Mathematics Stack Exchange
Mathematics Stack Exchange

Questions tagged [fourier-analysis]

Fourier analysis, also known as spectral analysis, encompasses all sorts of Fourier expansions, including Fourier series, Fourier transform and the discrete Fourier transform (and relatives). The non-commutative analog is (representation-theory).

Fourier analysis is the study of how general functions can be decomposed into trigonometric or exponential functions with definite frequencies. There are two types of Fourier expansions:

  • Fourier series: If a (reasonably well-behaved) function is periodic, then it can be written as a discrete sum of trigonometric or exponential functions with specific frequencies.
  • Fourier transform: A general function that isn’t necessarily periodic (but that is still reasonably well-behaved) can be written as a continuous integral of trigonometric or exponential functions with a continuum of possible frequencies.

The reason why Fourier analysis is so important is that many (although certainly not all) of the differential equations that govern physical systems are linear, which implies that the sum of two solutions is again a solution. Therefore, since Fourier analysis tells us that any function can be written in terms of sinusoidal functions, we can limit our attention to these functions when solving the differential equations. And then we can build up any other function from these special ones. This is a very helpful strategy, because it is invariably easier to deal with sinusoidal functions than general ones.

Fourier series

Consider a function $f(x)$ that is periodic on the interval $0 ≤ x ≤ L$, then Fourier’s theorem states that $f(x)$ can be written as $$f(x)={a_0}+\sum_{n=1}^{\infty}\left[a_n \cos\left(\frac{2n\pi x}{L}\right)+b_n \sin \left(\frac{2n\pi x}{L}\right)\right]$$ where the constant coefficients $a_n$ and $b_n$ are called the Fourier coefficients of $f$ and is given by $$a_0=\frac{1}{L}\int_0^L f(x)\mathrm{d}x$$ $$a_n=\frac{2}{L}\int_0^L f(x)\cos\left(\frac{2\pi nx }{L}\right)\mathrm{d}x$$ $$b_n=\frac{2}{L}\int_0^L f(x)\sin\left(\frac{2\pi nx }{L}\right)\mathrm{d}x$$

Reference:

http://www.people.fas.harvard.edu/~djmorin/waves/Fourier.pdf

https://en.wikipedia.org/wiki/Fourier_analysis

http://mathworld.wolfram.com/FourierSeries.html

Fourier Transform:

For this part find the following link

https://math.stackexchange.com/tags/fourier-transform/info

10420 questions
7
votes
1 answer

Gaussian fixed point Fourier transform

We know that $\text{exp}(-\alpha |x|^2)$ is a fixed point for the unitary Fourier transform if $\text{Re } \alpha > 0$. I know many arguments to show this (contour-integration and differentiation). Is there a not an elegant way where we can exploit…
JT_NL
  • 14,514
7
votes
2 answers

How many Fourier coefficients are enough ( in discrete fourier transform)

Probably there's a similar question, but I could't find it through all questions about FT As the title says, how many Fourier coefficients are enough, to be able to "resume" the original function, using inverse discrete Fourier transform? For…
Kiril Kirov
  • 205
7
votes
1 answer

Fourier Transform of $xf(x)$

I am not able to get the Fourier Transform of $xf(x)$ if $<f(x)>$ is the Fourier transform of $f(x)$ . BTW i tried using convolution theorem but didn't work out .
Theorem
  • 7,979
7
votes
1 answer

Fourier transform with $\sin(t^2)$

This exercise gave me nightmares this night. I have $$ x(t)=\sin(t^2)e^{-2|t-2|} $$ to Fourier transform. First I though about solving the integral. (should I divide the signal in $2$, first for $t-2<0$ then for $t-2\ge 0$ and then study then…
Crysis85
  • 233
7
votes
1 answer

why the convolution of two functions of moderate decrease is again function of moderate decrease?

I need to prove that a convolution of 2 functions of moderate decrease is a function of moderate decrease. I tried to split the integral into two integrals but I couldn't manage to bound any one of them by $\frac{A}{x^2+1}$. Thanks
user148728
  • 161
7
votes
2 answers

What is the intuition behind summability kernel and convolution?

