The subject aims to provide the student with:
1. An understanding of basic EE abstractions on which analysis and design of
electrical and electronic circuits and systems are based, including lumped circuit,
digital, and operational amplifier abstractions.
2. The capability to use abstractions to analyze and design simple electronic
circuits.
3. The ability to formulate and solve the differential equations describing
time behavior of circuits containing energy storage elements.
4. An understanding of how complex devices such as semiconductor diodes and
field-effect transistors are modeled and how the models are used in the design and
analysis of useful circuits.
5. The capability to design and construct circuits, take measurements of
circuit behavior and performance, compare with predicted circuit models, and explain
discrepancies.

Introduction, KVL, and KCL
Node Analysis
Linearity and Superposition
Thevenin and Norton Equivalence
Digital Abstraction and Logic
MOS Switches and Digital Logic
Nonlinear Resistors
Nonlinear Resistors and Small Signals
Dependent Sources and Amplifiers
MOS Amplifiers and Biasing
Small-Signal Analysis
Small Signal Circuit Models
RC Networks and Step Responses
RL Networks and Step Responses
Digital Circuit Delay
Transient Response Relations
Digital Memory
Digital Memory, ZIR, and ZSR
LC Networks and Responses
RLC Networks and Responses
Examples*
SSS and Frequency Response
Impedance and Admittance, Examples*
Filters, RLC Network SSS, and Q
Op-Amps and Amplifiers
Add, Sub, Int, and Diff
Positive Feedback
Op-Amp Filters
Energy and Power in Digital Logic
MOS Differential Amplifiers
Intro to CMOS
CMOS Examples
Diodes and Power Electronics
Diodes, RC, and LC Networks
Violating the Abstraction Barrier