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How do we put it into computer? |
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How do we put it into computer? |
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We can use A/D converter and a low pass filter to sample the signal that is wanted instead of from t = -\infty to \infty: |
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We can use A/D converter and a low pass filter to sample the signal that is wanted instead of from <math>t = -\infty\,\, to\,\, \infty</math>: |
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[[Image:DFT2.jpg|1000px]] |
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[[Image:DFT2.jpg|1000px]] |
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So <math>\sum_{m=0}^{N-1}X(m)\, e^{j2\pi\frac{lm}{N}}=\sum_{n=0}^{N-1}x(n)N\delta_{n,l}=Nx(l)</math> |
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So <math>\sum_{m=0}^{N-1}X(m)\, e^{j2\pi\frac{lm}{N}}=\sum_{n=0}^{N-1}x(n)N\delta_{n,l}=Nx(l)</math> |
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<math>x(l) = \frac{1}{N}\sum_{m=0}^{N-1}X(m)\, e^{j2\pi\frac{lm}{N}}\equiv\, IDFT(X(n)) </math> |
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<math>x(l) = \frac{1}{N}\sum_{m=0}^{N-1}X(m)\, e^{j2\pi\frac{lm}{N}}\equiv\, IDFT(X(m)) </math> |
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Key points to note: |
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Key points to note: |
If we have a signal, such as following:
How do we put it into computer?
We can use A/D converter and a low pass filter to sample the signal that is wanted instead of from :
But then we have to make it periodic, so we convolve it with impulse function with NT apart to have impulse function in both time and frequency domain:
From the equations of final signal in both time and frequency domain, we can see that in the computer we have x(n) and in the frequency domain:
Then the areas of the impulse functions is:
Which is the definition of the .
Property of the DFT
Proof:
Inverse DFT
Let's try to get back x(l) if we have X(m)
Let's try do some trick to this DFT, let's sum it up and with exponents tag along.
Note: will be N if .
Let then
So we know the sum of
Therefore, we can divide r at both side of equation and get
Think about this, if , since for any integer of l and n.
So
Key points to note:
- By doing the DFT, we make the signal periodic in both time domain and frequency domain.
- corresponds to
Approximation of Fourier integral
We can kind of see the DFT as an approximation to the Fourier integral.