(Other Topics)
 
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Office Hours: M W 11:00 am - 12:00 am
 
Office Hours: M W 11:00 am - 12:00 am
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Email : asan@purdue.edu
  
 
== Main Topics of the Course ==
 
== Main Topics of the Course ==
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##[[Unit step response of an LTI system_OldKiwi]]
 
##[[Unit step response of an LTI system_OldKiwi]]
 
#Lecture 8
 
#Lecture 8
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##[[LTI systems described by differential equations(CT) and difference equation(DT)_OldKiwi]]
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##[[Response of LTI systems to complex exponentials_OldKiwi]]
 
#Lecture 9
 
#Lecture 9
 
##[[Response of LTI systems to complex exponentials_OldKiwi]]
 
##[[Response of LTI systems to complex exponentials_OldKiwi]]
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##[[Fourier Series Representation of CT periodic signals_OldKiwi]]
 
##[[Fourier Series Representation of CT periodic signals_OldKiwi]]
 
##[[Properties of CT Fourier Series_OldKiwi]]
 
##[[Properties of CT Fourier Series_OldKiwi]]
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#Lecture 11
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##[[Fourier Series Representation of CT periodic signals using properties_OldKiwi]]
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##[[Fourier Series Representation of DT periodic signals_OldKiwi]]
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#Lecture 12
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##[[Properties of discrete time Fourier Series_OldKiwi]]
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##[[Fourier Series and LTI Systems_OldKiwi]]
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#Lecture 13
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##[[CT Fourier Transform_OldKiwi]]
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#Lecture 14
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##[[Convergence of Fourier Transform_OldKiwi]]
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##[[Fourier Transform of periodic signals_OldKiwi]]
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##[[Properties of Continuous Fourier Transforms_OldKiwi]]
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#Lecture 15
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##[[Applications of Convolution Property_OldKiwi]]
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##[[Applications of Multiplication Property_OldKiwi]]
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##[[Frequency selective filtering_OldKiwi]]
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#Lecture 16
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##[[Frequency selective filtering_OldKiwi]]
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##[[CT LTI systems charachterized by LCCDE_OldKiwi]]
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#Lecture 17
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##[[Communication Systems_OldKiwi]]
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##[[  Complex Exponential And Sinusoidal_OldKiwi]]
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##[[          Amplitude Modulation (AM_OldKiwi]]
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##[[  Demodulation for AM_OldKiwi]]
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#Lecture 18
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##[[Frequency Division Multiplextion (FDM)_OldKiwi]]
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##[[Single-Sideband Sinusoidal AM_OldKiwi]]
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##[[AM with a pluse-train carrier_OldKiwi]]
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#Lecture 19
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##[[ Discrete-time Fourir Transform_OldKiwi]]
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##[[DTFT for periodic signals_OldKiwi]]
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##[[Properties of DTFT_OldKiwi]]
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#Lecture 20
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##[[Tables 5.1 and 5.2_OldKiwi]]
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##[[LTI systems characterized by LCCDEs_OldKiwi]]
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#Lecture 21
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##[[Duality_OldKiwi]]
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##[[  CTFT_OldKiwi]]
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##[[  DTFS_OldKiwi]]
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##[[  CRFS & DTFT_OldKiwi]]
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#Lecture 22
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##[[Sampling_OldKiwi]]
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##[[Representation of a CT signalby its samples:_OldKiwi]]
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##[[  The Sampling Theorem_OldKiwi]]
  
 
== Homework Problems ==
 
== Homework Problems ==
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#[[Homework 4 - Missing 3.28 & 4.4b_OldKiwi]]
 
#[[Homework 4 - Missing 3.28 & 4.4b_OldKiwi]]
 
#[[Homework 4 - 4.4b_OldKiwi]]
 
#[[Homework 4 - 4.4b_OldKiwi]]
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#[[Homework 5 - Missing 4.45, 4.46 & 4.49_OldKiwi]]
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#[[Homework 5 - Missing First three and last one_OldKiwi]]
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#[[Homework 6 - Don't know 5.8_OldKiwi]]
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== Exams ==
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#[[Exam 1 - Summer 08_OldKiwi]]
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#[[ECE301:SanSummer08:Exam II_OldKiwi]]
  
 
== Bonus Problems ==
 
== Bonus Problems ==
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#[[Bonus 3 - Exam I_OldKiwi]]
 
#[[Bonus 3 - Exam I_OldKiwi]]
 
#[[Bonus 5 - Exam I_OldKiwi]]
 
#[[Bonus 5 - Exam I_OldKiwi]]
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#[[Bonus 6 - Convolution Proofs_OldKiwi]]
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#[[Bonus 12 - Exam II_OldKiwi]]
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#[[Bonus 12 scores_OldKiwi]]
  
 
==Other Topics==
 
==Other Topics==
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#[[Practice Problems - Exam 1_OldKiwi]]
 
#[[Practice Problems - Exam 1_OldKiwi]]
 
#[[Exam 1 Formula's_OldKiwi]]
 
#[[Exam 1 Formula's_OldKiwi]]
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#[[Practice Midterm 2 - Aung Kyi San Summer 2005 Solutions_OldKiwi]]

