1/28/2008EE105 Fall 2007 1EE105 –Spring 2008Microelectronic Devices and Circuitshttp://wwwinst eecs berkeley edu/~ee105http://www‐inst.eecs.berkeley.edu/ ee105Prof. Ming C. [email protected] Cory HallTeaching Assistants• Eudean Sun ([email protected])• Sung Hwan Kim ([email protected])• Abhinav Gupta ([email protected])EE105 Spring 2008 Course Overview, Slide 2• Office Hours will be announced on the web What is this class all about?• Basic semiconductor device physics and analog integrated circuits.• What will you learn?– Electrical behavior and applications of transistorsEE105 Spring 2008 Course Overview, Slide 3– Analog integrated circuit analysis and designSchedule• Lectures:– TuTh 3:40‐5:00 PM (102 Moffitt)• Discussion Sections (beginning Monday 1/28):EE105 Spring 2008 Course Overview, Slide 4(g g y /)– Sec. 102 (293 Cory): Mon. 4‐5PM, Eudean Sun– Sec. 103 (2305 Tolman ):Wed . 10‐11AM, Abhinav Gupta– Sec. 104 (293 Cory): Fri. 10‐11AM, Sung Hwan KimLab Schedule• Laborator y Sections (beginning Monday 1/28):– Section 10 (353 Cory): Monday 9AM‐12PM; Wilson Ko– Section 11 (353 Cory): Wednesday 5‐8PM; Eudean Sun– Section 12 (353 Cory): Wednesday 2‐5PM; Abhinav Gupta– Section 13 (353 Cory): Thursday 5‐8PM; Sung Hwan KimSt d ttiflbtitid353CEE105 Spring 2008 Course Overview, Slide 5•Studentsmustsign upfor onelabsection outside353Coryby 5PM Friday 1/25, and regularly attend this lab section.• Switching lab needs consent from both TAs• All of the lab assignments (and tutorials) are posted online athttp://inst.eecs.berkeley.edu/~ee105/sp08/#labs • Each pre‐lab assignment is due at the beginning of thecorresponding lab session. Post‐lab assignments are due atthe beginning of the following lab section.Relation to Other Courses• Prerequisite:– EECS40: KVL and KCL, Thevenin and Norton equivalent circuits, impedance, frequency response (Bode plots), semiconductor basics, simple pn‐junction diode and MOSFET theory and circuit applications, analog vs. digital signalsEE105 Spring 2008 Course Overview, Slide 6signals.• Relation to other courses:– EE105 is a prerequisite for EE113 (Power Electronics) and EE140 (Linear Integrated Circuits). – It is also helpful (but not required) for EE141 (Introduction to Digital Integrated Circuits).1/28/2008EE105 Fall 2007 2Class Materials• Textbook:– Fundamentals of Microelectronics by Behzad Razavi, Wiley Press, January 2008• Lecture Notes will be posted on the class EE105 Spring 2008 Course Overview, Slide 7website, but it is important that you read the corresponding sections in the textbook• Lectures will be recorded and webcasted, however, this is not intended to replace attendanceHomework• Weekly assignments will be posted online on Tuesdays• Due the following Tuesday at 5:10 PM @EE105 Drop box in Undergraduate Lounge, EE105 Spring 2008 Course Overview, Slide 8Cory Hall). • Late homework will not be accepted.• Students are encouraged to discuss homework problems. However, the work which you submit for grading must be your own.Grading– Homework (posted online)• due Tu (5:10PM at Drop Box in Undergrad Lounge) • late homeworks not accepted– Laboratory assignments• Prelab due at beginning of lab session•Report due at the beginning of the following lab15%15%EE105 Spring 2008 Course Overview, Slide 9–2 midterm exams•80 minutes each• closed book(3 pages of notes allowed)– Final exam• Th 5/22 from 12:30‐3:30PM• closed book(7 pages of notes allowed)• bring calculator30%40%Miscellany• Special accommodations:– Students may request accommodation of religious creed, disabilities, and other special circumstances. Please make an appointment to discuss your request, in advance.• Academic (dis)honestyEE105 Spring 2008 Course Overview, Slide 10– Departmental policy will be strictly followed– Collaboration (not cheating!) is encouraged• Classroom etiquette:– Arrive in class on time! – Bring your own copy of the lecture notes.– Turn off cell phones, pagers, MP3 players, etc.– No distracting conversationsSome Important Announcements• Please don’t bring food/drinks to 353 Cory• Lab experiments will be done in pairs. Each person should turn in his/her individual reports.EE105 Spring 2008 Course Overview, Slide 11• Homework should be done individually.• Cheating on an exam will result in an automatic F course grade.Getting Started• Assignment 1: – To be posted later today– Due 1/29 (Tuesday) at 5 PM• NO discussion sessions, labs, or office hours EE105 Spring 2008 Course Overview, Slide 12this week.1/28/2008EE105 Fall 2007 3Course Overview(refer to detailed syllabus)EE105 Spring 2008 Course Overview, Slide 13IntroductionIntroductionThe Integrated Circuit (IC)• An IC consists of interconnected electronic components in a single piece (“chip”) of semiconductor material.• In 1959, Robert Noyce (Fairchild Semiconductor) demonstrated an IC made in silicon using SiO2as the • In 1958, Jack S. Kilby (Texas Instruments) showed that it was possible to fabricate a EE105 Spring 2008 Course Overview, Slide 15The first planar IC(actual size: 0.06 in. diameter)g2insulator and Al for the metallic interconnects.psimple IC in germanium.From a Few, to Billions• By connecting a large number of components, each performing simple operations, an IC that performs very complex tasks can be built. • The degree of integration has increased at an exponential pace over the past ~40 years.» The number of devices on a chip doubles Intel Pentium®4 ProcessorEE105 Spring 2008 Course Overview, Slide 16every ~18 months, for the same price.“Moore’s Law” still holds today.1,00010,000100,0001,000,00010,000,000100,000,0001,000,000,00019711973197519771979198119831985198719891991199319951997199920012003Intel CPU DRAM40448080808680486PentiumPentiumII8028680386Pentium III & IV1K4K16K64K256K1M4M16M64M256M1 Gb300mm Si waferEECS 105 in the Grand Scheme • Example electronic system: cell phoneEE105 Spring 2008 Course Overview, Slide 17EECS 105: Emphasis on Analog IC’s• Example: 14‐bit analog‐to‐digital converter– Y. Chiu, IEEE Int’l Solid‐State Circuits Conference, 2004.EE105 Spring 2008 Course Overview, Slide 181/28/2008EE105 Fall 2007 4Digital or Analog Signal?EE105 Spring 2008 Course Overview, Slide 19• X1(t) is operating at 100Mb/s and X2(t) is operating at
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