Dr

Welcome to your EE207 Homepage. It is a pleasure to have you in this course.
A good start is needed. This course is very fundamental to many other courses and concepts in our life.

Matlab will be an integrated part of the course. It will be mostly self-learning tool. Start today by installing Matlab in your machine or find yourself a convenient access to it.

I pray Allah that you will find this course fruitful and enjoyable.

Best Regards,
Dr. Ali Muqaibel

Class Notes

Class Notes (Make sure you take your own notes in the class as not all notes will be posted. Your instructor will indicate the material that comes directly from the text to reduce the amount of writing. You are encouraged to read the textbook)

Chapter 1 & 2: Introduction

Tentative Notes (Please this does not substitute the book) (Ch1 & 2 pdf)
Matlab example for the sum of periodic signals, another Example (Matlab file)
Additional Examples for Graphical Convolution
Graphical Convolution (Power Point Presentation)
The Joy of Convolution (Link to another Website)

Chapter 3: LTI Systems and Convolution

Tentative Notes (Updated Notes )

Chapter 4: Fourier Series

Updated Notes (Please this does not substitute the book) (Fourier Series pdf 3/16/2013)
Matlab Examples to demonstrate FS (see figures below) (zip)
Visit Johns Hopkins University Signal Website:
- Fourier Series Approximation
- Listen to Fourier Series

Chapter 5: Fourier Transform

Fourier Transform Pairs (jpg)
Fourier Transform Properties (jpg)
Time Transformed Rectangular pulses and their Frequency Spectra (jpg)
Examples for integration/ differentiation properties and F.T. of periodic signals (pptx)
Tentative Notes (Please this does not substitute the book) (Fourier Transform pdf)

Chapter 6: Application of the Fourier Transform (ppt)

Chapter 7: Laplace Transform

Laplace Transform Pairs (jpg)
Laplace Transform Properties (jpg)
Tentative Notes (Please this does not substitute the book) (Laplace Transform pdf)
Explore the S-Domain (Link to JHU website)

Discrete Signals

Sampling (5.4) (docx)
Signal recovery (6.4) (pdf)
Discrete Time LTI Systems with Introduction (pdf)
Z-Transform (part1 , part 2)

___________________________________________________

Notes from the previous textbook are posted below

Check Course WebCT

Chapter 1: Introduction
- Chapter I_ Signal and System Modeling (pdf)
- Matlab for example_1_6.m: Is the sum of two sinusoids periodic?
Chapter 2: System Modeling & Analysis in the Time Domain
Chapter 3: The Fourier Series
- Matlab Examples to demonstrate FS (see figures below) (zip)
- Coefficients for complex exponential F.S. of Several Signals (Table 3.1) (jpg)
- Summary of F.S. Properties (Table 3-2: Print and Post in your room!)
- Additional Example and Practice Problem about Exponential F.S.
- Spectral lines for Periodic Pulse Train Signal (Figure 3-11 from the text)
- Example (3-12) from the text: Steady State Response of a Fixed, LTI distortionless system
- Visit Johns Hopkins University Signal Website (Fourier Series Approximation, Listen to Fourier Series)

Chapter 4: Fourier Transform & Applications
- Fourier Transform Theorem Table 4_1 (jpg)
- Fourier Transform Pairs Table 4_2 (jpg) *You should memorize (1,2,4,8-13,18)
- Example Ch4ex20.m, Fourier Transform of Spectrum of Periodic Signals: Output Figure(jpg)
Chapter 5:
- Laplace Transform Theorems Table 5_2 (jpg)
- Chapter 5 The Laplace Transform (jnt)
- Single_sided Laplace Transforms Table 5_3 (jpg)
- Partial Fraction Expansion (Power Point Presentation)

Chapter 6: *These are some of the notes (NOT ALL)

Introduction

Laplace Transform Equivalent Circuit Element

Analysis of Electrical Networks with Initial Conditions

Transfer Function Components of System Response

Chapter 8:

Analog to Digital Conversion (Sampling) (Lecture37.pdf)

Signal Reconstruction and Quantization Noise (Lecture38.pdf)

Z-transform (Lecture39.pdf)

