1 Intro to ECE 305 S16 - nanoHUBIntro_to_ECE305_S16.pdf · Lundstrom ECE-305 S16 3 electron devices...
Transcript of 1 Intro to ECE 305 S16 - nanoHUBIntro_to_ECE305_S16.pdf · Lundstrom ECE-305 S16 3 electron devices...
Lundstrom ECE-305 S16
ECE-305: Spring 2016
Course Introduction
Professor Mark Lundstrom Electrical and Computer Engineering
Purdue University, West Lafayette, IN USA [email protected]
1/12/16
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course objectives
To introduce students to the fundamentals of semiconductors and semiconductor devices.
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electron devices transistor
Bardeen, Brattain, Shockley, 1947
vacuum tube
Edison effect, 1880 J.J. Thompson, 1897 diode (Fleming, 1904) triode (De Forest, 1905)
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electron devices
semiconductor laser
Hall, 1962
LED
Holonyak, 1962
modern solar cell
Chapin, Pearson, Fuller, 1954
transistors
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"The transistor was probably the most important invention of the 20th Century, and the story behind the invention is one of clashing egos and top secret research.”
- Ira Flatow, Transistorized! http://www.pbs.org/transistor/
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Purdue’s semiconductor history
1941: WWII: Semiconductor diode rectifiers http://www.computerhistory.org
“Karl Lark-Horovitz is best known for turning the physics department of Purdue University, then a backwater school, into a research powerhouse. His personal research was in germanium and solid state science -- and if anyone had had a chance of inventing the transistor before Bell, it was Lark-Horovitz. As it was, the Purdue physics lab was probably only six to twelve months behind.” http://www.pbs.org/transistor/album1/addlbios/lark.html
transistors
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S
D
G
symbol
D
S G
switch amplifier
S
D
G input signal
output signal
The Si MOSFET
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S
D
G source drain
SiO
2
silicon
channel ~ 20 nm
gate oxide SiON ~ 1.1 nm
gate electrode
G D
symbol S
transistor IV characteristics (also QV)
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S
D
G
symbol
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“The most important moment since humankind emerged as a life form.” Isaac Asimov
(speaking about the “planar process” used to manufacture ICs -- invented by Jean Hoerni, Fairchild Semiconductor, 1959).
IEEE Spectrum Dec. 2007
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electron devices integrated circuit
Kilby (Texas Instruments) 1958
Noyce (Fairchild) 1959
Moore’s Law
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What is Moore’s Law?
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“Moore’s Law”
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L = 5000 nm
Micro- electronics
L = 5 nm ?
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5000 nm à 5 nm
Nano-electronics
exponential growth
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transistors per cpu chip
1974
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21st Century electronics
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Bell Labs 1947 Apple 2007 21st Century electronics
?
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The end of Moore’s Law
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http://spectrum.ieee.org/static/special-report-50-years-of-moores-law
Electronics beyond Moore’s Law
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Ion Torrent (Nature, 475, 349, 21 July, 2011)
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More than Moore: example: gene sequencing
19 http://www.genome.gov/sequencingcosts/
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What’s inside a smartphone?
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www.apple.com Lundstrom ECE-305 S16
What’s inside a smartphone?
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www.apple.com
CMOS transistors for logic SiGe HBTs for RF A/D and D/A convertors Digital Signal processor Microprocessor ROM and FLASH memory CMOS imager Gyroscope MEMS devices Magnetometer Microphone, speaker LCD display and touch screen
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21st Century electronics
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Bell Labs 1947 Apple 2007 21st Century electronics
?
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course outline
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Part 1: Semiconductor Fundamentals: 5 weeks
Part 2: PN diodes, MS diodes, and devices 5 weeks
Part 3: Transistors 5 weeks
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Course objectives: To introduce students to the fundamentals of semiconductors and semiconductor devices.
ECE-255 / 305 / 455-456
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υin
RD
υout = −gmRDυin
VDD
source drain
SiO
2
silicon
G DS
course text
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Semiconductor Device Fundamentals, 2nd Edition (SDF) R.F. Pierret, Addison-Wesley Publishing Co, 1996. ISBN-0-201-54393-1
Do the reading!
grading
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550 total course points
In-class quizzes/problems (maximum of 50 points)
Homework assigned. Solutions posted. Not graded.
