Untitled Quiz

Questions and Answers

What is a primary function of a Zener diode?

• Voltage regulation (correct)
• Amplification
• Rectification
• Switching

The BJT CE amplifier configuration is known for providing high current gain.

True (A)

Name two types of circuits that utilize logic gates.

Arithmetic circuits, multiplexers.

A _____ is used to convert digital signals to analog signals.

DAC (Digital-to-Analog Converter)

Match the following components with their function:

Flip-flop = Data storage Decoder = Signal conversion Multiplexer = Data selection Encoder = Data encoding

Which of the following is NOT a Boolean operation?

SUM (B)

The primary purpose of a half-wave rectifier is to convert AC to DC.

True (A)

What is the role of a decoder in digital circuits?

A decoder converts binary information from the encoded inputs to unique outputs.

Which law states that the current entering a junction equals the current leaving the junction?

Kirchhoff's Current Law (A)

Thevenin's Theorem allows for the simplification of a complex circuit.

True (A)

What is the primary use of a rectifier in circuits?

To convert alternating current (AC) to direct current (DC).

The maximum power transfer theorem states that maximum power is transferred when the load resistance is equal to the ______.

Thevenin resistance

Match the following circuit analysis concepts with their corresponding definitions:

Ohm's Law = V = IR Voltage Division Rule = Used to calculate voltage drops across components in series Norton’s Theorem = Simplifies a circuit into a current source and parallel resistor Mesh Analysis = A method using loop currents to analyze circuits

Which type of motor is associated with single-phase and three-phase systems?

Induction motor (C)

The RMS value of an AC waveform is always higher than its peak value.

False (B)

Name one application of electromagnetic induction in electrical machines.

Electric generators.

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Study Notes

Course Details

• Course Code: EEE1001
• Course Title: Electric Circuits and Systems
• Credit Hours: 4
• Prerequisites: None
• Course Objectives:
  • Analyze voltages and currents within electrical circuits
  • Comprehend the operation principles of electrical machines and transformers
  • Develop familiarity with fundamental semiconductor devices
  • Understand the logic of combinational and sequential circuits
  • Grasp the construction and function of electronic devices and circuits
• Course Outcomes:
  • Gain knowledge in the principles of electric circuits, electronic devices and electrical machines
  • Student Outcomes (SO): a, b, c, e, i, k

Teaching and Learning

• Mode: Flipped Classroom, Activity-Based Learning, Digital/Computer-based models
• Lectures: Industry experts provide minimum 2 hours on contemporary topics

Evaluation

• Assessment:
  • Unannounced open book exams
  • Quizzes
  • Portfolio generation and assessment
  • Innovative assessment practices
• Continuous Assessment:
  • Tests
  • Term End Examination

Textbook

• Main Text: S.K. Bhattacharya, 'Basic Electrical and Electronics Engineering', Pearson Publications, 1st Edition, 2011.

Reference Textbooks

• Allan R. Hambley, 'Electrical Engineering-Principles & Applications' Pearson Education, First Impression, 6th Edition, 2013.
• P.S. Bimbhra, "Electrical Machinery", Khanna Publishers, 2003.
• Charles K Alexander, Mathew N.O Sadiku, 'Fundamentals of Electric Circuits', McGraw Hill, 5th Edition, 2012.
• Thomas L. Floyd, 'Digital Fundamentals', Pearson Education, 10th Edition, 2010.
• William H. Hayt Jr. Jack E. Kemmerly, Jamie D. Phillips, Steven M. Durbin, Electric Circuit Analysis, McGraw Hill, 9th Edition, 2020
• Adel S Sedra, Kenneth C Smith, Chandorkar, Microelectronic Circuits, Theory and Applications, Oxford Press, 7th Edition, 2017.

Modules

• Module 1 - Electric Circuits:
  • Topics:
    • DC Circuit Analysis:
      • Ohm's Law, voltage and current division rule
      • Kirchhoff's Current and Voltage Laws (KCL, KVL)
      • Series and parallel circuits
      • Star-Delta Conversion
      • Mesh and Nodal Analysis
    • Network Theorems:
      • Superposition Theorem
      • Thevenin's Theorem
      • Norton's Theorem
      • Duality Theorem
      • Maximum Power Transfer Theorem
      • Voltage and Current Sources
  • Hours: 9
  • Student Outcomes: a, b, c, e
• Module 2 - AC Circuits Analysis
  • Topics:
    • Fundamentals of AC Waveforms:
      • Average, RMS, Peak
    • AC Circuit Analysis and Phasors:
      • RL, RC, RLC series and parallel circuits
      • Resonance
    • Natural and Forced Responses:
      • First Order Systems
      • Second Order Systems
  • Hours: 8
  • Student Outcomes: a, c, e
• Module 3 - Magnetic Circuits
  • Topics:
    • Magnetic Coupled Circuits:
      • Analogy between electric and magnetic circuits
      • Series and parallel magnetic circuits
      • Electromagnetic Self and Mutual Induction
    • Applications of Electromagnetism:
      • DC Motor & Generator
      • Single-Phase and 3-Phase Induction Motors
      • Transformers
  • Hours: 9
  • Student Outcomes: a, b, c, e
• Module 4 - Semiconductor Devices
  • Topics:
    • Introduction to Semiconductors
    • PN Junction Diode:
      • Construction and operation with characteristics
    • Rectifiers:
      • Half-Wave and Full-Wave rectifiers
    • Zener Diode:
      • Construction and operation with characteristics
    • Zener Regulator
    • BJT:
      • CE Amplifier Configuration
      • Characteristics
    • MOSFET
  • Hours: 9
  • Student Outcomes: a, b, c, e
• Module 5 - Digital and Logical Systems
  • Topics:
    • Number systems and conversion
    • Boolean Algebra
    • Logic Gates and Universal Gates
    • Arithmetic Circuits
    • MUX/DEMUX, Decoder/Encoder
    • Flip-flops
  • Hours: 8
  • Student Outcomes: a, b, c, i
• Module 6 - Guest Lecture
  • Topics: Contemporary Topics in Electrical Engineering
  • Hours: 2
  • Student Outcomes: k

Experiments

• Experiments:
  • Analysis of circuit parameters using mesh, nodal, and network theorems
  • Analysis of Magnetic Circuits and resonance
  • IV Characteristics of PN Junction Diode
  • IV Characteristics of Zener Diode
  • Rectifier circuits (half-wave, full-wave, bridge rectifier)
• Student Outcomes: a, b, c, e, i