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− | =This pages contains exercises to practice computing the Fourier series of a CT signal = | + | [[Category:problem solving]] |
− | Note: This is a collective study page. You are expected to participate by adding content/comment/questions/exercises etc. This is a wiki after all! | + | [[Category:Fourier series continuous-time]] |
+ | = This pages contains exercises to practice computing the Fourier series of a CT signal = | ||
+ | |||
+ | Note: This is a collective study page. You are expected to participate by adding content/comment/questions/exercises etc. This is a wiki after all! | ||
+ | |||
---- | ---- | ||
− | ==Recall the basic formulas== | + | |
+ | == Recall the basic formulas == | ||
+ | |||
*Fourier series of a continuous-time signal x(t) periodic with period T | *Fourier series of a continuous-time signal x(t) periodic with period T | ||
+ | |||
:<math>x(t)=\sum_{n=-\infty}^\infty a_n e^{j \frac{2\pi}{T}nt}</math> | :<math>x(t)=\sum_{n=-\infty}^\infty a_n e^{j \frac{2\pi}{T}nt}</math> | ||
+ | |||
*Fourier series coefficients of a continuous-time signal x(t) periodic with period T | *Fourier series coefficients of a continuous-time signal x(t) periodic with period T | ||
+ | |||
:<math>a_n=\frac{1}{T} \int_{0}^T x(t) e^{-j \frac{2\pi}{T}nt}dt</math> | :<math>a_n=\frac{1}{T} \int_{0}^T x(t) e^{-j \frac{2\pi}{T}nt}dt</math> | ||
+ | |||
---- | ---- | ||
− | |||
− | |||
− | |||
− | |||
+ | == Case 1: For some periodic functions, the Fourier series coefficients must be obtained by integration == | ||
+ | |||
+ | *[[Fourier series coefficients of a periodic square wave period two|Periodic square wave with period two]] | ||
+ | *[[Fourier series coefficients student 1|Periodic <span class="texhtml"> | sin(π''t'') | </span> with period one]] | ||
+ | *write a page with another example [[Fourier series coefficients student 2|here]]. | ||
+ | |||
+ | <br> | ||
---- | ---- | ||
− | ==Case 2: Some periodic functions (e.g. sine and cosine) can be directly expanded into a linear combination of complex exponentials== | + | |
+ | == Case 2: Some periodic functions (e.g. sine and cosine) can be directly expanded into a linear combination of complex exponentials == | ||
+ | |||
The following pages contain a periodic signal along with a computation of the Fourier series coefficients of that signal. These were contributed by your peers in ECE301. Check whether the answers are correct. Are all the steps explained clearly and logically? Do you have questions? Feel free to comment directly on the pages! | The following pages contain a periodic signal along with a computation of the Fourier series coefficients of that signal. These were contributed by your peers in ECE301. Check whether the answers are correct. Are all the steps explained clearly and logically? Do you have questions? Feel free to comment directly on the pages! | ||
− | *[[HW4. | + | |
− | *[[HW4. | + | *[[HW4.1 Austin Melnyk ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Adrian Delancy ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Ananya Panja ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Wei Jian Chan ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Carlos Leon ECE301Fall2008mboutin]] |
− | *[[HW4- | + | *[[HW4.1 Ronny Wijaya ECE301Fall2008mboutin]] |
− | *[[HW4- | + | *[[HW4-1 Steve Anderson ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4-1 Steve Anderson ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Max Paganini ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Miles Whittaker ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Scott Erdbruegger ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Jungu (Joe) Choi ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 I-Cheng CHen ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Emily Blount ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Ben Laskowski ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Travis Safford ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Daniel Morris ECE301Fall2008mboutin]] |
− | *[[HW4. | + | *[[HW4.1 Nicholas Block ECE301Fall2008mboutin]] |
