What is the method for solving the Gaussian integral?

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The discussion focuses on solving the Gaussian integral I = ∫ e^{-x^2-4x-1} dx. The user attempts to square the integral and convert it into a double integral, expressing confusion about using polar coordinates for the first time. They find success by completing the square and changing variables, ultimately arriving at the solution I = √π e^3. The conversation highlights the importance of recognizing patterns in Gaussian integrals and suggests that once familiar, the process becomes quicker and easier. The user expresses satisfaction with their progress and looks forward to tackling more complex integrals.
Noorac
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Homework Statement


Find the Gaussian integral:

I = \int_{-\infty}^{\infty} e^{-x^2-4x-1}dx

(That's all the information the task gives me, minus the I=, I just put it there to more easily show what I have tried to do)

2. The attempt at a solution
I tried to square I and get a double integral:


I^2 = \int_{-\infty}^{\infty}\int_{-\infty}^{\infty} e^{(-x^2-4x-1)+(-y^2-4y-1)}dxdy

and then my plan was to convert to polar-coordinates, however, this is my first time ever with double-integrals and/or switching to polarcoordinates, and I am kind of lost because every single example on the internet use the standard e^{-x^2} gaussian function(and it is easy to see r^2=x^2+y^2). Anyone who can push me in the right direction(I'm not even sure what finding the Gassuian integral means(?))?
 
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Complete the square. -x^2-4*x-1=(-(x+2)^2+3). Try using that.
 
Tried that earlier on, but didn't get anywhere with it. Been trying it some more now, but I still don't see it though. I don't see the next step, I'm going to try some more though=) Thanks
 
Noorac said:
Tried that earlier on, but didn't get anywhere with it. Been trying it some more now, but I still don't see it though. I don't see the next step, I'm going to try some more though=) Thanks

Next step would be a change of variables, u=x+2. Keep thinking about it.
 
There! At least I got to the same answer as Wolfram Alpha;

I = \sqrt{\pi}e^{3}

I hope it is correct. The steps I did after changeing variables r^2=(x+2)^2 + (y+2)^2 was substituting

u=r^2

\frac{du}{dr}= 2r

du = 2rdr

dr = \frac{du}{2r}

And just left the 6-constant alone all until I did the actual integral:

2\pi \int_{0}^{\infty} re^{-u+6} \frac{du}{2r}

\pi \int_{0}^{\infty} e^{-u+6}du = \pi e^6

(I think it's correct)
Thanks for the help=)
 
wow that's great.
 
Noorac said:
(I think it's correct)
Thanks for the help=)

That is great. But you don't have the repeat the polar coordinate trick every time you see a Gaussian integral. After you've done it once, you should just remember (or look up) \int_{-\infty}^{\infty} e^{-u^2} du=\sqrt{\pi}
 
Yeah, the next task was somewhat similar, same objective, and it took only 3 minutes compared to the 3-4 hours of the last one =)

Now it's on to triple-integrals and what will probably be the most fun weekend since school ended before christmas!

Again, thanks=)
 

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