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That's alot of numbers seemingly out of the blue, at first observance. I bet your questions are:
That's alot of numbers seemingly out of the blue, at first observance. I bet your questions are:


<br>1. Telling me the difference between a transformer and a Fourier Transform hasn't helped me finish my assignment. What else can you tell me? <br>
<br>=== 1. Telling me the difference between a transformer and a Fourier Transform hasn't helped me finish my assignment. What else can you tell me? === <br>
2.Can you show me some really easy plug-in formulas so I can get my homework done faster so I can start playing World of Warcraft. <br>
2.Can you show me some really easy plug-in formulas so I can get my homework done faster so I can go play World of Warcraft? <br>
3.If I've got one, what can I do with it?
3.If I've got one, what can I do with it?



Revision as of 18:52, 8 October 2007

An Introduction to the Fourier Transform

Unfortunately, the Fourier Transform isn't a Transformer. If it was, you would have seen it in the movie that came out lately. Transformer roolbar.jpg
One way to explain a Fourier Transform is to say it's a bunch of sinusoids added to create a just about any function you want. Another way to describe it is to say it's a way of representing a function in the frequency domain instead of the time domain.
For example, a square wave could be represented by:

That's alot of numbers seemingly out of the blue, at first observance. I bet your questions are:


=== 1. Telling me the difference between a transformer and a Fourier Transform hasn't helped me finish my assignment. What else can you tell me? ===
2.Can you show me some really easy plug-in formulas so I can get my homework done faster so I can go play World of Warcraft?
3.If I've got one, what can I do with it?



X(f)=\int_{-\infty}^{\infty} x(t) e^{-j2\pi ft}\, dt

</math>

Suppose that we have some function, say , that is nonperiodic and finite in duration.
This means that for some

Now let's make a periodic function by repeating with a fundamental period . Note that
The Fourier Series representation of is
where
and
can now be rewritten as
From our initial identity then, we can write as
and becomes
Now remember that and
Which means that
Which is just to say that

So we have that
Further

Some Useful Fourier Transform Pairs






Some other usefull pairs can be found here: Fourier Transforms

A Second Approach to Fourier Transforms