− | *See more exercise in the first question of [[ | + | *[[HW4.1 Sean Ray ECE301Fall2008mboutin]] |
+ | *See more exercise in the first question of [[Homework 4 ECE301Fall2008mboutin|this page]] | ||
---- | ---- | ||
− | ==Questions== | + | |
+ | == Questions == | ||
+ | |||
*What is the difference between the Fourier series of a signal, and the Fourier series coefficients for a signal? | *What is the difference between the Fourier series of a signal, and the Fourier series coefficients for a signal? | ||
− | |||
− | For example: | + | The Fourier series coefficients are in terms of k, and are the coefficients of each nth progression of the signal. The Fourier series is the sum of the Fourier coefficient and nth term of the signal product. |
+ | |||
+ | For example: | ||
+ | |||
<math> | <math> | ||
\begin{align} | \begin{align} | ||
− | x(n) | + | &x(n) = \sum_{n=-\infty}^\infty sin(\pi*n)\\ |
− | a_k = sinc(k) | + | &a_k = sinc(k) \\ |
− | Therefore, x(n) = sinc(0) | + | &\text{Therefore, } x(n) = sinc(0)sin(\pi*n) + sinc(1)sin(\pi*n) + ... \\ |
− | \end{align} | + | \end{align}</math> |
− | </math> | + | |
− | At least that's how I understand it now. | + | At least that's how I understand it now. |
+ | |||
+ | ~ksoong | ||
+ | |||
+ | ::Ok, that's a good start. (And great job with the latex, by the way!) Now let's do the "variable test" on the above equations. (This is an excellent trick to use when doing transforms!). First, let's look at the statement regarding the coefficients: | ||
+ | |||
+ | ::<math>a_{\color{OliveGreen}k} = sinc({\color{OliveGreen}k}) </math> | ||
+ | |||
+ | ::Notice that both the left side and the right side of the equations only depend on the variable k. That's good! This is what you would expect since, as you meant above, the coefficients depend on the variable k, and you do indeed have an expression in terms of k on the right-hand side. | ||
+ | |||
+ | <br> | ||
+ | |||
+ | ::Now compare this with the Fourier series formula stated: | ||
+ | |||
+ | ::<math>x( {\color{blue}n} ) = \sum_{{\color{blue}n}=-\infty}^\infty sin(\pi*{\color{blue}n})</math> | ||
+ | |||
+ | ::Notice that the left-hand side depends on the variable n. However, the right-hand side actually does NOT depend on n. This is because n is the variable used to index all the terms of the summation: it is not a meaningful variable, because at the end when all the terms are summed together (so to get the left-hand-side value x[n]), there is no need for the variable n anymore. The variable used to index the terms of the summation is an example of what is called a "dummy variable", just like the integration variable in an integral. Now, the fact that the left hand side depends on n, and the right-hand side does not is problematic: you would expect both sides to depend on the same variable n. Can you/somebody propose a way to solve this problem? --[[User:Mboutin|Mboutin]] 19:39, 16 September 2010 (UTC) | ||
+ | |||
+ | <br> | ||
+ | |||
+ | ::That seems to imply the example itself isn't correct. | ||
+ | <math> | ||
+ | \begin{align} | ||
+ | &x(n) = \sum_{k=-\infty}^n sin(\pi*k)\\ | ||
+ | &\text{Running sum formatting? } \\ | ||
+ | \end{align}</math> | ||
+ | [[User:Ajfunche|Ajfunche]] | ||
+ | <br> | ||
− | |||
---- | ---- | ||
[[ECE301|Back to ECE301]] | [[ECE301|Back to ECE301]] | ||
+ | |||
+ | [[ECE438|Back to ECE438]] |
Latest revision as of 08:43, 29 December 2010
This pages contains exercises to practice computing the Fourier series of a CT signal
Note: This is a collective study page. You are expected to participate by adding content/comment/questions/exercises etc. This is a wiki after all!
Recall the basic formulas
- Fourier series of a continuous-time signal x(t) periodic with period T
- $ x(t)=\sum_{n=-\infty}^\infty a_n e^{j \frac{2\pi}{T}nt} $
- Fourier series coefficients of a continuous-time signal x(t) periodic with period T
- $ a_n=\frac{1}{T} \int_{0}^T x(t) e^{-j \frac{2\pi}{T}nt}dt $
Case 1: For some periodic functions, the Fourier series coefficients must be obtained by integration
- Periodic square wave with period two
- Periodic | sin(πt) | with period one
- write a page with another example here.
