ECE 29595 - Electrical & Computer Engineering Fundamentals II (Now runs as ECE 20002)
Course Details
Lecture Hours: 3 Credits: 3
Counts as:
- EE Core
- CMPE Core
Experimental Course Offered:
Spring 2018, Spring 2019
Requisites:
ECE 29595 Electrical and Computer Engineering Fundamentals I (Minimum Grade of C) and MA 26200 [may be taken concurrently] or MA 26600 [may be taken concurrently] or MA 366 [may be taken concurrently]).
Requisites by Topic:
Prerequisites: Elementary linear circuit analysis including dc, transient, and phasor techniques. Concurrent Prerequisites: Differential equations.
Catalog Description:
Continuation of Electrical and Computer Engineering Fundamentals I. The course addresses mathematical and computational foundations of circuit analysis (differential equations, Laplace Transform techniques) with a focus on application to linear circuits having variable behavior as a function of frequency, with emphasis on filtering. Variable frequency behavior is further considered for applications of electronic components through single-transistor and operational amplifiers. The course ends with consideration of how circuits behave and may be modeled for analysis at high frequencies.
Required Text(s):
- Class notes will be provided in class.
Recommended Text(s):
None.
Learning Outcomes:
- an ability to analyze 2nd order linear circuits with sources and/or passive elements.. [1]
- an ability to compute responses of linear circuits with and without initial conditions via one-sided Laplace transform techniques.. [1]
- an ability to compute responses to linear circuits using transfer function and convolution techniques.. [1]
- an ability to analyze and design transistor amplifiers at low, mid and high frequencies.. [1]
- an ability to work with transmission line models to analyze circuits at high-frequency.. [1]
- the ability to use a CAD tool (e.g., SPICE) in circuit analysis and design.. [1]
Lecture Outline:
| Lecture | Lecture Topics |
|---|---|
| 1 | OpAmps-operation (gain, input/output resistance, common-mode) |
| 2 | Field-Effect Transistor devices; DC review; Current mirror example |
| 3 | FET small signal models; Active loads |
| 4 | Common Source amplifier (mid-frequency behavior) |
| 5 | Common Drain and Common Gate amplifiers (mid-frequency behavior) |
| 6 | Single-stage amplifier time constants for low-/high-freq response |
| 7 | OpAmp model using FETs |
| 8 | ODE models for circuits and the solutions thereof |
| 9-12 | RC/RL/LC/RLC circuits with and without initial conditions |
| 13 | Modeling of switching in circuits using initial conditions |
| 14 | Impulse response, h(t), from the step response |
| 15 | Circuit modeling using h(t); Intro to convolution |
| 16-18 | Convolution integral and properties; Convolution examples and graphical interpretation; convolution algebra and examples |
| 19-22 | Laplace Transform definition and basic pairs; Duality with time-domain; Properties of Laplace Transform; Inverse Laplace Transform via partial fraction expansion |
| 23-24 | Impedance; Admittance; LT solution of ODEs for "at rest" circuits; Incorporation of initial conditions in LT analysis |
| 25 | Transfer function, H(s) |
| 26 | System analysis in frequency and time domains |
| 27 | Response decomposition, steady-state analysis |
| 28 | Complex plane concepts, pole/zero plots, stability |
| 29-30 | Frequency response; Frequency and magnitude scaling |
| 31-35 | Resonance; 2nd-order systems; Passive BPF/LPF/HPF and design |
| 36 | Implications of duality for passive filters; Passive filter examples |
| 37-38 | Active LPF/HPF with real and complex poles; Duality in active filters and examples |
| 39 | Non-ideal components; Wave equation in conductors |
| 40-41 | Frequency dependence of transmission line impedance, velocity; Frequency dependence of reflection; Effect on input impedance |
Engineering Design Content:
- Analysis
Assessment Method:
Three exams, final exam, homework, Circuit simulation projects