Z-Transform and Applications to Discrete-Time Systems (Lecture40.pdf)

Short Table of Z-Transforms (jpg)

8.2. Analog-to-Digital Conversion Sampling ( x ) Impulse Train Sampling Model ( x ) Data Reconstruction ( x ) Ideal Reconstruction Filter ( x ) Linear Interpolation ( ) Reconstruction with a simple RC filter ( ) Quantization and Encoding (General ideal )

8.3 The Z-Transform Definition of the z-Transform ( x ) Linearity ( x ) Initial Value and Final Value Theorems ( x ) Inverse z-Transform ( x ) Delay Operator ( x )

8.4 Difference Equations and DT Systems Properties of Systems ( x ) Shift-Invariant Systems ( x ) Cause and Non-causal Systems ( x ) Linear Systems ( x ) Stable Systems ( ) Difference Equations ( x ) Steady-State Freq. Resp. of LDT Sys. ( ) Frequency Resp. at f = 0 and f = 0.5 fs ( )

News!

The website is redesigne. If you face any problem, please let me know

My office hours are posted

Sun 11:00-11:50AM

Tuesday 11:00-11:50AM+12:20-12:50PM

Homework

Additional Selected Problems from the textbook (not for submission)

HW No.	HW Problems
1	2.3; 2.6; 2.12 a,b,c; 2.22 c; 2.30 d; Ext1
2	3.2; 3.4 f (b and c signals); 3.8 iv; 3.15 b; 3.20; 3.25; Ext2
3	4.2 ii iii; 4.3 ii iv; 4.8 b; 4.13 d; 4.26; 4.32; Ext3
4	5.1 b d; 5.4 e f; 5.8 c; 5.9 d; 5.12; Ext4
5	5.19 c; 5.26; 6.3; 6.6; Ext5
6	7.1 d f; 7.5; 7.10; 7.17 ii; 7.24; 7.29 b; Ext6
7	6.14; 6.18; 6.24; Ext7
8	9.2 a; 9.14 iii iv; 9.27 g; 10.2; 10.6 c; Ext8
9	10.14; 11.1 b f; 11.12

Quizzes

#	Topic	Due Week	class	081	111	121	122	131
1	Signals and Systems Modeling Concepts	2	3	Quiz 1	Q1	Q1	Q1	Q1v1&v2
2	System Analysis in Time Domain			Quiz 2	Q2	Q2	Q2, Q3
3	Fourier Series			Quiz 3	Q3	Q3	Q4
4	Fourier Transform	10	1	Quiz 4	Q4	Q4	Q5
5	Fourier Transform Analysis and Laplace Transform			Quiz 5		Q5	Q6
6	Application of Laplace Transform to Circuits			Quiz 6	Q5	Q6
7	Sampling and z-transform				Q6	Q7	Q7

Exams

Exam I	033	042	043	081	111	121,sol	122	131
Exam II	033	042 Sol	043	081	111	121sol	122	131
Final		042	043 043Sol			121

Major 1: Thureday 24 Oct. , 7-9 PM (Location:?)

Major 2: Sunday 24 Nov., 7-9 PM (Location:?)

Tutorial 1: Chapters 1, 2, & 3

Instructional Objectives (Summary)

Main Ideas Summary:

1)      Exponential Fourier series

2)      Magnitude and Phase Spectra Symmetry properties of Exponential Series

3)    Average power from exponential series Pav=sum (xn^2)   Parsaval.

4)      Fourier Transform by definition (Integral)

5)      Inverse Fourier Transform by definition (integral)

6)      Symmetry properties of the Fourier Transform ( complex, real, imaginary)

7)      Ability to use tables for F.T Theorems , properties. To perform both FT and IFT

8)      Circuit and System analysis using F.T

9)      Energy Spectral Density

10)   Laplace Transform /Inverse Laplace transform by definition.

11)   Laplace transform Theorems (Properties)

12)  Inverse Laplace Transform

Projects

Term	Project
122	Aliasing, Fourier Series and Convolution (pdf)
121	Term project (pdf)
111	EE207 Term Project 111
081	EE207 TERM Project 081

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