Total score: The sum of the highest 4 of exams 1-5 and exam 6 plus your quiz total.
You must take Exam 6.
6 exams (5 + “final”, maximum of 100 points each)
frequent exams
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1) Multiple choices (5 questions) 25 points
2) Problem 1 (usually 25 points)
3) Problem 2 (usually 25 points)
4) Exam score: (# correct / 75) x 100
frequent exams
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ECE Policy for Calculators in Exams
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Effective beginning in January 2015, the only calculator permitted for exams in ECE undergraduate courses (those at the 10000 – 40000 level) will be the Texas Instruments TI-30X IIS scientific calculator. This is an inexpensive calculator with a 2-line display, a fraction feature, one or two-variable statistics, simple conversions, and basic scientific & trigonometric functions. Students are encouraged to familiarize themselves with the use of this calculator well in advance of any exam.
course web page
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https://nanohub.org/groups/ece305s16
All course information is posted on the class home page
Class announcements will supersede prior written information and will be posted on the course homepage Campus Emergency Policies: In the event of a major campus emergency, course requirements, deadlines and grading percentages are subject to changes that may be necessitated by a revised semester calendar or other circumstances. Information about changes will be posted on the course web page and available from [email protected]
ABET outcomes
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(i) An understanding of the semiconductor bonding and energy band models, of semiconductor carrier properties and statistics, and of carrier action.
(ii) An ability to apply standard device models to explain/calculate critical
internal parameters and standard terminal characteristics of the pn-junction diode and the Schottky diode
(iii) An ability to apply standard device models to explain/calculate critical
internal parameters and standard terminal characteristics of the Metal-Oxide-Semiconductor Field Effect Transistor and the Bipolar Junction Transistor
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Assessment: Exams 1 and 2 will assess outcome (i), exams 3 and 4 will access outcome (ii), and exams 5 and 6 will access outcome (iii).
To report an emergency, call 911. To obtain updates regarding an ongoing emergency, sign up for Purdue Alert text messages, view www.purdue.edu/ea. There are nearly 300 Emergency Telephones outdoors across campus and in parking garages that connect directly to the PUPD. If you feel threatened or need help, push the button and you will be connected immediately. If we hear a fire alarm during class we will immediately suspend class, evacuate the building, and proceed outdoors. Do not use the elevator. If we are notified during class of a Shelter in Place requirement for a tornado warning, we will suspend class and shelter. If we are notified during class of a Shelter in Place requirement for a hazardous materials release, or a civil disturbance, including a shooting or other use of weapons, we will suspend class and shelter in the classroom, shutting the door and turning off the lights. Please review the Emergency Preparedness website for additional information. http://www.purdue.edu/ehps/emergency_preparedness/index.html
EMERGENCY PREPAREDNESS
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cheating
It’s wrong. I have a zero tolerance policy. Any case of cheating will earn you an F in the course and a report to the Dean of Students.
-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐ Exam Integrity Statement -‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐-‐ I understand that if I am caught cheating on this exam or anything else in this course, I will earn an F for the course and be reported to the Dean of Students. Read and understood; ______________________________________________
Signature Lundstrom ECE-305 S16
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questions
How to study
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1) Do the assigned reading before class 2) Attend class and pay attention 3) Review the lecture after class 4) Do the HW without looking at the solutions 5) Review and understand the solutions 6) Be sure you understand the quizzes
7) Ask questions (in class, office hours, Piazza)
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Google Official: on “ideal recruits” "There is no single set of discrete skills one can learn that will last an entire career in high-tech," Johnson writes. Instead, "ideal recruits are creative, adaptable and autonomous, and they have achieved a deep understanding of core subjects such as math, physics and computer science that make it possible to have a razor-sharp intuition and an ability to assimilate new subjects and technologies quickly, without even the expectation of being trained; they train themselves on the skills du jour as the need arises and with minimum help or structure.”
Bruce Johnson, the Atlanta site and engineering director for Google, in the Atlanta Journal-Constitution (12/23/11.
Recommendations
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ECE 305
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Work hard, have fun, learn something you can use for the rest of your career. Get started now and do well on Exam 1! https://nanohub.org/groups/ece305s16