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00:00 - 13:0013:00 - 21:0021:00 - 00:00

Kevin Driscoll
Kevin Driscoll
21:00
@Robjohn AH that makes sense. Now all we have are internet memes.
robjohn
robjohn
@KevinDriscoll Monty Python is still available and still funny.
3
Kevin Driscoll
Kevin Driscoll
Its true, but they arent as big a part of nerd culture as they once were.
Daniel Fischer
Daniel Fischer
Is it still a nerd culture at all then?
Kevin Driscoll
Kevin Driscoll
I guess that depends on if you allow your definition to 'float'
user127001
user127001
My question got re-opened after 17 days lol
Ted Shifrin
Ted Shifrin
21:06
@Daniel: I find that so fulfilling that you are so offended :P
hi @robjohn, @Kevin
Gabriel R.
Gabriel R.
@KevinDriscoll this is exactly why I asked :P
Ted Shifrin
Ted Shifrin
hi again @Gabriel and @user127001
What question, @user127001?
Kevin Driscoll
Kevin Driscoll
@Ted Howdy. Sorry if Ive already pestered you about it, but did you see that I thought of a way to compute my horrible integrals?
Gabriel R.
Gabriel R.
hey @TedShifrin
Ted Shifrin
Ted Shifrin
No, I didn't go look for it. @Kevin
Kevin Driscoll
Kevin Driscoll
21:08
not rigorous at all @Ted
r9m
r9m
@robjohn nooooooooooooooo
Kevin Driscoll
Kevin Driscoll
The answers are not simple.....
Ted Shifrin
Ted Shifrin
Not exactly my cup of tea, @Kevin ...
Kevin Driscoll
Kevin Driscoll
Haha, I imagined not. At least you were right though! There's a way to do it. @Ted
robjohn
robjohn
@r9m I have the Luke Skywalker "Noooooo!" as a ringtone on my phone.
Ted Shifrin
Ted Shifrin
21:10
Now that I see the question, I'm surprised to have been right.
Kevin Driscoll
Kevin Driscoll
Hahaha, fake it til you make it!
r9m
r9m
@robjohn lol ..
Chris's sis
Chris's sis
A funny double inequality I met while learning some stuff in complex analysis $$\left|e^{z}-\sum_{k=0}^{n} \frac{z^k}{k!}\right|\le \left| e^{|z|}-\sum_{k=0}^{n} \frac{|z|^k}{k!}\right| \le |z|^{n+1} e^{|z|}$$
It seems a piece of cake to finish Fresnel integrals by complex analysis.
(A proper slice of pizza makes the job :-))
robjohn
robjohn
@Chris'ssis the first inequality is pretty easy. The second one is not so obvious (or I am missing it).
Chris's sis
Chris's sis
21:25
@robjohn Yeah, right! Well, maybe it's not that obvious, but it doesn't require any special manipulation.
Daniel Fischer
Daniel Fischer
@robjohn The second one is very brutal, $$\sum_{k=n+1}^\infty \frac{\lvert z\rvert^k}{k!} = \lvert z\rvert^{n+1}\sum_{m=0}^\infty \frac{\lvert z\rvert^m}{(m+n+1)!} \leqslant \lvert z\rvert^{n+1}\sum_{m=0}^\infty \frac{\lvert z\rvert^m}{m!}.$$
robjohn
robjohn
@DanielFischer yeah, I was just writing that out to check. Nice.
Chris's sis
Chris's sis
That's the work!
r9m
r9m
Prestige
robjohn
robjohn
@DanielFischer sometimes when the inequality is so overwhelming, it is hard to find a proof at first. :-)
Daniel Fischer
Daniel Fischer
21:30
It's a waste, we could write $$\leqslant \frac{\lvert z\rvert^{n+1}}{(n+1)!}e^{\lvert z\rvert}.$$
Chris's sis
Chris's sis
21:42
@DanielFischer Do you remember some particular cases involving the evaluation of some integrals by complex analysis where these inequalities are very useful?
@DanielFischer I noticed that often one needs to be pretty good at manipulating inequalities for nicely showing that some integrals tend to $0$.
Daniel Fischer
Daniel Fischer
@Chris'ssis Let me quote Peter: "I don't remember. I don't recall. I have no memory of anything at all." No, I don't remember any such occurrence.
Chris's sis
Chris's sis
@robjohn I previous had to show that $$\left| \int_0^{\pi/4} e^{-R^2} e^{2x i} R e^{x i} i \ dx\right| \rightarrow 0$$ as $R$ goes to $\infty$.
