EE70

The solutions for homework 9 are available for download in the homework section.

The deadline for turning in lab report #5 has been extended to Friday March 21. See John for details.

NEW: Here is a link to a website with lots of examples on node/mesh analysis, Thevenin, Norton etc. (Thanks, Gavin!)

Here is a link to be a very useful interactive web site that has lots of useful examples. While some of the material is beyond the level of this class, there is much here that could be useful, particularly to develop your intuition about how circuits work. Try it out and let me know what you think.

Introduction to the physical basis and mathematical models of electrical components and circuits. Topics include: circuit theorems, constant and sinusoidal inputs, natural and forced response of linear circuits. Introduction to circuit/network design, maximum power transfer, analog filters, and system compensation. Topics in elementary electronics: devices, linear models, amplifiers, feedback. Nonlinear elements and devices also introduced. Prerequisites: Physics 5C and 5N, or 6C and 6N, and Mathematics 24 or 27. Students must enroll concurrently in course 70L.

Laboratory sequence illustrating topics covered in course 70. One two-hour laboratory session per week. Prerequisites: Physics 5C and 5N, or 6C and 6N, and Mathematics 24 or 27. Students must enroll concurrently in course 70.

Lecture

Tu-Th 4 pm - 5:45 pm, Porter 144

Instructor

Holger Schmidt

Office

157B Baskin Engineering Building

Phone

(831) 459-1482

Email

hschmidt@soe.ucsc.edu

Office Hours

Mo 1-2 pm, Wed 1:30-2:30 pm

TA

John Wang, johndape@cse.ucsc.edu

Grader

Tam Nguyen

Required text

A. R. Hambley, Electrical Engineering Principles and Applications, Prentice Hall, 2002, 2nd Edition.

Recommended texts

The Art of Electronics by Paul Horowitz, Winfield Hill, 2nd edition (1989); Cambridge Univ Press (Short); ISBN: 0521370957

Schaum's Outline of Basic Circuit Analysis by John O'Malley (plenty of solved problems!), McGraw-Hill; ISBN: 0070478244

Basic Engineering Circuit Analysis by J. David Irwin; John Wiley & Sons; ISBN: 0471381314

Electrical Engineering : An Introduction, Steven E. Schwarz,William G. Oldham, Oxford University Press, Pub. Date: October 1995

Discussion section

in front of the whiteboards in Baskin Engineering (Jack's lounge). Time: Monday 2-4 pm

Lab sessions

Baskin Engineering building room 113, Time: Wed 11:40-1:40 pm and Wed 2:20-4:20 pm

Homework Assignments

Homeworks will be assigned and collected during class sessions, and will generally follow a weekly sequence. Solutions are posted on the web site on the date of collection. Thus, late homework will not be accepted or graded. Homework is graded in terms of it being complete, well organized, readable and showing evidence of thoughtful attention to the problem itself. Sloppy submissions will not be considered for grading.

Required Textbook

Grading Method

The course will not be graded on a curve. It is possible for everyone to earn an “A” or for everyone to earn an “F”. You have to get a passing grade on the final in order to pass the class. Your final course grade does not depend in any way upon anyone else's performance. Thus it is to your benefit to find a group of people you can study with and to help each other learn.

Grading

Course Element Percentage of Course Grade

Homework

25 %

Two Midterms

30 %

Final Exam

35 %

Quiz

10 %

Total

100 %

This newsgroup has been created so students can ask questions of each other and communicate with the TA on matters that might be of general interest to the class. The TA recommends that you post the questions you are planning to ask in the discussion section to the newsgroup. He will specifcally prepare for the most popular problems. According to CATS (no guarantee), you can use the newsgroup as follows:

1. Find a newsgroup reader, Microsoft OutLook/OutLook Express Can do this. Netscape Mail can do this.

2. Then create the NewsGroup account in Outlook/Netscape Mail. The server should be:" darkstar.ucsc.edu

3. Then try to find the newsgroup with the name ucsc.class.ee70, and subscribe the messages.

1) Do the reading before each lecture, the readings are listed for each lecture in the schedule below.

2) Read with a pencil and paper and try to do all the examples before you read their solutions. This is very valuable.

3) Seriously engage with all the homework problems, try them all before you work with someone else. There is no substitute for doing lots of problems to learn this material.

4) Make a copy of your homeworks and check your result against the solutions. Go back and figure out what you didn't understand.

5) This class is challenging and moves rapidly, falling behind is fatal. The results from one week will be used the next.

6) You need to be able to figure out what you don't understand and then ask your fellow students, the TAs, or the instructor for help if you cannot figure it out on your own.

8) You are encouraged to work in groups and discuss about the homework assignments. However, each has to write his/her own solution and fully understand them

Learning occurs by the active involvement of the student. Consequently there will be many different opportunities for active learning, such as cooperative problem-solving in lab. The student is expected to come to class prepared to think and learn. The lecture period will be used to establish fundamental concepts. The lab periods will be used to practice the engineering skills of problem-solving and data acquisition and analysis.

