Problem 2

[Calvin Arnott]

To be perfectly clear- in problem 2 and problem 3, we have that $\beta > 0$, correct?

[Victor Ivrii]

To be perfectly clear- in problem 2 and problem 3, we have that $\beta > 0$, correct?

Sure you can assume this: $\beta=0$ is covered by (a), (b) and $\beta<0$ is covered by $\beta>0$. However this assumption is not needed.

Cool avatar

[Hanqing Liu]

I think I'm on the wrong track or this question just doesn't seem to be integrable!

[Victor Ivrii]

I think I'm on the wrong track or this question just doesn't seem to be integrable!

Read preamble! Use properties!!! See lectures

[Zarak Mahmud]

This integral can be computed using residues, but I think the whole point of the Fourier tranform is lost if one uses that approach...

[Aida Razi]

Solution is attached!

[Ian Kivlichan]

Aida: How did you do the integral?

[Calvin Arnott]

Problem 2

Let: $ \alpha > 0,    \beta > 0,    n\in\mathbb{N} $. Compute the Fourier transform for:

a. $ \left(x^2 + \alpha^2\right)^{-1} $

Answer

Let $ f\left(z\right) $ be holomorphic on a domain $ D $. Cauchy's formula states that for any positively oriented piecewise smooth simple closed curve $ \gamma \in D $ whose inside $ \Omega $ lies in $ D $:

$$ \forall z \in \Omega: f\left(z\right) = \frac{1}{2 \pi i}\int_\gamma \frac{f\left(\zeta\right)}{\left(\zeta - z\right)} d\zeta $$

$$ \text{Claim: } F\left(k\right) = \int_{-\infty}^{\infty}\frac{e^{-i k x}}{x^2 + \alpha^2}dx = \int_{-\infty}^{\infty}\frac{e^{-i k x}}{\left(x - i\alpha\right)\left(x + i\alpha\right)}dx = \frac{ \pi e^{-\alpha  |k|} }{\alpha } $$

Proof: Let: $ \gamma_r^+ $ be the positively oriented semi-circle on the upper half-plane with radius $ r $, and $ \gamma_r^- $ be the positively oriented semi-circle on the lower half-plane with radius $ r $. Then both $ \{\gamma_r^+,\gamma_r^-\} $ are positively oriented piecewise smooth simple closed curves. Moreover, $ f^+\left(z\right)= \frac{e^{-i k z}}{\left(z + i\alpha\right)} $ and $ f^-\left(z\right) = \frac{e^{-i k z}}{\left(z - i\alpha\right)} $ are holomorphic on $ \gamma_r^+ $ and $ \gamma_r^- $ respectively, as $ e^{z} $ is entire and we avoid the poles of the rational functions on their respective domains. We take cases and apply Cauchy's formula:

$$ \text{Suppose: } k < 0. \text{ Then: } \int_{\gamma_r^+}\frac{\frac{e^{-i k x}}{\left(x + i\alpha\right)}}{\left(x - i\alpha\right)}dx = 2 \pi i f^+\left(i\alpha\right) = 2\pi i \frac{e^{-i k \left(i \alpha\right)}}{\left(\left(i \alpha\right) + i\alpha\right)} = \frac{ \pi e^{\alpha  k} }{\alpha } $$

$$ \text{Suppose: } k > 0. \text{ Then: } \int_{\gamma_r^-}\frac{\frac{e^{-i k x}}{\left(x - i\alpha\right)}}{\left(x + i\alpha\right)}dx = 2 \pi i f^-\left(i\alpha\right) = 2\pi i \frac{e^{-i k \left(i \alpha\right)}}{\left(\left(-i \alpha\right) - i\alpha\right)} = -\frac{ \pi e^{- \alpha  k} }{\alpha } $$

$$ \text{Now, } \int_{\gamma_r}\frac{e^{-i k x}}{\left(x + i\alpha\right)\left(x - i\alpha\right)}dx \text{ is the sum of two integrals:} $$

$$ \int_{\gamma_r^+}\frac{e^{-i k x}}{\left(x + i\alpha\right)\left(x - i\alpha\right)}dx = \int_{-r}^{r}\frac{e^{-i k x}}{x^2 + \alpha^2}dx + \int_{C_r^+}\frac{e^{-i k x}}{\left(x + i\alpha\right)\left(x - i\alpha\right)}dx = \frac{ \pi e^{\alpha  k} }{\alpha }$$

$$ \int_{\gamma_r^-}\frac{e^{-i k x}}{\left(x + i\alpha\right)\left(x - i\alpha\right)}dx = \int_{r}^{-r}\frac{e^{-i k x}}{x^2 + \alpha^2}dx + \int_{C_r^-}\frac{e^{-i k x}}{\left(x + i\alpha\right)\left(x - i\alpha\right)}dx = -\frac{ \pi e^{- \alpha  k} }{\alpha } $$

