–Part of a system: chips + board + software + …
–System companies: HP, Cisco
–Chip companies: Intel, Qualcomm
–nVidia vs. Hercules
Example: high-end data switch
–Marketing gives range of specs, architect tries to
meet them
–Off the shelf chips, embedded software
–Why don’t we teach system design?
Systems and Chips
This course: designing ICs
–Part of a system: chips + board + software + …
–System companies: HP, Cisco
–Chip companies: Intel, Qualcomm
–nVidia vs. Hercules
Example: high-end data switch
–Marketing gives range of specs, architect tries to
meet them
–Off the shelf chips, embedded software
–Why don’t we teach system design?
Introduction Slide 5CMOS VLSI Design
Course Goals
Learn to design and analyze state-of-the-art digital VLSI chips
using CMOS technology
Employ hierarchical design methods
–Understand design issues at the layout, transistor, logic and
register-transfer levels
–Use integrated circuit cells as building blocks
–Use commercial design software in the lab
Understand the complete design flow
–Won’t cover architecture, solid-state physics, analog design
–Superficial treatment of transistor functioning
Course Goals
Learn to design and analyze state-of-the-art digital VLSI chips
using CMOS technology
Employ hierarchical design methods
–Understand design issues at the layout, transistor, logic and
register-transfer levels
–Use integrated circuit cells as building blocks
–Use commercial design software in the lab
Understand the complete design flow
–Won’t cover architecture, solid-state physics, analog design
–Superficial treatment of transistor functioning
Introduction Slide 6CMOS VLSI Design
Course Information
Instructor: Adnan Aziz
–(512) 465-9774, [email protected]
–http://www.ece.utexas.edu/~adnan
Course Web Page
– Link from my page
Book: Weste and Harris, CMOS VLSI Design: A
Circuits and Systems Perspective, AW, 3
rd
edition
Course Information
Instructor: Adnan Aziz
–(512) 465-9774, [email protected]
–http://www.ece.utexas.edu/~adnan
Course Web Page
– Link from my page
Book: Weste and Harris, CMOS VLSI Design: A
Circuits and Systems Perspective, AW, 3
rd
edition
Introduction Slide 7CMOS VLSI Design
Work in the Course
Lectures: largely from text (not always in sequence)
Homework: roughly 6 HWs
–Relatively straightforward review questions
Laboratory exercises
–Three major exercises dealing with various
aspects of VLSI design
–Complete each section before the deadline
Grad students: VLSI design project
–Design an IP core, architecture to layout
Course involves a large amount of work
throughout the semester
Work in the Course
Lectures: largely from text (not always in sequence)
Homework: roughly 6 HWs
–Relatively straightforward review questions
Laboratory exercises
–Three major exercises dealing with various
aspects of VLSI design
–Complete each section before the deadline
Grad students: VLSI design project
–Design an IP core, architecture to layout
Course involves a large amount of work
throughout the semester
Introduction Slide 8CMOS VLSI Design
What Will We Cover?
Designing chips containing lots of transistors
–How basic components work (transistors, gates,
flops, memories, adders,
–Complexity management: hierarchy and CAD tools
Key issues:
–Creating logical structures from transistors
–Performance analysis and optimization
–Testing: functional and manufacturing
–Power consumption, clocking, I/O, etc.
What Will We Cover?
Designing chips containing lots of transistors
–How basic components work (transistors, gates,
flops, memories, adders,
–Complexity management: hierarchy and CAD tools
Key issues:
–Creating logical structures from transistors
–Performance analysis and optimization
–Testing: functional and manufacturing
–Power consumption, clocking, I/O, etc.
