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Again, notice that <math>e^{j2 \pi f(f'-f)} \equiv \delta (f'-f) = \delta (f-f')</math> |
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Again, notice that <math>e^{j2 \pi f(f'-f)} \equiv \delta (f'-f) = \delta (f-f')</math> |
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This is good news for both the time-domain and frequency domain, because these integrals will only be non-zero when <math>t=t' \mbox( and ) f=f'</math> respectively. |
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This is good news for both the time-domain and frequency domain, because these integrals will only be non-zero when |
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<math> \,t = \,t' \mbox{ and } \,f = \,f'</math> |
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respectively. |
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Revision as of 17:55, 14 October 2009
October 5th, 2009, class notes (as interpreted by Nick Christman)
The topic covered in class on October 5th was about how to deal with signals that are not periodic.
Given the following Fourier series (Equation 1), what if the signal is not periodic?
where
To investigate this potential disaster, let's look at what happens as the period increases (i.e. not periodic). Essentially, as we can say the following:
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With this, we get the following (Equation 2):
Given the above equivalence, we say the following:
Therefore, we have obtained an equation to relate the Fourier analysis of a function in the time-domain to the frequency-domain:
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From this we can see that is the inverse Laplace transform of . Similarly, is the Laplace transform of
The next thing we did was rearranged some limits within Equation 2 (given the above similarities) to give us the following:
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Notice that
Similarly,
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Again, notice that
This is good news for both the time-domain and frequency domain, because these integrals will only be non-zero when
respectively.
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