In a textbook is given a way that I think it can be improved.
@DanielFischer OK
previously
Chris's sis
Chris's sis
22:06
@N3buchadnezzar you should probably know how to nicely prove that integral converges to $0$. It seems to me that you're involved in learning complex analysis these days. :D
N3buchadnezzar
N3buchadnezzar
Yeah =)
Chris's sis
Chris's sis
:D
N3buchadnezzar
N3buchadnezzar
I just proved Jordans lemma and corollary
Chris's sis
Chris's sis
Good.
robjohn
robjohn
@Chris'ssis is that to show that the integral along a big arc goes to $0$?
Chris's sis
Chris's sis
22:12
@robjohn Exactly.
Mike
Mike
@Daniel It turns out I misunderstood what my homework was, and my professor forgot that the spectral theorem was nontrivial.
robjohn
robjohn
@Chris'ssis usually noting that on $[0,\pi/2]$, $\frac{2x}{\pi}\le\sin(x)\le x$ often helps
Chris's sis
Chris's sis
@robjohn Yeah! :-)
Daniel Fischer
Daniel Fischer
@Mike And what aws the homework meant to be?
Mike
Mike
@Daniel "Prove the spectral theorem for compact self- adjoint operators." No fancy machinery intended.
He didn't realize it wasn't an easy proof.
(on a Hilbert space)
Daniel Fischer
Daniel Fischer
22:25
I should look at the proof of the spectral theorem for compact operators an a Banach space in Rudin, and see what can be simplified and how much for compact normal operators on a Hilbert space. I guess some things get substantially easier, but the entire thing probably remains somewhat nontrivial.
Chris's sis
Chris's sis
@robjohn btw, I think I'll try the summation by parts to that series (just thought of it while working on some different questions)
N3buchadnezzar
N3buchadnezzar
@Chris'ssis It is enough to prove jordans lemma then, who cares about each special case that follows?
robjohn
robjohn
@Chris'ssis to which series?
Chris's sis
Chris's sis
@robjohn the one involving the convergence you proved it diverges.
robjohn
robjohn
@Chris'ssis I thought I used summation by parts.
Chris's sis
Chris's sis
22:35
@robjohn I didn't note that. (honestly)
robjohn
robjohn
@Chris'ssis second equation to $(2)$.
Chris's sis
Chris's sis
@robjohn The summation by parts may be applied in various way though, depending on the way you choose the sequences.
robjohn
robjohn
@Chris'ssis okay. I will be interested to see how that goes.
Alec Teal
Alec Teal
Continuity from the right $\forall\epsilon>0\exists\delta>0:0\le x-c<\delta\implies|f(x)-f(c)|<\epsilon$ is okay right? If the limit from the right exists then $f(c)$ is that limit, so I took that definition and strapped the $x=c$ case on to it. I am confident this is fine, is it?
robjohn
robjohn
@AlecTeal it looks okay to me.
Alec Teal
Alec Teal
22:46
Thanks.
Chris's sis
Chris's sis
@robjohn in my proof I apply the summation by parts from the beginning ... then I saw that I reached the same expressions as yours ...
@robjohn I'll modify many things there to be different.
@robjohn the idea is to get a different proof, not the same proof a bit changed.
@robjohn from the beginning I used $$ a_k=\frac{1}{k}, \space b_k=\frac{\sin(H_k)}{H_k}$$
then applied the summation by parts
robjohn
robjohn
@Chris'ssis and $\frac1k=H_k-H_{k-1}$
Chris's sis
Chris's sis
@robjohn OK, I'll check another way.
@robjohn It's unbelievable it cannot be done by other means... Some professors I talk to failed to finish it too.
robjohn
robjohn
@Chris'ssis I haven't tried anything else since that approach is so strongly suggested.
Chris's sis
Chris's sis
@robjohn I agree that it's a natural thing to think of the summation by parts.
@robjohn If I posted this question on MSE, then I'd also add a 500 points bounty since I'm curious if someone might come up with a better proof than what you found. :-)
@robjohn At the moment I really doubt this is possible ....
@robjohn the proof is right in the heart of the question ... it's a deadly proof
robjohn
robjohn
23:13
@Chris'ssis :-p
Chris's sis
Chris's sis
@robjohn I think I should read some more on convergence series topic.
Now I'm out for a while. :-)
robjohn
robjohn
Ugh... I was just serially upvoted. Luckily, only 3 votes counted, the others were past the cap.
@Chris'ssis have fun
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