Where $ C_r $ is the upper or lower half of the half circle. We show that the $C_r$ portion of the integral vanishes as $ r \rightarrow \infty $. Without loss of generality we set $ \alpha $ to $ 1 $ to simplify the inequalities:

$$ \mid \int_{C_r^+}\frac{e^{-i k x}}{x^2 + 1}dx \mid \le \int_{C_r^+} \mid \frac{e^{-i k x}}{x^2 + 1} \mid \mid dx \mid \le \int_{C_r^+}\frac{1}{r^2 - 1} \mid dx \mid = \frac{\pi r}{r^2 - 1} \rightarrow 0 \text{ as } r \rightarrow \infty $$

$$ \text{Then: } \lim_{r \to +\infty} \int_{\gamma_r^+}\frac{e^{-i k x}}{\left(x + i\alpha\right)\left(x - i\alpha\right)}dx \rightarrow \int_{-\infty}^{\infty}\frac{e^{-i k x}}{x^2 + \alpha^2}dx + 0 = \frac{ \pi e^{\alpha  k} }{\alpha } $$

$$ \implies \int_{-\infty}^{\infty}\frac{e^{-i k x}}{x^2 + \alpha^2}dx = \frac{ \pi e^{\alpha  k} }{\alpha } \text{ when } k < 0 $$

And similarly for our $ \gamma_r^- $ integral, changing the bounds of integration and the sign. We have then: $ \frac{ \pi e^{\alpha  k} }{\alpha } $ for $ k < 0 $ and $ \frac{ \pi e^{-\alpha  k} }{\alpha } $ for $ k > 0 $. Thus:

$$ F\left(k\right) = \int_{-\infty}^{\infty}\frac{e^{-i k x}}{x^2 + \alpha^2}dx = \frac{ \pi e^{-\alpha  |k|} }{\alpha }   \blacksquare $$




b. $ x\left(x^2 + \alpha^2\right)^{-1} $

Answer

We have for for any function $ f\left(x\right) $ with Fourier transform $ F\left(k\right), $ the transform of $ g\left(x\right) = x f\left(x\right) $  is given by: $ G\left(k\right) = i\frac{dF}{dk} $. Then:
$$ g\left(x\right) = x\left(x^2 + \alpha^2\right)^{-1} = x f\left(x\right) \implies G\left(k\right) = i\frac{dF}{dk} = i \partial_k \left(\frac{ \pi e^{-\alpha  |k|} }{\alpha }\right) = - i \pi sgn\left(k\right)  e^{-\alpha  |k|} \blacksquare $$

Where $ f\left(x\right) = \left(x^2 + \alpha^2\right)^{-1} $ and $ F\left(k\right) = \frac{ \pi e^{-\alpha  |k|} }{\alpha } $ as found in part a.




c. i) $ \left(x^2 + \alpha^2\right)^{-1} \cos\left(\beta x\right)$

Answer

Two properties of the Fourier transform are that for: $ g\left(x\right) = e^{i a x} f\left(x\right) $ the Fourier transform of $ g\left(x\right) $ is given by $ G\left(k\right) = F\left(k-a\right) $, and that the transform is linear: $ h\left(x\right) = a f\left(x\right) + b g\left(x\right) \implies H\left(k\right) = a F\left(k\right) + b G\left(k\right) $

$$ \text{Now, } \cos{\beta x} = \frac{1}{2}\left(e^{i \beta x} + e^{- i \beta x}\right) \text{ so we write:} $$

$$ \left(x^2 + \alpha^2\right)^{-1}\cos\left(\beta x\right) = \frac{1}{2}\left(e^{i \beta x} \left(x^2 + \alpha^2\right)^{-1} + e^{- i \beta x} \left(x^2 + \alpha^2\right)^{-1}\right) $$

$$ \text{Then our transform is given by: } G\left(k\right) = \frac{1}{2}\left(F\left(k-\beta\right) + F\left(k+\beta\right)\right) \text{ where: } $$

$$ F\left(k\right) = \int_{-\infty}^{\infty}\frac{e^{-i k x}}{x^2 + \alpha^2}dx = \frac{ \pi e^{-\alpha  |k|} }{\alpha } \text{ is our transform from part a.} $$

$$ \implies G\left(k\right) = \frac{1}{2} \left( \frac{ \pi e^{-\alpha  |k - \beta|} }{\alpha } + \frac{ \pi e^{-\alpha  |k + \beta|} }{\alpha }\right) \blacksquare $$




ii) $ \left(x^2 + \alpha^2\right)^{-1} \sin\left(\beta x\right)$

Answer

$$ \text{Proceeding as in part c. i): } \sin{\beta x} = \frac{1}{2i}\left(e^{i \beta x} - e^{- i \beta x}\right) \text{ so we write:} $$

$$ \left(x^2 + \alpha^2\right)^{-1}\sin\left(\beta x\right) = \frac{1}{2i}\left(e^{i \beta x} \left(x^2 + \alpha^2\right)^{-1} - e^{- i \beta x} \left(x^2 + \alpha^2\right)^{-1}\right) $$

$$ \text{Then our transform is given by: } G\left(k\right) = \frac{1}{2i}\left(F\left(k-\beta\right) - F\left(k+\beta\right)\right) \text{ where: } $$