In Fourier analysis, when I look at the theorems and useful results derived using summability kernel and convolution, I get to think "Ok, I guess it works that way. but what is the intuition behind all those complicated looking definitions?" To a…
user224218
  • 71
6
votes
3 answers

Fourier Transform of $sgn(t)$

I'm trying to find the Fourier transform of $sgn(t)$ where $$ sgn(t) = \begin{cases} 1, & t > 0 \\ 0, & t = 0 \\ -1, & t < 0. \end{cases} $$ By definition, $$ X(\omega) = \int_{-\infty}^{\infty} sgn(t) e^{-i\omega t} \, dt = \int_0^{\infty}…
Steven Rash
  • 807
6
votes
1 answer

Simplified version of the Fourier inversion formula

I'm working out of Stein's Fourier Analysis (working with Riemann integrable functions), and I'm having trouble with problem 1: Suppose $f$ is continuous and supported on $[-M,M] \subset \mathbb{R}$ such that the Fourier transform satisfies…
Lost
  • 2,095
6
votes
1 answer

Clarification on "Inverse Fourier transform of $(1 \pm \hat{f}(w))^{-1}$"

The original question: Assume I have a real function $f(t)$ with Fourier transform of $\hat{f}(w)$. Can one say anything about the inverse Fourier transform of $\frac{1}{1\pm\hat{f}(w)}$? An answer (edit: the answer was deleted, and is now a…
angryavian
  • 89,882
6
votes
1 answer

Show $ \frac{\cosh(a( \pi -x))}{\sinh(a \pi)} = \frac{1}{a \pi} + \frac{2}{\pi} \sum_{n = 1}^{\infty}\frac{a}{a^2+n^2}\cos(nx). $

Let $f(x) = e^{-a |x|}, a > 0$. Show that $$ \frac{\cosh(a( \pi -x))}{\sinh(a \pi)} = \frac{1}{a \pi} + \frac{2}{\pi} \sum_{n = 1}^{\infty}\frac{a}{a^2+n^2}\cos(nx). $$ for $ 0 \leq x \leq \pi$. So the idea is to use Poissons summation formula…
Henrik Finsberg
  • 1,387
6
votes
3 answers

Fourier analysis prerequisites and lecture notes

I want to know what the prerequisites are for fully grasping Fourier analysis, and some free pdfs and such to help me with it (no videos, actual paper I can print and read/ make exercises at school). I am asking this because I remember that I asked…
Fourier
  • 71
6
votes
2 answers

Exercise - Fourier transform in two variables?

I need your help for the following problem: Compute the fourier transform of the functions $$\chi_{[0,+\infty[}e^{-x} \quad \text{ and } \quad \frac{e^{(-\frac{x^2}{2})}}{1+iy}$$ The second function does it belong to $L^1(\mathbb{R}^2)$ and/or to…
Mathoman
  • 707
6
votes
2 answers

convolution a continuous function?

define $$h(x)=\int_0^{2\pi}f(x-y)g(y)dy=f*g(x)$$ if $f,g \in L^2$ are $2\pi$ periodic, show that h is continuous on $[0,2\pi)$ so let $x_n \to x$, then $$|h(x)-h(x_n)|=|\int f(x-y)g(y)-\int f(x_n-y)g(y)|$$ i tried to manipulate this but couldnt get…
user8401
6
votes
2 answers

Conditions for a nonnegative Fourier transform

I was wondering if there was known necessary and sufficient conditions for the result of a Fourier transform to be nonnegative, i.e.: $$ F(f) \ge 0 $$ where $F$ is the Fourier transform.
Mike Flynn
  • 1,917
6
votes
2 answers

Example of a function whose Fourier Series fails to converge at One point

Can one think of an example of a continuous $2\pi$ periodic function whose Fourier series fails to converge on $\mathbb{R}$. I referred this in the wikipedia page but no avail: It might be interesting to note that Jean-Pierre Kahane and Yitzhak…
anonymous
1 2 3
67 68