Revision as of 11:34, 1 August 2022

Fourier Transform(Q6520159)

Fourier Transform ^[1] is the next level of the Fourier Series, it comes up with a way to approximate hole functions by using exponentials $e^{ikx}$ that means, unlike Fourier Series can only approximate a function on an interval, now we can approximate functions that are infinitely long.

Example for Fourier transform: We have a signal called $x(t)$ we will represent it in terms of the time domain. We also can represent it in another way which is called $x(f)$ we will represent it in terms of the frequency domain and This is why we called transformation. Fourier Transform is an equivalent representation of the signal.

Fourier Series equation $f(\omega )=\int f(x)e^{-i\omega x}dx$

Eulers formula $e^{i\omega x}=\cos({\omega x})+i\sin({\omega x}),$

$i$ represents imaginary numbers,
$\omega$ is so and so,
$f()$ is the strength of the signal over time,
$x$ represents time,
$f(x)$ or $x(f)$ represents the frequency function....

-From The Fourier Series and Fourier Transform Demystified^[2]

References

↑ Douglas, Brian (Jan 11, 2013). Introduction to the Fourier Transform. local page: Brian Douglas.
↑ Tan-Holmes, Jade (Jun 30, 2022). The Fourier Series and Fourier Transform Demystified. local page: Up and Atom.

Related Pages

[1] Douglas, Brian (Jan 11, 2013). Introduction to the Fourier Transform. local page: Brian Douglas.

[2] Tan-Holmes, Jade (Jun 30, 2022). The Fourier Series and Fourier Transform Demystified. local page: Up and Atom.

[1]

[2]

@@ Line 7: / Line 7: @@
 We have a signal called <math>x(t)</math> we will represent it in terms of the time domain. We also can represent it in another way which is called <math>x(f)</math> we will represent it in terms of the frequency domain and This is why we called transformation. Fourier Transform is an equivalent representation of the signal.
-<H1>You must list out <math>i,k,x,t,f</math> individually, and state individually what they are explicitly.</H1>
-For example:
-where:
+Fourier Series equation <math> f(\omega)= \int f(x) e^{-i \omega x } dx </math>
-*<math>i</math> represents imaginary numbers,
-*<math>k</math> is so and so,
-*<math>x(t)</math> is the strength of the signal over time,
-*<math>t</math> represents time,
-*<math>f(x)</math> or <math>x(f)</math> represents the frequency function....
-<H1>This must apply to all equations ...</H1>
+Eulers formula <math>e^{i \omega x} = \cos ({\omega x}) + i\sin ({\omega x}),</math>
-Fourier Series equation <math> f(\omega)= \int f(x) e^{-i \omega x } dx </math>
+*<math>i</math> represents imaginary numbers,
+*<math> \omega </math> is so and so,
+*<math>f()</math> is the strength of the signal over time,
+*<math>x</math> represents time,
+*<math>f(x)</math> or <math>x(f)</math> represents the frequency function....
-Eulers formula <math>e^{i \omega x} = \cos ({\omega x}) + i\sin ({\omega x}),</math>
+-From [[Video/The Fourier Series and Fourier Transform Demystified | The Fourier Series and Fourier Transform Demystified]]<ref>{{:Video/The Fourier Series and Fourier Transform Demystified}}</ref>
--From [[Video/The Fourier Series and Fourier Transform Demystified | The Fourier Series and Fourier Transform Demystified]]<ref>{{:Video/The Fourier Series and Fourier Transform Demystified}}</ref>
-In this equation f(x) is the time function we're calculating the Fourier series for. Then we times it by exponential<math>e^{i \omega x}</math>.
 <noinclude>

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Difference between revisions of "Fourier Transform"

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