Mathematics - 2012-11-30 (page 4 of 6)

robjohn

1:00 PM

@cassandra0 link?

cassandra0

you already saw it!

Here math.stackexchange.com/questions/247733/…

but basically I understand the result of prime number theorem now so that was really nice

Peter Tamaroff

@robjohn Say $f$ is integrable over $[a,b]$

robjohn

@cassandra0 Oh! I thought you were talking about Argon. sorry

cassandra0

I was trying to explain a basic things about generating functions to Argon but I don't think I did it well

Peter Tamaroff

My lemma is that if $P$ is a partition such that $U(f,P)-L(f,P)<(b-a)/m$ for some $m$ natural, then there must exist ad index $i$ for which $M_i-m_i<1/m$

I'm not sure about my proof

cassandra0

1:02 PM

it's quite hard with all the infinite series when you only write out first 3 terms

robjohn

@PeterTamaroff What are $M_i$ and $m_i$?

Peter Tamaroff

@robjohn $\sup f$ and $\inf f$ over $[t_{i-1},t_i]$

THe thing is as follows

robjohn

@PeterTamaroff Take the signum function over [-1,1]

Peter Tamaroff

@robjohn ?

Suppose for the sake of contradiction that for evert $1\leq i \leq n$ we have $M_i-m_i\geq 1/m$

Then $$\frac 1 m (b-a)=\frac 1 m \sum_{i=1}^n (t_i-t_{i-1})$$

robjohn

@PeterTamaroff on some interval $M_i-m_i=2$ or $1$

Peter Tamaroff

1:07 PM

$$ \sum_{i=1}^n \frac 1 m (t_i-t_{i-1})\geq \sum_{i=1}^n(f(t_i)-f(t_{i-1})) (t_i-t_{i-1})=U(f,P)-L(f,P)<(b-a)/m $$

@robjohn Well, but there are many points where $M_i-m_i=0$ right?

robjohn

@PeterTamaroff Oh, you are looking for just one interval that is shallow?

Peter Tamaroff

@robjohn Yes. FOr some index $i$

robjohn

@PeterTamaroff That is trivial.

Peter Tamaroff

@robjohn ¬¬

@robjohn Is my "Proof" ok?

The thing is I have a $\geq$ in the middle of a $<$ argument

I mean, I get $A<blah\geq blah <A$

robjohn

@PeterTamaroff yes, if I am reading it right

@PeterTamaroff that is not good

Peter Tamaroff

1:13 PM

@robjohn Why is it "trivial"?

@robjohn Yes, I know...

=(

peoplepower

I don't see how there can be a contradiction using that sequence of inequalities.

robjohn

@peoplepower That is why I said it is not good

Peter Tamaroff

$$\frac 1 m (b-a)=\sum_{i=1}^n \frac 1 m (t_i-t_{i-1})\geq \sum_{i=1}^n(M_i-m_i)(t_i-t_{i-1})=U(f,P)-L(f,P)<(b-a)/m$$

THat is what I wrote

robjohn

@PeterTamaroff Yes, but you need to break that into two inequalities, one that you derived, and one that is supposed to be true

Peter Tamaroff

@robjohn Oh, OK.

robjohn

1:16 PM

I can see what you mean, but your notation is not good

Peter Tamaroff

@robjohn Yeah.

cassandra0

do you have a favorite proof of betrands postulate?

Peter Tamaroff

$U(f,P)-L(f,P)<(b-a)/m$ by hypothesis

And I seem to arrive to $U(f,P)-L(f,P)\leq (b-a)/m$

That's no good.

robjohn

$$
\begin{align}
U(f,P)-L(f,P)
&=\sum_i(M_i-m_i)(x_i-x_{i-1})\\
&\ge\frac1m(b-a)
\end{align}
$$
but by hypothesis $U(f,P)-L(f,P)<\frac1m(b-a)$

Peter Tamaroff

Oh, duh.

@robjohn =)

I was thinking it right, writing it wrong.

robjohn

1:21 PM

@PeterTamaroff trivial?

Peter Tamaroff

@robjohn Nah.

robjohn

@PeterTamaroff Okay, then I retract my comment about triviality :-)

Peter Tamaroff

@robjohn I don't like the word trivial that much.

peoplepower

@PeterTamaroff Find a subgroup of a group. The answer to this trivial problem is one of the trivial subgroups. :)

cassandra0

hello

trivial just means that it comes without exploiting deeper properties

Peter Tamaroff

1:26 PM

@cassandra0 Not really.

(Methinks)

Trivial, for me, means dead obvious

And most things aren't.

Trivial is very subjective.

