# EECS 70B Network Analysis II (2013-2014)

#### EECS 70B Network Analysis II

**EECS 70B Network Analysis II (Credit Units: 4)** Laplace transforms, complex frequency, and the s-plane. Network functions and frequency response, including resonance. Bode plots. Two-port network characterization. Corequisite: EECS70LB. Prerequisite: EECS10, CEE10, or MAE10; EECS70A. Computer Engineering, Electrical Engineering, and Materials Science Engineering majors have first consideration for enrollment. (Design units: 1)

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1. Use mathematical tools for analyzing linear RLC circuits. (EAC a, EAC k)

2. Describe the steps involved in the design of frequency selective circuits and resonance. (EAC a, EAC k)

3. Describe the concept of log-log Bode plots and use them in analyzing frequency response of RLC circuits. (EAC a, EAC k)

4. Explain the use of two-port network models in analyzing complex linear circuits. (EAC a, EAC k)

- Understanding of basic RLC circuits.
- Understanding of Op Amps, dependent sources, independent sources and energy-storage elements.
- Understanding of first and second order linear RLC circuits.

This course is aimed at the use of transform methods (phasor, Fourier, and Laplace) to analyze sinusoidal steady-state response, complete responses, interconnections, and stability of liner RLC circuits.

Meets for 3 hours of lecture and 1 hour of discussion each week for 10 weeks.

Students are required to use PSCPICE circuit simulations software and scientific calculator. Students also use Mathematica to solve circuit related problems

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Contributes toward the Computer Engineering Topics Courses and the Electrical Engineering Topics Courses and Major Design experience.

Three weeks of this course are devoted to elementary design of linear circuits. In particular, time is devoted to: the design of voltage and current dividers; the design of basic operational amplifier circuits, including voltage followers, summers, and inverting summers, and feedback amplifiers; the design of basic RLC networks; and the design of basic frequency selective RLC networks.

- 8 Problem sets: 10%
- 2 Midterm exams: 60%
- Comprehensive Final Exams: 30%
- Total: 100%

Mathematics and Basic Science: 0.0 credit units

Computing: 0.0 credit units

Engineering Topics: 4.0 credit units

Engineering Science: 3.0 credit units

Engineering Design: 1.0 credit units