[vc_row el_class=”inner-body-content” css=”.vc_custom_1667282390690{padding-top: 30px !important;padding-bottom: 20px !important;}”][vc_column][vc_custom_heading text=”COURSE OBJECTIVES” use_theme_fonts=”yes” css=”.vc_custom_1667282376659{margin-top: 0px !important;}”][vc_column_text]

This course is meant to reinforce a good understanding of the fundamentals of electrical engineering through practical applications. Starting from Ohm’s law, and the Kirchhoff’s laws, basic analysis techniques are taught. Important laws of circuit analysis are explained using passive circuit elements.

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CLO-1: Illustrate knowledge of primary electronic lab instruments including DMM, Function Generator, Oscilloscope and electronic trainer. (P2)

CLO-2: Show knowledge of constructing electronic circuits and simulating their results using PSPICE. (C3)

CLO-3: Design a basic electronic circuit and investigate effect of different changes on the final outcome. (C6)

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• Experiment # 1
  • Introduction to lab instruments
• Experiment #2
  • Series and parallel circuits
• Experiment #3
  • Ohm’s Law
• Experiment # 4
  • Kirchhoff’s voltage and current law
• Experiment # 5
  • Superposition theorem
• Experiment # 6
  • Thevenin Theorem
• Experiment # 7
  • Maximum Power Transfer Theorem
• Experiment # 8
  • Introduction to PSPICE
• Experiment # 9
  • Transient Analysis using PSPICE
• Experiment #10
  • AC analysis using PSPICE.
• Experiment # 11
  • AC signal and measurements
• Experiment # 12
  • RC circuit and filter
• Experiment # 13
  • Series resonant circuit
• Experiment # 14
  • Parallel resonant circuit

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