During both lab and lecture time, you will be asked to participate in solving problems. Always bring your calculator to both lab and lecture. It also is helpful to bring your textbook along.

To get the most out of this class, you need to read the assigned sections in the textbook before coming to class, and most importantly to read the assigned Lab Notes before coming to lab sections. There will be quizzes in the lab and lecture sessions.

Any confirmed academic dishonesty including but not limited to copying homeworks or cheating on exams, will result in a no-pass or failing grade. You are encouraged to read the campus policies regarding academic integrity. Examples of cheating include (but are not limited to):

Day	Start Lab Number	Lab Due Date
Jan 8
Jan 15	1
Jan 22	2
Jan 29		1
Feb 5	3	2
Feb 12
Feb 19	4	3
Feb 26
Mar 5	5	4
Mar 12
Mar 19		MARCH 21

The lab sessions take place in BE 113, times: 11:40-1:40 and 2:20-4:20. The TA will be present throughout the day.

Each lab report is to be submitted to the TA on the day shown above. For each day that the report is late, 5% will be subtracted from the grade.

Clarification for passing the lab: You will need to pass the lecture in order to pass the lab.

The lab reports should be prepared according to the following guide lines: Lab report format

Solutions are posted here on the date of collection. Thus, late homework will not be accepted or graded.

Graded homework is placed in the top right drawer of the printer desk in the lab. You can pick them up there.

The reading assignment should be completed prior to the lecture, come prepared for quizzes about the previous lectures.

Quizzes will be unannounced and be given at the beginning of a lecture. They cannot be made up if you are late for class or can't make it to class for any other reason.

Date	Lect.	Topic	Reading Assignment
Jan 7	1	Introduction/ Overview, Circuit elements	1.1-1.3, 1.6,1.7
Jan 9	2	Circuit laws, Voltage and current divider	1.4,1.5,2.1-2.3
Jan 14	3	Node/loop analysis	2.4,2.5
Jan 16	4	Networks (Thevenin/Norton), Non-linear elements, Power	2.6-2.8
Jan 21	5	Amplifiers, Op Amps	11.1-11.3,14.1
Jan 23	6	Op-Amp Circuits	14.2-14.4
Jan 28	7	Midterm 1
Jan 30	8	Inductance & Capacitance, First order transient response	3.1-3.6, 4.1,4.2
Feb 4	9	RC/RL circuits, Time-dependent op amp circuits	4.3, 4.4. 14.10
Feb 6	10	Second order transient response	4.4,4.5
Feb 11	11	No class, advising day!!
Feb 13	12	Sinusoidal signals, complex numbers, phasors	5.1-5.3, Appendix A
Feb 18	13	Phasor circuits, AC power, Thevenin	5.4-5.6
Feb 20	14	Midterm 2
Feb 25	15	Fourier analysis, low pass filters, decibels, Bode plot	6.1-6.4
Feb 27	16	High pass filters, 2nd order filters. active filters, resonances	6.5-6.6, 14.11
Mar 4	17	Transformers	15.1-15.5
Mar 6	18	Diodes	10.1,10.2,10.4-10.7
Mar 11	19	Field effect transistors	12.1-12.3
Mar 13	20	FET transistor circuits, FET logic	12.4,12.5,12.7
Mar 19		Final Exam, 4-7 pm

Lecture	Tu-Th 4 pm - 5:45 pm, Porter 144
Instructor	Holger Schmidt
Office	157B Baskin Engineering Building
Phone	(831) 459-1482
Email	hschmidt@soe.ucsc.edu
Office Hours	Mo 1-2 pm, Wed 1:30-2:30 pm
TA	John Wang, johndape@cse.ucsc.edu
Grader	Tam Nguyen
Required text	A. R. Hambley, Electrical Engineering Principles and Applications, Prentice Hall, 2002, 2nd Edition.
Recommended texts	The Art of Electronics by Paul Horowitz, Winfield Hill, 2nd edition (1989); Cambridge Univ Press (Short); ISBN: 0521370957 Schaum's Outline of Basic Circuit Analysis by John O'Malley (plenty of solved problems!), McGraw-Hill; ISBN: 0070478244 Basic Engineering Circuit Analysis by J. David Irwin; John Wiley & Sons; ISBN: 0471381314 Electrical Engineering : An Introduction, Steven E. Schwarz,William G. Oldham, Oxford University Press, Pub. Date: October 1995
Discussion section	in front of the whiteboards in Baskin Engineering (Jack's lounge). Time: Monday 2-4 pm
Lab sessions	Baskin Engineering building room 113, Time: Wed 11:40-1:40 pm and Wed 2:20-4:20 pm

Grading
Course Element	Percentage of Course Grade
Homework	25 %
Two Midterms	30 %
Final Exam	35 %
Quiz	10 %
Total	100 %