Apr 20, 2024  
2018-2019 Undergraduate Catalog 
    
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2018-2019 Undergraduate Catalog [ARCHIVED CATALOG]

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EET 426 - Advanced Electrical Network

Description:
Analysis of continuous-time linear time-invariant systems using Laplace transforms. Topics include the forward and inverse Laplace transform, system response and stability, transfer functions, and state variable modeling. Formerly EET 324, students may not receive credit for both. Four hours of lecture per week. Course will be offered every year (Winter).

Prerequisites:
Prerequisite: EET 325.

Credits: (4)

Learner Outcomes:
Upon successful completion of this course, the student will be able to:

  • Demonstrate an ability to analyze analog circuits using the Laplace transforms given time domain functions crated from given circuits.
  • Demonstrate an ability to analyze analog circuits using the inverse Laplace transforms given s-domain functions.
  • Demonstrate an ability to create time domain analog circuit models then applying Laplace transform methods to analysis of complete analog circuit solutions.
  • Demonstrate an ability to analyze circuit operations and characteristics using analog circuits transfer functions.
  • Demonstrate an ability to analyze and optimize analog circuit designs by determining the poles and zeros of the circuits transfer function to evaluate their effect on the systems stability.
  • Demonstrate an ability to develop state-variable models to analyze the transient and steady-state behavior of a circuit.


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