Introduction Slide 9CMOS VLSI Design
Exams and Grading
Two midterm tests: in class, open book/notes;
samples will be posted
–Dates for exams in syllabus
–Final: exam (360R), project (382M)
Lab dates in syllabus
–Bonus/penalty for early/late submission
Weights for homework, exams, project are in syllabus
–Relative weights of MT1/2, Lab 1/2/3 intentionally
not specified
Exams and Grading
Two midterm tests: in class, open book/notes;
samples will be posted
–Dates for exams in syllabus
–Final: exam (360R), project (382M)
Lab dates in syllabus
–Bonus/penalty for early/late submission
Weights for homework, exams, project are in syllabus
–Relative weights of MT1/2, Lab 1/2/3 intentionally
not specified
Introduction Slide 10CMOS VLSI Design
Academic Honesty
Cheating will not be tolerated
–OK to discuss homework, laboratory exercises
with classmates, TAs and the instructors
–However: write the homework and lab exercises
by yourself
We check for cheating, and report incidents
Academic Honesty
Cheating will not be tolerated
–OK to discuss homework, laboratory exercises
with classmates, TAs and the instructors
–However: write the homework and lab exercises
by yourself
We check for cheating, and report incidents
Introduction Slide 11CMOS VLSI Design
General Principles
Technology changes fast => important to understand
general principles
–optimization, tradeoffs
–work as part of a group
–leverage existing work: programs ,building blocks
Concepts remain the same:
–Example: relays -> tubes -> bipolar transistors ->
MOS transistors
General Principles
Technology changes fast => important to understand
general principles
–optimization, tradeoffs
–work as part of a group
–leverage existing work: programs ,building blocks
Concepts remain the same:
–Example: relays -> tubes -> bipolar transistors ->
MOS transistors
Introduction Slide 12CMOS VLSI Design
Types of IC Designs
IC Designs can be Analog or Digital
Digital designs can be one of three groups
Full Custom
–Every transistor designed and laid out by hand
ASIC (Application-Specific Integrated Circuits)
–Designs synthesized automatically from a high-level
language description
Semi-Custom
–Mixture of custom and synthesized modules
Types of IC Designs
IC Designs can be Analog or Digital
Digital designs can be one of three groups
Full Custom
–Every transistor designed and laid out by hand
ASIC (Application-Specific Integrated Circuits)
–Designs synthesized automatically from a high-level
language description
Semi-Custom
–Mixture of custom and synthesized modules
Introduction Slide 13CMOS VLSI Design
MOS Technology Trends
MOS Technology Trends
Introduction Slide 14CMOS VLSI Design
Steps in Design
Define Overall Chip
C/RTL Model
Initial Floorplan
Cell Libraries
Circuit Schematics
Megacell Blocks
Circuit Simulation
Layout and Floorplan
Place and Route
Parasitics Extraction
DRC/LVS/ERC
Behavioral Simulation
Logic Simulation
Synthesis
Datapath Schematics
RTL Simulator
Synthesis Tools
Timing Analyzer
Power Estimator
Text Editor
C Compiler
Schematic Editor
Circuit Simulator
Router
Designer Tasks Tools
Architect
Logic
Designer
Designer
Circuit
Physical
Designer
Place/Route Tools
Physical Design
and Evaluation
Tools
Steps in Design
Define Overall Chip
C/RTL Model
Initial Floorplan
Cell Libraries
Circuit Schematics
Megacell Blocks
Circuit Simulation
Layout and Floorplan
Place and Route
Parasitics Extraction
DRC/LVS/ERC
Behavioral Simulation
Logic Simulation
Synthesis
Datapath Schematics
RTL Simulator
Synthesis Tools
Timing Analyzer
Power Estimator
Text Editor
C Compiler
Schematic Editor
Circuit Simulator
Router
Designer Tasks Tools
Architect
Logic
Designer
Designer
Circuit
Physical
Designer
Place/Route Tools
Physical Design
and Evaluation
Tools
Introduction Slide 15CMOS VLSI Design
System on a Chip
Source: ARM
System on a Chip
Source: ARM
Introduction Slide 16CMOS VLSI Design
Laboratory Exercises
Layout and evaluation of standard cells
–Familiarity with layout, circuit simulation, timing
Design and evaluation of an ALU, performance
optimization
–Learn schematic design, timing optimization
Design, synthesis and analysis of a simple controller as
part of an SoC
–Learn RT-level design, system simulation, logic
synthesis and place-and-route
If you already have industrial experience with some of
these tools, you can substitute lab for final project
–Need my approval; will expect more from project
Laboratory Exercises
Layout and evaluation of standard cells
–Familiarity with layout, circuit simulation, timing
Design and evaluation of an ALU, performance
optimization
–Learn schematic design, timing optimization
Design, synthesis and analysis of a simple controller as
part of an SoC
–Learn RT-level design, system simulation, logic
synthesis and place-and-route
If you already have industrial experience with some of
these tools, you can substitute lab for final project
–Need my approval; will expect more from project
Introduction Slide 17CMOS VLSI Design
Laboratory Design Tools
We will use commercial CAD tools
–Cadence, Synopsys, etc.