$$ F\left(k\right) = \int_{-\infty}^{\infty}\frac{e^{-i k x}}{x^2 + \alpha^2}dx = \frac{ \pi e^{-\alpha  |k|} }{\alpha } \text{ is our transform from part a.} $$

$$ \implies G\left(k\right) = \frac{1}{2i} \left( \frac{ \pi e^{-\alpha  |k - \beta|} }{\alpha } - \frac{ \pi e^{-\alpha  |k + \beta|} }{\alpha }\right) \blacksquare $$




d. i) $ x \left(x^2 + \alpha^2\right)^{-1} \cos\left(\beta x\right)$

Answer

$$ \text{Proceeding as in part c. i): } \cos{\beta x} = \frac{1}{2}\left(e^{i \beta x} + e^{- i \beta x}\right) \text{ so we write:} $$

$$ x \left(x^2 + \alpha^2\right)^{-1}\cos\left(\beta x\right) = \frac{1}{2}\left(e^{i \beta x} x \left(x^2 + \alpha^2\right)^{-1} + e^{- i \beta x} x \left(x^2 + \alpha^2\right)^{-1}\right) $$

$$ \text{Then our transform is given by: } G\left(k\right) = \frac{1}{2}\left(F\left(k-\beta\right) + F\left(k+\beta\right)\right) \text{ where: } $$

$$ F\left(k\right) = \int_{-\infty}^{\infty}\frac{x e^{-i k x}}{x^2 + \alpha^2}dx = - i \pi sgn\left(k\right)  e^{-\alpha  |k|} \text{ is our transform from part b.} $$

$$ \implies G\left(k\right) = \frac{1}{2} \left( - i \pi sgn\left(k - \beta\right)  e^{-\alpha  |k - \beta|} - i \pi sgn\left(k + \beta\right)  e^{-\alpha  |k + \beta|}\right) $$

$$ = - \frac{i \pi}{2} \left(sgn\left(k - \beta\right)  e^{-\alpha  |k - \beta|} + sgn\left(k + \beta\right)  e^{-\alpha  |k + \beta|}\right) \blacksquare $$


ii) $ x \left(x^2 + \alpha^2\right)^{-1} \sin\left(\beta x\right)$

Answer

$$ \text{Proceeding as in part c. ii): } \sin{\beta x} = \frac{1}{2i}\left(e^{i \beta x} - e^{- i \beta x}\right) \text{ so we write:} $$

$$ x \left(x^2 + \alpha^2\right)^{-1}\sin\left(\beta x\right) = \frac{1}{2i}\left(e^{i \beta x} x \left(x^2 + \alpha^2\right)^{-1} - e^{- i \beta x} x \left(x^2 + \alpha^2\right)^{-1}\right) $$

$$ \text{Then our transform is given by: } G\left(k\right) = \frac{1}{2i}\left(F\left(k-\beta\right) - F\left(k+\beta\right)\right) \text{ where: } $$

$$ F\left(k\right) = \int_{-\infty}^{\infty}\frac{x e^{-i k x}}{x^2 + \alpha^2}dx = - i \pi sgn\left(k\right)  e^{-\alpha  |k|} \text{ is our transform from part b.} $$

$$ \implies G\left(k\right) = \frac{1}{2i} \left( - i \pi sgn\left(k - \beta\right)  e^{-\alpha  |k - \beta|} {\alpha } + i \pi sgn\left(k + \beta\right)  e^{-\alpha  |k + \beta|} {\alpha }\right) $$

$$ = - \frac{\pi}{2} \left(sgn\left(k - \beta\right)  e^{-\alpha  |k - \beta|} - sgn\left(k + \beta\right)  e^{-\alpha  |k + \beta|}\right)  \blacksquare $$

[Calvin Arnott]

Part 2

[Zarak Mahmud]

Aida: How did you do the integral?

She didn't. She used a fourier transform pair from part 1(a).

[Aida Razi]

Aida: How did you do the integral?

He didn't. He used a fourier transform pair from part 1(a).

Yes, That's right!
By the way Zarak, I guess it is clear from my name that I am female!

[Victor Ivrii]

This integral can be computed using residues, but I think the whole point of the Fourier tranform is lost if one uses that approach...

Yes, residues work miracles here (see Calvin) but most have not taken Complex Analysis and there is a property for that

$\newcommand{\sgn}{\operatorname{sgn}}$
Calvin, it is $\sgn$ not $sgn$

See source

[Ziting Zhou]

Hi. I answered 2(d) in four cases. Is it not necessary to do it?

[Victor Ivrii]

Ziting, your jpgs are borked. Anyway, we have enough solutions.

Calvin, if you type your solutions in LaTeX or TeX, you could post just the source fixing some discrepancies on the fly

[Ziting Zhou]

Ziting, your jpgs are borked. Anyway, we have enough solutions.

Calvin, if you type your solutions in LaTeX or TeX, you could post just the source fixing some discrepancies on the fly

Yes, there are enough solutions. So I won't post mine. I am still wondering if we need to consider the problem on cases, for example, the transform is not defined when w=β or w=-β. Thanks!