Case 2: Some periodic functions (e.g. sine and cosine) can be directly expanded into a linear combination of complex exponentials
The following pages contain a periodic signal along with a computation of the Fourier series coefficients of that signal. These were contributed by your peers in ECE301. Check whether the answers are correct. Are all the steps explained clearly and logically? Do you have questions? Feel free to comment directly on the pages!
- HW4.1 Austin Melnyk ECE301Fall2008mboutin
- HW4.1 Adrian Delancy ECE301Fall2008mboutin
- HW4.1 Ananya Panja ECE301Fall2008mboutin
- HW4.1 Wei Jian Chan ECE301Fall2008mboutin
- HW4.1 Carlos Leon ECE301Fall2008mboutin
- HW4.1 Ronny Wijaya ECE301Fall2008mboutin
- HW4-1 Steve Anderson ECE301Fall2008mboutin
- HW4-1 Steve Anderson ECE301Fall2008mboutin
- HW4.1 Max Paganini ECE301Fall2008mboutin
- HW4.1 Miles Whittaker ECE301Fall2008mboutin
- HW4.1 Scott Erdbruegger ECE301Fall2008mboutin
- HW4.1 Jungu (Joe) Choi ECE301Fall2008mboutin
- HW4.1 I-Cheng CHen ECE301Fall2008mboutin
- HW4.1 Emily Blount ECE301Fall2008mboutin
- HW4.1 Ben Laskowski ECE301Fall2008mboutin
- HW4.1 Travis Safford ECE301Fall2008mboutin
- HW4.1 Daniel Morris ECE301Fall2008mboutin
- HW4.1 Nicholas Block ECE301Fall2008mboutin
- HW4.1 Sean Ray ECE301Fall2008mboutin
- See more exercise in the first question of this page
Questions
- What is the difference between the Fourier series of a signal, and the Fourier series coefficients for a signal?
The Fourier series coefficients are in terms of k, and are the coefficients of each nth progression of the signal. The Fourier series is the sum of the Fourier coefficient and nth term of the signal product.
For example:
$ \begin{align} &x(n) = \sum_{n=-\infty}^\infty sin(\pi*n)\\ &a_k = sinc(k) \\ &\text{Therefore, } x(n) = sinc(0)sin(\pi*n) + sinc(1)sin(\pi*n) + ... \\ \end{align} $
At least that's how I understand it now.
~ksoong
- Ok, that's a good start. (And great job with the latex, by the way!) Now let's do the "variable test" on the above equations. (This is an excellent trick to use when doing transforms!). First, let's look at the statement regarding the coefficients:
- $ a_{\color{OliveGreen}k} = sinc({\color{OliveGreen}k}) $
- Notice that both the left side and the right side of the equations only depend on the variable k. That's good! This is what you would expect since, as you meant above, the coefficients depend on the variable k, and you do indeed have an expression in terms of k on the right-hand side.
- Now compare this with the Fourier series formula stated:
- $ x( {\color{blue}n} ) = \sum_{{\color{blue}n}=-\infty}^\infty sin(\pi*{\color{blue}n}) $
- Notice that the left-hand side depends on the variable n. However, the right-hand side actually does NOT depend on n. This is because n is the variable used to index all the terms of the summation: it is not a meaningful variable, because at the end when all the terms are summed together (so to get the left-hand-side value x[n]), there is no need for the variable n anymore. The variable used to index the terms of the summation is an example of what is called a "dummy variable", just like the integration variable in an integral. Now, the fact that the left hand side depends on n, and the right-hand side does not is problematic: you would expect both sides to depend on the same variable n. Can you/somebody propose a way to solve this problem? --Mboutin 19:39, 16 September 2010 (UTC)
- That seems to imply the example itself isn't correct.
$ \begin{align} &x(n) = \sum_{k=-\infty}^n sin(\pi*k)\\ &\text{Running sum formatting? } \\ \end{align} $
Ajfunche