Commercial software is powerful, but very complex
–Designers sent to long training classes
–Students will benefit from using the software, but
we don’t have the luxury of long training
–TAs have experience with the software
Start work early in the lab
–Unavailability of workstations is no excuse for late
submissions
–Plan designs carefully and save work frequently
Laboratory Design Tools
We will use commercial CAD tools
–Cadence, Synopsys, etc.
Commercial software is powerful, but very complex
–Designers sent to long training classes
–Students will benefit from using the software, but
we don’t have the luxury of long training
–TAs have experience with the software
Start work early in the lab
–Unavailability of workstations is no excuse for late
submissions
–Plan designs carefully and save work frequently
Introduction Slide 18CMOS VLSI Design
Laboratory Exercise 1
DRC
Schematics
Layout
SPICE
Library
(Simulation)
Functional model
Symbol
Footprint (APR)
Timing model
LVS
Extraction
(Cadence) (Cadence)
(Cadence)
Characterization
Laboratory Exercise 1
DRC
Schematics
Layout
SPICE
Library
(Simulation)
Functional model
Symbol
Footprint (APR)
Timing model
LVS
Extraction
(Cadence) (Cadence)
(Cadence)
Characterization
Introduction Slide 19CMOS VLSI Design
Laboratory Exercise 2
Library
Library
DRC
LVS
Layout
Schematics
Data Path Block
Static Timing
Analysis
Layout
Schematic
(Cadence)
Extraction
VerilogXL
Functional
Verification
(Cadence)
(Cadence) (Synopsys)
Laboratory Exercise 2
Library
Library
DRC
LVS
Layout
Schematics
Data Path Block
Static Timing
Analysis
Layout
Schematic
(Cadence)
Extraction
VerilogXL
Functional
Verification
(Cadence)
(Cadence) (Synopsys)
Introduction Slide 20CMOS VLSI Design
Laboratory Exercise 3
Synthesis
(Synopsis)
Formal
Verification
Control Block
Netlist
Layout
(Synopsys)
Static Timing Analysis
(Cadence)
APR
(Cadence)
Extraction
(Verplex)
RTL model
Verilog
Laboratory Exercise 3
Synthesis
(Synopsis)
Formal
Verification
Control Block
Netlist
Layout
(Synopsys)
Static Timing Analysis
(Cadence)
APR
(Cadence)
Extraction
(Verplex)
RTL model
Verilog
Introduction Slide 21CMOS VLSI Design
Need for transistors
Cannot make logic gates with voltage/current source,
RLC components
–Consider steady state behavior of L and C
Need a “switch”: something where a (small) signal
can control the flow of another signal
Need for transistors
Cannot make logic gates with voltage/current source,
RLC components
–Consider steady state behavior of L and C
Need a “switch”: something where a (small) signal
can control the flow of another signal
Introduction Slide 22CMOS VLSI Design
Coherers and Triodes
Hertz: spark gap transmitter, detector
–Verified Maxwell’s equations
–Not practical Tx/Rx system
Marconi: “coherer” changes resistance after EM
pulse, connects to solenoid
Triode: based on Edison’s bulbs!
•See Ch. 1, Tom Lee, “Design of CMOS RF ICs”
Coherers and Triodes
Hertz: spark gap transmitter, detector
–Verified Maxwell’s equations
–Not practical Tx/Rx system
Marconi: “coherer” changes resistance after EM
pulse, connects to solenoid
Triode: based on Edison’s bulbs!
•See Ch. 1, Tom Lee, “Design of CMOS RF ICs”
Introduction Slide 23CMOS VLSI Design
A Brief History of MOS
Some of the events which led to the
microprocessor
Photographs from “State of the Art: A photographic
history of the integrated circuit,” Augarten, Ticknor &
Fields, 1983.
They can also be viewed on the Smithsonian web site,
http://smithsonianchips.si.edu/
A Brief History of MOS
Some of the events which led to the
microprocessor
Photographs from “State of the Art: A photographic
history of the integrated circuit,” Augarten, Ticknor &
Fields, 1983.
They can also be viewed on the Smithsonian web site,
http://smithsonianchips.si.edu/
Introduction Slide 24CMOS VLSI Design
Lilienfeld patents
1930: “Method and
apparatus for controlling
electric currents”, U.S.
Patent 1,745,175
1933: “Device for controlling
electric current”, U. S. Patent
1,900,018
Lilienfeld patents
1930: “Method and
apparatus for controlling
electric currents”, U.S.
