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These are given without guarantee of correctness. If you see a typo or error, please let me know.
 
These are given without guarantee of correctness. If you see a typo or error, please let me know.
 
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* [[Media:ECE301Summer2016_Aug01.pdf|Mon Aug 1st]]
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* [[Media:ECE301Summer2016_Jul28.pdf|Thu Jul 28th]]
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* [[Media:ECE301Summer2016_Jul27.pdf|Wed Jul 27th]]
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** Moving from sampling a CT signal to a discrete time sequence.
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* [[Media:ECE301Summer2016_Jul21.pdf|Thu Jul 21st]]
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* [[Media:ECE301Summer2016_Jul20.pdf|Wed Jul 20th]]
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** [[Media:ece301Summer2016_samplingExample.zip| Code]] for sampling a sine wave.
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* [[Media:ECE301Summer2016_Jul19.pdf|Tue Jul 19th]]
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* [[Media:ECE301Summer2016_Jul18.pdf|Mon Jul 18th]]
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* [[Media:ECE301Summer2016_Jul15.pdf|Fri Jul 15th]]
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* [[Media:ECE301Summer2016_Jul14.pdf|Thu Jul 14th]]
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** This is a short lecture because of our quiz.
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* [[Media:ECE301Summer2016_Jul13.pdf|Wed Jul 13th]]
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* [[Media:ECE301Summer2016_Jul11.pdf|Mon Jul 11th]]
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* [[Media:ECE301Summer2016_Jul08.pdf|Fri Jul 8th]]
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** [[Media:classMovingAverage.zip| Code]] to plot the moving average.
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* [[Media:ECE301Summer2016_Jul07.pdf|Thu Jul 7th]]
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** [[Media:euler.png|Plot]] of the complex exponential. Modified matlab [[Media:classExample_jun07.zip| code]].
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* [[Media:ECE301Summer2016_Jul06.pdf| Wed Jul 6th]]
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* [[Media:ECE301Summer2016_Jul05.pdf| Tue Jul 5th]]
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** Fourier series representation of CT periodic signals and FS properties.
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* [[Media:ECE301Summer2016_Jun29.pdf| Thu Jun 29th]]
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** Includes a list of what is covered on Exam 1, and some worked examples.
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* Wed Jun 29th
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** Extra notes on [[Media:ECE301Summer2016_Prob2_22e.pdf| problem 2.22e]].
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* Tue Jun 28th
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** Mainly looked at some examples from the homework. They will be revisited on Wednesday.
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** Here is the [[Media:ECE301_FSClassExample.zip| matlab example]] that was run in class (with some additional comments).
  
 
* [[Media:ECE301Summer2016_Jun24.pdf| Friday June 24th]]
 
* [[Media:ECE301Summer2016_Jun24.pdf| Friday June 24th]]
 
** Note that there was a change to page 6 (the length of the output). It should be an equality (length(x[n]*h[n]) = length(x[n]) + length(h[n]) - 1). Also note that the upper bound of 14 came from y[14]=0, not the length of the sequences being convolved. More explanation has been added to the notes.
 
** Note that there was a change to page 6 (the length of the output). It should be an equality (length(x[n]*h[n]) = length(x[n]) + length(h[n]) - 1). Also note that the upper bound of 14 came from y[14]=0, not the length of the sequences being convolved. More explanation has been added to the notes.
  
* [[Media:ECE301Summer2016_Jun27.pdf| Monday June 27th]]
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** Here is the [[Media:ECE301_FSClassExample.zip| matlab example]] that was run in class (with some additional comments).
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== Discussions ==
 
== Discussions ==

Latest revision as of 20:09, 1 August 2016


ECE301, Summer 2016, Trey E. Shenk

Lecture Notes

These are given without guarantee of correctness. If you see a typo or error, please let me know.


  • Wed Jul 27th
    • Moving from sampling a CT signal to a discrete time sequence.
  • Tue Jul 5th
    • Fourier series representation of CT periodic signals and FS properties.
  • Thu Jun 29th
    • Includes a list of what is covered on Exam 1, and some worked examples.
  • Tue Jun 28th
    • Mainly looked at some examples from the homework. They will be revisited on Wednesday.
    • Here is the matlab example that was run in class (with some additional comments).
  • Friday June 24th
    • Note that there was a change to page 6 (the length of the output). It should be an equality (length(x[n]*h[n]) = length(x[n]) + length(h[n]) - 1). Also note that the upper bound of 14 came from y[14]=0, not the length of the sequences being convolved. More explanation has been added to the notes.



Discussions

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