Higher Level Integration Marathon & Questions (1 Viewer)

leehuan · Apr 2, 2016

Re: Extracurricular Integration Marathon

$\int_{0}^{\infty}{\cos{\left({x}^{2}\right)}\,dx}$

Paradoxica · Apr 2, 2016

Re: Extracurricular Integration Marathon

leehuan said:
$\int_{0}^{\infty}{\cos{\left({x}^{2}\right)}\,dx}$

Done earlier on this thread.

We all know the answer is $\sqrt{\frac{\pi}{8}}$

KingOfActing · Apr 23, 2016

Re: Extracurricular Integration Marathon

$\int_{-\infty}^{\infty} \frac{\sin^2{x}}{1+x^2}\,dx$

Paradoxica · Apr 24, 2016

Re: Extracurricular Integration Marathon

leehuan said:
Not sure if this is doable

$\int_{0}^{n}{\sin{\left\lfloor x \right\rfloor }dx}, n \in \mathbb N$

Then why post it?

leehuan · Apr 24, 2016

Re: Extracurricular Integration Marathon

Nvm deleted it. I was mindlessly experimenting with Wolfram when I realised what the f**** I actually did

Paradoxica · Apr 24, 2016

Re: Extracurricular Integration Marathon

leehuan said:
Not sure if this is doable

$\int_{0}^{n}{\sin{\left\lfloor x \right\rfloor }dx}, n \in \mathbb N$

Since this is a series of rectangles across the real line, convert it into a sum.

Unsing the standard trigo-geometric summation identity for sin(x), the answer is

$\frac{\sin{\frac{n}{2}}\sin{\frac{n-1}{2}}}{\sin{\frac{1}{2}}}$

leehuan · Jun 21, 2016

Re: Extracurricular Integration Marathon

$\int _{ 0 }^{ \infty }{ { e }^{ \cos { x } }\frac { \sin { \left( \sin { x } \right) } }{ x } dx } \\$

Paradoxica · Jun 28, 2016

Re: Extracurricular Integration Marathon

leehuan said:
$\int _{ 0 }^{ \infty }{ { e }^{ \cos { x } }\frac { \sin { \left( \sin { x } \right) } }{ x } dx } \\$

Take the Imaginary part of the following integral:

$\int_0^\infty \frac{e^{e^{ix}}}{x}$d$x$

The imaginary component of the integral is absolutely convergent, and so is the Taylor expansion, so (insert reasoning here) it is valid to exchange summation, integration and complex extraction.

Take the Taylor series of e^x and replace x with e^ix

Swap the order of integration and summation. Integrate termwise.

final answer:

π(e-1)/2

seanieg89 · Jun 28, 2016

Re: Extracurricular Integration Marathon

Paradoxica said:
Take the Imaginary part of the following integral:

$\int_0^\infty \frac{e^{e^{ix}}}{x}$d$x$

The imaginary component of the integral is absolutely convergent, and so is the Taylor expansion, so (insert reasoning here) it is valid to exchange summation, integration and complex extraction.

Take the Taylor series of e^x and replace x with e^ix

Swap the order of integration and summation. Integrate termwise.

final answer:

π(e-1)/2

I don't think that integral is absolutely convergent...there might be a nice way of justifying that interchange, but its not a trivial matter.

Paradoxica · Jun 28, 2016

Re: Extracurricular Integration Marathon

seanieg89 said:
I don't think that integral is absolutely convergent...there might be a nice way of justifying that interchange, but its not a trivial matter.

The Imaginary part is absolutely convergent. The real part is divergent.

IDK about the justification of interchange.

InteGrand · Jun 28, 2016

Re: Extracurricular Integration Marathon

Paradoxica said:
The Imaginary part is absolutely convergent. The real part is divergent.

IDK about the justification of interchange.

Are you absolutely (lol) sure about this?

Paradoxica · Jun 28, 2016

Re: Extracurricular Integration Marathon

InteGrand said:
Are you absolutely (lol) sure about this?