Patent 1,745,175
1933: “Device for controlling
electric current”, U. S. Patent
1,900,018
Introduction Slide 25CMOS VLSI Design
Bell Labs
1940: Ohl develops the PN Junction
1945: Shockley's laboratory established
1947: Bardeen and Brattain create point contact
transistor (U.S. Patent 2,524,035)
Diagram from patent application
Bell Labs
1940: Ohl develops the PN Junction
1945: Shockley's laboratory established
1947: Bardeen and Brattain create point contact
transistor (U.S. Patent 2,524,035)
Diagram from patent application
Introduction Slide 26CMOS VLSI Design
Bell Labs
1951: Shockley develops a junction transistor
manufacturable in quantity (U.S. Patent 2,623,105)
Diagram from patent application
Bell Labs
1951: Shockley develops a junction transistor
manufacturable in quantity (U.S. Patent 2,623,105)
Diagram from patent application
Introduction Slide 27CMOS VLSI Design
1950s – Silicon Valley
1950s: Shockley in Silicon Valley
1955: Noyce joins Shockley Laboratories
1954: The first transistor radio
1957: Noyce leaves Shockley Labs to form Fairchild with
Jean Hoerni and Gordon Moore
1958: Hoerni invents technique for diffusing impurities into Si
to build planar transistors using a SiO
2
insulator
1959: Noyce develops first true IC using planar transistors,
back-to-back PN junctions for isolation, diode-isolated Si
resistors and SiO
2
insulation with evaporated metal wiring on
top
1950s – Silicon Valley
1950s: Shockley in Silicon Valley
1955: Noyce joins Shockley Laboratories
1954: The first transistor radio
1957: Noyce leaves Shockley Labs to form Fairchild with
Jean Hoerni and Gordon Moore
1958: Hoerni invents technique for diffusing impurities into Si
to build planar transistors using a SiO
2
insulator
1959: Noyce develops first true IC using planar transistors,
back-to-back PN junctions for isolation, diode-isolated Si
resistors and SiO
2
insulation with evaporated metal wiring on
top
Introduction Slide 28CMOS VLSI Design
The Integrated Circuit
1959: Jack Kilby, working at TI, dreams up the
idea of a monolithic “integrated circuit”
–Components connected by hand-soldered
wires and isolated by “shaping”, PN-diodes
used as resistors (U.S. Patent 3,138,743)
Diagram from patent application
The Integrated Circuit
1959: Jack Kilby, working at TI, dreams up the
idea of a monolithic “integrated circuit”
–Components connected by hand-soldered
wires and isolated by “shaping”, PN-diodes
used as resistors (U.S. Patent 3,138,743)
Diagram from patent application
Introduction Slide 29CMOS VLSI Design
Integrated Circuits
1961: TI and Fairchild introduce the first logic
ICs ($50 in quantity)
1962: RCA develops the first MOS transistor
RCA 16-transistor MOSFET ICFairchild bipolar RTL Flip-Flop
Integrated Circuits
1961: TI and Fairchild introduce the first logic
ICs ($50 in quantity)
1962: RCA develops the first MOS transistor
RCA 16-transistor MOSFET ICFairchild bipolar RTL Flip-Flop
Introduction Slide 30CMOS VLSI Design
Computer-Aided Design
1967: Fairchild develops the “Micromosaic” IC using
CAD
–Final Al layer of interconnect could be customized for
different applications
1968: Noyce, Moore leave Fairchild, start Intel
Computer-Aided Design
1967: Fairchild develops the “Micromosaic” IC using
CAD
–Final Al layer of interconnect could be customized for
different applications
1968: Noyce, Moore leave Fairchild, start Intel
Introduction Slide 31CMOS VLSI Design
RAMs
1970: Fairchild introduces 256-bit Static RAMs
1970: Intel starts selling1K-bit Dynamic RAMs
Fairchild 4100 256-bit SRAM Intel 1103 1K-bit DRAM
RAMs
1970: Fairchild introduces 256-bit Static RAMs
1970: Intel starts selling1K-bit Dynamic RAMs
Fairchild 4100 256-bit SRAM Intel 1103 1K-bit DRAM
Introduction Slide 32CMOS VLSI Design
The Microprocessor
1971: Intel introduces the 4004
–General purpose programmable computer instead of
custom chip for Japanese calculator company
The Microprocessor
1971: Intel introduces the 4004
–General purpose programmable computer instead of
custom chip for Japanese calculator company
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