1. Home
2. [NCC] NCC Engineering Programs

EEE202 CIRCUITS THEORY II

Course Objectives

Let the students learn about the phasor domain and the complex frequency domain analyses of linear time-invariant dynamic lumped circuits;the characterizations of such circuits in the above-mentioned domains.

Course Content

Sinusoidal steady-state analysis. Three-phase circuits. Coupled inductors. Frequency response. Linear time-invariant dynamic circuits: state equations, natural frequencies, complex frequency domain analysis. Time-varying and nonlinear circuits.

Course Learning Outcomes

Having successfully completed this course, the student will be able to:

• Transform a circuit to frequency domain using phasor concepts and apply circuit analysis techniques (node-voltages method, mesh-currents method, source transformations, Thevenin and Norton conversions, and superposition) to determine the sinusoidal steady state response.
• Calculate instantaneous power, average power, reactive power, complex power and power factor in a circuit, and analyze the loading requirements for a circuit for maximum power transfer. 
• Identify and analyze mutual inductance circuits, ideal and linear transformers together with power calculations.
• Identify and analyze balanced three-phase circuits together with power calculations.
• Transform a circuit to frequency domain using Laplace transform (LT) and apply LT techniques for circuit analysis to determine the transient and steady state responses; identify transfer functions, magnitude and frequency response of transfer functions.
• Identify ideal filters, cutoff frequency, gain, and transition width concepts of filters; obtain frequency response of passive filters; design and test passive filters.
• Obtain frequency response of opamp based active filters; design and test active filters.
• Calculate two-port parameters and analyze terminated two-port circuits.