The Fourier Transforms: Difference between revisions
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==== Shifting the function changes the phase of the spectrum === |
==== Shifting the function changes the phase of the spectrum ==== |
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<math>\mathcal{F}[x(t-a)] = X(t)e^{j2\pi f a}</math> |
<math>\mathcal{F}[x(t-a)] = X(t)e^{j2\pi f a}</math> |
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=== Symmetries ==== |
=== Symmetries ==== |
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''' |
''' |
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- if x(t) is real, then <math> X(-f) = F(t)^*</math> |
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- if x(t) is imaginary, then <math>X(-f) = -X(f)^*</math> |
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- if x(t) is even, then <math>X(-f) = X(f)$</math> |
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- if x(t) is odd, then <math> X(-f) = -X(f)$.</math>''' |
Latest revision as of 12:44, 28 October 2007
The Fourier transform was named after Joseph Fourier, a French mathematician. A Fourier Transform takes a function to its frequency components.
Properties of a Fourier Transform:
Properties of a Fourier Transform:
Linearity
Shifting the function changes the phase of the spectrum
Frequency and amplitude are affected when changing spatial scale inversely
Symmetries =
- if x(t) is real, then
- if x(t) is imaginary, then
- if x(t) is even, then
- if x(t) is odd, then