Latest revision as of 11:32, 25 July 2008

General Course Information

ECE 301

Summer 2008

Instructor: Aung Kyi San

Lecture: M T W Th F 9:50 am - 10:50 am @ EE 117

Office Hours: M W 11:00 am - 12:00 am

Email : asan@purdue.edu

Main Topics of the Course

  1. Lecture 1
    1. Signal Energy and Power_OldKiwi
    2. Transformation of the independent variable_OldKiwi
  2. Lecture 2
    1. Periodic Signals_OldKiwi
    2. Even and Odd Signals_OldKiwi
    3. Exponential and Sinusoidal signals (CT)_OldKiwi
  3. Lecture 3
    1. Exponential and Sinusoidal signals (DT)_OldKiwi
    2. The unit impulse and unit step functions_OldKiwi
  4. Lecture 4
    1. Continuous-Time and Discrete-Time_OldKiwi
    2. Basic System Properties_OldKiwi
  5. Lecture 5
    1. DT LTI systems: The convolution sum_OldKiwi
  6. Lecture 6
    1. CT LTI systems: The convolution integral_OldKiwi
  7. Lecture 7
    1. Properties of LTI systems_OldKiwi
    2. Unit step response of an LTI system_OldKiwi
  8. Lecture 8
    1. LTI systems described by differential equations(CT) and difference equation(DT)_OldKiwi
    2. Response of LTI systems to complex exponentials_OldKiwi
  9. Lecture 9
    1. Response of LTI systems to complex exponentials_OldKiwi
    2. Fourier Series representation of continuous-time periodic signals_OldKiwi
  10. Lecture 10
    1. Fourier Series Representation of CT periodic signals_OldKiwi
    2. Properties of CT Fourier Series_OldKiwi
  11. Lecture 11
    1. Fourier Series Representation of CT periodic signals using properties_OldKiwi
    2. Fourier Series Representation of DT periodic signals_OldKiwi
  12. Lecture 12
    1. Properties of discrete time Fourier Series_OldKiwi
    2. Fourier Series and LTI Systems_OldKiwi
  13. Lecture 13
    1. CT Fourier Transform_OldKiwi
  14. Lecture 14
    1. Convergence of Fourier Transform_OldKiwi
    2. Fourier Transform of periodic signals_OldKiwi
    3. Properties of Continuous Fourier Transforms_OldKiwi
  15. Lecture 15
    1. Applications of Convolution Property_OldKiwi
    2. Applications of Multiplication Property_OldKiwi
    3. Frequency selective filtering_OldKiwi
  16. Lecture 16
    1. Frequency selective filtering_OldKiwi
    2. CT LTI systems charachterized by LCCDE_OldKiwi
  17. Lecture 17
    1. Communication Systems_OldKiwi
    2. Complex Exponential And Sinusoidal_OldKiwi
    3. Amplitude Modulation (AM_OldKiwi
    4. Demodulation for AM_OldKiwi
  18. Lecture 18
    1. Frequency Division Multiplextion (FDM)_OldKiwi
    2. Single-Sideband Sinusoidal AM_OldKiwi
    3. AM with a pluse-train carrier_OldKiwi
  19. Lecture 19
    1. Discrete-time Fourir Transform_OldKiwi
    2. DTFT for periodic signals_OldKiwi
    3. Properties of DTFT_OldKiwi
  20. Lecture 20
    1. Tables 5.1 and 5.2_OldKiwi
    2. LTI systems characterized by LCCDEs_OldKiwi
  21. Lecture 21
    1. Duality_OldKiwi
    2. CTFT_OldKiwi
    3. DTFS_OldKiwi
    4. CRFS & DTFT_OldKiwi
  22. Lecture 22
    1. Sampling_OldKiwi
    2. Representation of a CT signalby its samples:_OldKiwi
    3. The Sampling Theorem_OldKiwi

Homework Problems

  1. Homework 1 - Summer 08_OldKiwi
  2. Homework 2 - Summer 08_OldKiwi
  3. Homework 3 - Summer 08_OldKiwi
  4. Homework 4 - Missing 3.28 & 4.4b_OldKiwi
  5. Homework 4 - 4.4b_OldKiwi
  6. Homework 5 - Missing 4.45, 4.46 & 4.49_OldKiwi
  7. Homework 5 - Missing First three and last one_OldKiwi
  8. Homework 6 - Don't know 5.8_OldKiwi

Exams

  1. Exam 1 - Summer 08_OldKiwi
  2. ECE301:SanSummer08:Exam II_OldKiwi

Bonus Problems

  1. Bonus 2 - Summer 08_OldKiwi
  2. Bonus 3 - Exam I_OldKiwi
  3. Bonus 5 - Exam I_OldKiwi
  4. Bonus 6 - Convolution Proofs_OldKiwi
  5. Bonus 12 - Exam II_OldKiwi
  6. Bonus 12 scores_OldKiwi

Other Topics

Add other relevent/interesting pages here:

You can use latex in Kiwi, here is a Latex Cheat Sheet

  1. Practice Problems - Exam 1_OldKiwi
  2. Exam 1 Formula's_OldKiwi
  3. Practice Midterm 2 - Aung Kyi San Summer 2005 Solutions_OldKiwi

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