Outline of EE100:

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Outline of EE100

• Text Electrical Engineering Principles and
  Applications,
• 3rd Edition, by Allan R. Hambley
• Prerequisites
• Physics 42 with 22 or 125
• Goals
• To understand and be able to analyze the
  operation of basic digital and analog electronic
  circuits and motors and generators used in modern
  computer, communications, transportation,
  manufacturing, medical, entertainment and
  education systems.
• To help prepare for the FE exam.
• Prerequisite for EE101 in the second semester

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Course Content

• Chapter 1 Introduction
• Kirchhoffs Law
• Circuits Elements
• Chapter 2 Resistive Circuits
• Resistance in Series and Parallel
• Node-Voltage Mesh-Current
• Circuits Network Analysis
• Chapter 3 Inductance and Capacitance
• Capacitance
• Inductance
• Chapter 4 Transients
• First Order RC circuits RL circuits
• Second Order circuits

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Course Content

• Chapter 5 Steady-State Sinusoidal Analyses
• AC (phasor) analysis of simple circuits with
  resistors, inductors and capacitor.
• Three-phase circuits
• Chapter 6 Frequency Response, Bode Plots and
  Resonance
• Fourier analysis applied to circuits
• Transfer functions and simple low-pass and
  high-pass filters
• Digital-to-analog and analog to digital
  conversion
• Chapter 7 Logic Circuits
• Basic logic blocks AND, OR, INVERT, NAND, NOR
  and XOR
• Flip flops, latches, shift registers and
  counters
• Chapter 8 Microcomputers
• Concept of the stored program computer
  organization
• ALU, Control Unit, Buses and Memory
• The Motorola 68HC11/12 Quick overview of
  structure and organization
• Chapter 9 Computer-Based Instrumentation Systems
• Very quick overview, because of time limits

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• Chapter 10 Diodes
• Structure and electrical characteristics of
  diodes
• Graphical load line analysis of diode/resistor
  circuits
• Zener diodes and application for voltage
  regulator
• Circuit analysis using simplified models for the
  diodes
• Half-wave and full-wave rectifier circuits
• Clipper and clamping circuits
• Small signal linear analysis using circuits
  with diodes
• Chapter 11 Amplifiers Specifications and
  External Characteristics
• Terminal characteristics
• Multistage or cascaded amplifier stages
• AC and DC amplifiers
• Chapter 12 Field Effect Transistors
• Structures and current equations for MOSFETs
• Load line analysis of simple MOSFET-resistor
  circuits
• Design and operation of a NMOS and CMOS logic
  circuits
• Small signal operation and analysis for
  amplifiers, etc.
• Survey of DRAM, SRAM and Flash memory circuits

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• Chapter 13 Bipolar Junction Transistor
• Structures and equations of operation
• Simple amplifier or inverter circuit using load
  line analysis
• Emitter followers
• Chapter 14 Operational Amplifiers
• Ideal op amps and practical limitations
• Instrumentation using op amps
• Active filters
• Chapter 15 Magnetic Circuits and Transformers
• Basics of magnetic fields
• Transformers
• Chapter 16 DC Machines
• Overview of AC and DC motors
• Principles and analysis of DC motors and
  generators
• Chapter 17 AC Machines
• Three phase induction motors
• Synchronous motors, single phase motors and
  stepper motors

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Chapter 1. Introduction
Part 1 Circuits

• Recognize interrelationships of electrical
  engineering with other fields of science and
  engineering.
• 2. List the major subfields of electrical
  engineering.
• 3. List several important reasons for studying
  electrical engineering.

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4. Define current, voltage, and power, including
their units. 5. Calculate power and energy, as
well as determine whether energy is supplied or
absorbed by a circuit element. 6. State and
apply basic circuit laws. 7. Solve for currents,
voltages, and powers in simple circuits.
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1.1 Electrical systems have two main objectives

• To gather, store, process, transport, and present
  information
• To distribute and convert energy between various
  forms

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Electrical Engineering Subdivisions

• Communication systems
• Computer systems
• Control systems
• Electromagnetics
• Instrumentation

• Electronics
• Photonics
• Power systems
• Signal processing
• Sensor

Computer System includes Intelligent Machinery
such as Robotics
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Why Study Electrical Engineering?

• To pass the Fundamentals of Engineering (FE)
  Examination
• So you can lead projects in your own field
• To be able to operate and maintain electrical
  systems
• To communicate with electrical engineering
  consultants

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Correspond
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1.2 Electrical Current

• Electrical current is the time rate of flow of
  electrical charge through a conductor or circuit
  element. The units are amperes (A), which are
  equivalent to coulombs per second (C/s).

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Electrical Current
Electrical Current flow
Net Charge
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Reference Direction
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Direct Current Alternating Current

• When a current is constant with time, we say
  that we have direct current, abbreviated as dc.
  On the other hand, a current that varies with
  time, reversing direction periodically, is called
  alternating current, abbreviated as ac.

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Double-Script Notation for Current
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Voltages

• The voltage associated with a circuit element
  is the energy transferred per unit of charge that
  flows through the element. The units of voltage
  are volts (V), which are equivalent to joules per
  coulomb (J/C).

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POWER AND ENERGY
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KIRCHHOFFS CURRENT LAW

• The net current entering a node is zero.
• Alternatively, the sum of the currents entering a
  node equals the sum of the currents leaving a
  node.

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KIRCHHOFFS VOLTAGE LAW

• The algebraic sum of the voltages equals zero
  for any closed path (loop) in an electrical
  circuit.

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Resistors and Ohms Law
a
b
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Conductance
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Resistance Related to Physical Parameters
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Using KVL, KCL, and Ohms Law to Solve a Circuit
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