Dirichlet's test.

seanieg89 · Jun 29, 2016

Re: Extracurricular Integration Marathon

The imaginary part of the integrand is the original integrand, which is

$\frac{e^{\cos(x)}\sin(\sin(x))}{x}.$

This is not absolutely convergent. We have something continuous and periodic divided by x. Upon taking absolute values, integrating this is like summing a harmonic series.

The integral converges in the sense of an improper Riemann integral because it oscillates as well as decays (things like the Dirichlet test or alternating series test pin this notion down), but its rate of decay is too slow to give us absolute convergence.

The most common ways of justifying an interchange rely on our limit function being absolutely integrable (the monotone/dominated/vitali convergence theorems), or on us having an absolutely integrable error term which we can bound and show tends to zero, so this is not as routine as you might think, even if it is probably justifiable somehow.

Paradoxica · Jun 29, 2016

Re: Extracurricular Integration Marathon

seanieg89 said:
The imaginary part of the integrand is the original integrand, which is

$\frac{e^{\cos(x)}\sin(\sin(x))}{x}.$

This is not absolutely convergent. We have something continuous and periodic divided by x. Upon taking absolute values, integrating this is like summing a harmonic series.

The integral converges in the sense of an improper Riemann integral because it oscillates as well as decays (things like the Dirichlet test or alternating series test pin this notion down), but its rate of decay is too slow to give us absolute convergence.

The most common ways of justifying an interchange rely on our limit function being absolutely integrable (the monotone/dominated convergence theorems), or on us having an absolutely integrable error term which we can bound and show tends to zero, so this is not as routine as you might think, even if it is probably justifiable somehow.

I don't even know, Leehuan says this is from an IB textbook. Advanced much?

seanieg89 · Jun 29, 2016

Re: Extracurricular Integration Marathon

Paradoxica said:
I don't even know, Leehuan says this is from an IB textbook. Advanced much?

There has to be a less potentially dodgy way of doing it, I also thought of expanding out a series in e^(ix) to start with, but I couldn't see any way of justifying that so I left it.

Gotta be careful with these things, because functions/sequences that oscillate and decay but are not absolutely integrable are a common source of counterexamples to otherwise believable claims.

Paradoxica · Jun 29, 2016

Re: Extracurricular Integration Marathon

seanieg89 said:
There has to be a less potentially dodgy way of doing it, I also thought of expanding out a series in e^(ix) to start with, but I couldn't see any way of justifying that so I left it.

Gotta be careful with these things, because functions/sequences that oscillate and decay but are not absolutely integrable are a common source of counterexamples to otherwise believable claims.

Well the only other way I see is by contouring the first quadrant but like I said.

Too advanced.

leehuan · Jun 29, 2016

Re: Extracurricular Integration Marathon

I don't even know at all. When I first saw this integral I had absolutely no idea on what to do obviously.

Paradoxica · Jun 29, 2016

Re: Extracurricular Integration Marathon

leehuan said:
I don't even know at all. When I first saw this integral I had absolutely no idea on what to do obviously.

I only saw the imaginary extraction during an epiphany on the train last week.

My first thought was contouring due to the singularity but I have little experience with that.

Taylor expansion didn't occur to me until a lot later.

seanieg89 · Jun 29, 2016

Re: Extracurricular Integration Marathon

leehuan said:
I don't even know at all. When I first saw this integral I had absolutely no idea on what to do obviously.

Could you clarify the source and the typical integration techniques used in this book? I will have another look at it later today if I have time.

seanieg89 · Jun 29, 2016

Re: Extracurricular Integration Marathon

Paradoxica said:
Well the only other way I see is by contouring the first quadrant but like I said.

Too advanced.

We are in the extracurricular marathon, so post a contour integration solution if you do find one.

The slow decay of the integrand again makes things nontrivial (what contour do you suggest?), and the singularity is removable, not a pole so there is no benefit in contouring about it (for the original function, it is a pole of the complexified function, but the problem of slow decay remains).

Higher Level Integration Marathon & Questions (1 Viewer)

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