ECE53A Fundamentals of Electrical Engineering

Fall 2007, Instructor: CK Cheng

Class Schedule

• Lecture: Center 105, TTh 2-3:20PM
• Discussion: WLH 2204, W 4-4:50PM
• Hardware Labs: EBU2 333A, M 10-1PM, M 5-8PM, W 5-8PM (group of 2 or less person)
• PSpice Simulation: EBU2 329
• Midterm 1: Tu 10/16/2007
• Midterm 2: Tu 11/13/2007
• Midterm 3: Th 11/27/2007
• Final: Th 3-6PM, 12/13/2007

Instructor, TA and Tutor

• Instructor: CK Cheng
• Office: CSE 2130
• CKCheng at ucsd dot edu
• Office Hours: TTh 330-420PM
• TA: Shibin Parameswaran
• sparames at ucsd dot edu
• Tutor: York Hung
• cyhung at ucsd dot edu

Schedule of the Week of Final

• CK: 330-430PM, TW, CSE2130.
• York: 10AM-12PM, W, Hardware Lab.
• Shibin: 5-7PM, M, Hardware Lab.
• Review Session: 5-630PM, T, WLH2114.
• Final: 3-6PM, Th, 12/13/2007.

Course Textbooks

• Required: Foundations of Analog and Digital Electronic Circuits, Anant Agarwal and Jeffrey H. Lang, published by Morgan Kaufmann
• Recommended: SPICE Second Edition, Gordon W. Roberts and Adel S. Sedra, published by Oxford

Tentative Coverage

Chapter 1 circuit abstraction

Digital components: Power, Clock, Bus, CPU, Memory, Interface

Chapter 2 resistive networks

Voltage sources, current sources, wires, voltage drops

Chapter 3 network theorems

Circuit analysis: admittance matrix, serial-parallel reduction, Y Delta transformation, superposition, equivalent circuits.

Chapter 6 mosfet switch

The regions of operations

Chapter 9 energy storage elements

Foundation of memory storage, Equivalent circuit of dynamic behavior, concept of moments

Chapter 10 first-order linear system

Gate delay, and wire delay due to RC effect

Chapter 11 energy and power

The consumption of power in digital circuits

Chapter 12 second-order circuits

Power network resonances, digital signal overshoots

Exercises from Textbook:

1. Exercises 1.2, 2.3, 2.8, 2.9, Problems 2.7, 2.8, 2.11, 2.12, 2.17.

2. Derive the Y Delta transformation to reduce a 5-node resistive circuit to a circuit of 4 nodes.

3. Odd numbered exercises and problems in chapter 3.

4.1 Use Complementary CMOS Logic to design the following Boolean functions, (A+B)', (AB)', (A+BC)', [A(B+C)]'.

4.2 Use transmission gate to design the following Boolean functions, (A+B)', (AB)', (A+BC)', [A(B+C)]'.

4.3 Problems 7.8, 7.9, 7.12, 7.13, 7.17.

5. Exercises 9.1, 10.4, 10.11, 10.14, 11.1 Problems 9.7, 9.8, 9.10, 10.1, 10.7.

6. RLC Circuits I, W. Ku 11/29/07 revised 12/4/07.

7. RLC Circuits II, W. Ku 12/4/07.

8. Exercises 12.1, 12.2, 12.3, 12.4, 12.5, 12.8

Exam Solutions:

• Midterm 1 Solution
• Midterm 2 Solution
• Midterm 3 Solution
• Final Solution

Hardware Laboratories:

• Lab Policy
• Lab 1: Basic Instruments
• Lab 2: Eqivalent Circuits
• Lab 3: MOS Logic Gates
• Lab 4: Low Pass RC Lines

Grading Information:

• The grade will be based on Labs reports, two midterms, and a final, as follows:
• Labs: 20%
• Midterms: The best two of the three midterms. Each weights 20%
• Final: 40%
• subjective influences like class participation will have an impact in the margins -- it does pay to let the professor know who you are!