Mar 28, 2024  
Official Course Syllabi 2020-2021 
    
Official Course Syllabi 2020-2021 [ARCHIVED CATALOG]

Add to Favorites (opens a new window)

ELEC 1182 - Semiconductor Theory & Devices

Credit Hours: 3.00


Prerequisites: ELEC 1171

(formerly ELEC 1181)

ELEC 1182 provides students with the knowledge required to understand and troubleshoot electronic circuits containing diodes, transistors, FETs, and MOSFETs. Among the topics discussed are Thevenin’s Theorem, semiconductor theory, half-wave and full-wave rectifiers, transistor biasing circuits, FET and MOSFET biasing. Students will learn through lecture, textbook assignments, hands-on laboratory experimentation, and simulated virtual experiments utilizing computer software.

Location: South Campus

Contact Hours: 8 per week for 8 weeks
Billable Contact Hours: 4
OUTCOMES AND OBJECTIVES
Outcome 1: Upon completion of this course students will be able to analyze electronic circuits utilizing Thevenin’s Theorem.

Objectives:

  1. Given an electronic schematic of a series circuit the student will calculate the Thevenin voltage and resistance of the circuit.
  2. Given an electronic schematic of a parallel circuit the student will calculate the Thevenin voltage and resistance of the circuit.
  3. Given an electronic schematic of a series-parallel circuit the student will calculate the Thevenin voltage and resistance of the circuit.

Outcome 2: Upon completion of this course students will be able to apply knowledge of semiconductor physics toward the analysis and evaluation of electronic circuits containing semiconductor devices.

Objectives:

  1. Apply knowledge of the basic structure of semiconductor materials toward the analysis of semiconductor circuits.
  2. Demonstrate biasing of a PN junction.

Outcome 3: Upon completion of the course the student will be able to analyze, build and take measurements in electronic circuits which contain diodes.

Objectives:

  1. Students will construct, analyze, and evaluate the operation of:
    1. Half wave and full wave rectifiers.
    2. Rectifier circuits which utilize electronic filtering.
    3. Diode limiters and clampers.
    4. Zener diodes
    5. Varactor diodes.
    6. Light emitting diodes and photo diodes.
  2. Interpret diode data sheets and apply that data to the analysis of circuitry.
  3. Troubleshoot and repair faults in power supplies and diode circuits.

Outcome 4: Upon completion of the course the student will be able to analyze, build and take measurements in electronics circuits which contain transistors.

Objectives:

  1. Students will construct, analyze, and evaluate the operation of:
    1. Bipolar transistor biasing circuits.
    2. Bipolar transistor switching circuits.
    3. Junction Field Effect Transistor biasing circuits.
    4. Metal Oxide Semiconductor Field Effect Transistor biasing circuits.
  2. Identify for specific purposes BJT, FET, and MOSFET package configurations.

COMMON DEGREE OUTCOMES
(Bulleted outcomes apply to the course)

  • 1. The graduate can integrate the knowledge and technological skills necessary to be a successful learner.
  • 2. The graduate can demonstrate how to think competently.
  • 3. The graduate can demonstrate how to employ mathematical knowledge.
  • 4. The graduate can demonstrate how to communicate competently.
  1. The graduate is sensitive to issues relating to a diverse, global society.

COURSE CONTENT OUTLINE
  1. Thevenin’s Theorem
    1. Series circuits
    2. Parallel circuits
    3. Series-parallel circuits
  2. Introduction to Semiconductors
    1. Atomic structure
    2. Hole flow and electron flow
    3. N-type and P-type
    4. PN junctions
    5. Diode characteristics
  3. Diode Applications
    1. Half wave rectifiers
    2. Full wave rectifiers
    3. Filters and regulators
    4. Limiting and clamping circuits
    5. Special purpose diodes
      1. zener diodes
      2. varactor diodes
      3. Light Emitting Diodes
      4. Photodiodes
    6. Diode data sheets
    7. Troubleshooting diode circuits
  4. Transistors
    1. Bipolar Junction Transistors
    2. Junction Field Effect Transistors
    3. Metal Oxide Semiconductor Field Effect Transistors
    4. Biasing transistors
    5. Transistor packaging and terminal identification

Primary Faculty
Dulinski, Kenneth
Secondary Faculty

Associate Dean
Hinrichsen, Timothy
Dean
Hutchison, Donald



Official Course Syllabus - Macomb Community College, 14500 E 12 Mile Road, Warren, MI 48088



Add to Favorites (opens a new window)