Fourier Transform Properties: Difference between revisions

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Note that <math>\int_{-\infty}^{\infty}e^{j2\pi (f^{''}-f^')t}dt = \delta (f^{''}-f^') \!</math><br><br>
Note that <math>\int_{-\infty}^{\infty}e^{j2\pi (f^{''}-f^')t}dt = \delta (f^{''}-f^') \!</math><br><br>
So <math>\mathcal{F}\bigg[\int_{-\infty}^{\infty}g(t) h^*(t) dt\bigg] = \int_{-\infty}^{\infty}G(f)H^*(f)df \!</math><br><br>
So <math>\mathcal{F}\bigg[\int_{-\infty}^{\infty}g(t) h^*(t) dt\bigg] = \int_{-\infty}^{\infty}G(f)H^*(f)df \!</math><br><br>

Someone please review this!
Reviewed by [[Nick Christman]]


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[[Nick Christman|<b><u>Nick Christman</u></b>]]<br><br>
[[Nick Christman|<b><u>Nick Christman</u></b>]]<br><br>
'''Find <math>\mathcal{F}[10^{t}g(t)e^{j2 \pi ft_{0}}]</math><br/>'''
1. '''Find <math>\mathcal{F}[\int_{- \infty}^{\infty}10^{t}g(t)e^{j2 \pi ft_{0}} \,dt]</math><br/>'''


To begin, we know that<br/>
To begin, we know that<br/>


<math>
<math> \mathcal{F}[10^{t}g(t)e^{j2 \pi ft_0}] = \int_{-\infty}^{\infty}10^{t}g(t)e^{j2 \pi ft_0}e^{-j2 \pi ft}\,dt = \int_{-\infty}^{\infty}10^{t}g(t)e^{j2 \pi f(t_{0}-t)}\,dt</math>
\mathcal{F}[\int_{- \infty}^{\infty}10^{t}g(t)e^{j2 \pi ft_0} \,dt]
= \int_{- \infty}^{\infty} \left( \int_{-\infty}^{\infty}10^{t}g(t)e^{j2 \pi ft_0} \,dt \right) e^{-j2 \pi ft}\,dt
</math>
<br/>
After some factoring and combinting of like terms we get:
<br/>
<math>
\mathcal{F}[\int_{- \infty}^{\infty}10^{t}g(t)e^{j2 \pi ft_0} \,dt]
= \int_{- \infty}^{\infty} \left( \int_{- \infty}^{\infty} 10^{t}g(t) \,dt \right) e^{j2 \pi f(t_0-t)}\,dt
</math>
<br/>


But recall that
But recall that <math>e^{j2 \pi f(t_{0}-t)} \equiv \delta (t_{0}-t) \mbox{ or } \delta (t-t_{0})</math>
<math>\int_{- \infty}^{\infty}e^{j2 \pi f(t_{0}-t)} \,dt \equiv \delta (t_{0}-t) \mbox{ or } \delta (t-t_{0})</math>




Because of this definition, our problem has now been simplified significantly: <br/>
Because of this definition (and some "math magic") our problem has been simplified significantly: <br/>


<math>
<math> \mathcal{F}[10^{t}g(t)e^{j2 \pi ft_0}] = \int_{-\infty}^{\infty}10^{t}g(t) \delta (t-t_{0})\,dt = 10^{t_0}g(t_0)</math> <br/>
\mathcal{F}[\int_{- \infty}^{\infty}10^{t}g(t)e^{j2 \pi ft_0} \,dt]
= \int_{- \infty}^{\infty}10^{t}g(t) \delta (t-t_{0})\,dt = 10^{t_0}g(t_0)
</math>
<br/>


Therefore,
Therefore,
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<math> \mathcal{F}[10^{t}g(t)e^{j2 \pi ft_0}] = 10^{t_0}g(t_0) </math>
<math> \mathcal{F}[10^{t}g(t)e^{j2 \pi ft_0}] = 10^{t_0}g(t_0) </math>




2.





Revision as of 12:37, 31 October 2009

Some properties to choose from if you are having difficulty....

Max Woesner

1. Find
Recall , so
Also recall ,so
Now
So


reviewed by Joshua Sarris


2. Find
Recall
Similarly,
So
Now

Note that

So

Reviewed by Nick Christman


Nick Christman

1. Find

To begin, we know that


After some factoring and combinting of like terms we get:

But recall that


Because of this definition (and some "math magic") our problem has been simplified significantly:


Therefore,


2.



Joshua Sarris

Find


Recall ,

so expanding we have,


Also recall ,

so we can convert to exponentials.


Now integrating gives us,



So we now have the identity,

or rather

Reviewed by Max