Our bag of trivialities gets filled up with time. Surely rob's is bigger than mine.

(And that should not be taken out of context.)

cassandra0

:)

* $\nu(x) = \sum_{p \text{ prime} \le x} \log(p)$
* $\psi(x) = \nu(x) + \nu(x^{\frac{1}{2}}) + \nu(x^{\frac{1}{3}}) + \ldots$
* $\log([x]!) = \psi(x) + \psi(x/2) + \psi(x/3) + \ldots$

Peter Tamaroff

@robjohn

robjohn

@PeterTamaroff yes?

Peter Tamaroff

I'm showing that if $f$ is R integrable over $[a,b]$ then the set of "continuities" of $f$ is dense over $[a,b]$

robjohn

@PeterTamaroff Don't you want to show that the set of discontinuities is a set of measure 0?

Peter Tamaroff

1:35 PM

@robjohn I don't really know how to show that. But it would be good. =)

How does one construct a measure?

cassandra0

'm having trouble seeing this for x=7. I actually get two different answers

robjohn

@PeterTamaroff You can define the idea of a null set (set of measure 0) without really defining a measure

Peter Tamaroff

DEFINITION: A null set is...?

cassandra0

set of measure 0

robjohn

@PeterTamaroff Look here: en.wikipedia.org/wiki/Null_set#Lebesgue_measure

cassandra0

1:37 PM

do you have definition of set of measure 0?

I'll explain it yf you like

Peter Tamaroff

@robjohn You Wikipediated me! How dare you!

@robjohn =)

robjohn

@PeterTamaroff It can be contained in a union of intervals whose total length is arbitrarily small

Peter Tamaroff

@robjohn I see.

►

2

That is bliss.

N3buchadnezzar

Parsevals identity, why art thou so evil...

Peter Tamaroff

@N3buchadnezzar They are nice! Not evil,

N3buchadnezzar

1:42 PM

Maybe

cassandra0

1

A: Fouriercoefficient of the sawtooth wave help to find that the bessel equation gives $\sum \frac{1}{k^2}=\frac{\pi^2}{6}$

The fourier coefficients for nonzero $n$ are $$\begin{eqnarray} \hat f(n) &=& \frac{1}{2 \pi} \int_0^{2 \pi} (\pi-t) e^{-i n t} dt \\ &=& \frac{1}{2} \int_0^{2 \pi} e^{-i n t} dt - \frac{1}{2 \pi} \int_0^{2 \pi} t e^{-i n t} dt \\ &=& - \frac{1}{2 \pi} \left(\left[t \frac...

parseval identity

N3buchadnezzar

So given $$ f(x) = \left\{ \begin{array}{ccc} (\pi - a)x & \text{if} & x\leq a \\
(\pi-x)a & \text{if} & x>a \end{array} \right. $$

Then Parsevals identity when developing the series gives

cassandra0

what

N3buchadnezzar

$$ \frac{1}{2\pi} \int_0^{\pi} f(x)^2\mathrm{d}x = \sum_{n=1}^\infty a_n^2 + b_n^2 $$ ? =)

Peter Tamaroff

@rob

Is the FIT equivalent to completeness?

robjohn

1:51 PM

@PeterTamaroff FIT Fourier Inversion Theorem?

Peter Tamaroff

@robjohn I meant Fitted intervals theorem

Nested intervals theorem

robjohn

@PeterTamaroff what is that?

Peter Tamaroff

Cantor's

robjohn

This one? en.wikipedia.org/wiki/Cantor%27s_Intersection_Theorem

Peter Tamaroff

Yes.

robjohn

1:52 PM

Then yes, the space has to be complete

Peter Tamaroff

but only the case of $\Bbb R$

I mean if we take NIP as an axiom, we can deduce completeness

NIP=Nested INterval Property

robjohn

@cassandra0 my favorite method of computing $\zeta(2k)$ is here

@PeterTamaroff I guess it depends on how you state the FIP (finite intersection property)

@cassandra0 The fact that the generating function is pretty simple is nice.

cassandra0

That's incredible!

(1) is actually such a simple calculation

Peter Tamaroff

@robjohn Let $I_n$ be a sequence of closed intervals with the property that $I_{i+1}\subseteq I_{i}$. Then $\bigcap_{n\in \Bbb N} I_n$ is nonempty.

robjohn

@PeterTamaroff I would require that the $I_n$ have the finite intersection property

Old John

2:02 PM

@PeterTamaroff does $[n,\infty)$ count as a closed interval?

Peter Tamaroff

@robjohn I'm stating it as a principle. For $I_n$ subsets of $\Bbb R$

@OldJohn Nope. Thats a ray! =D

Old John

@PeterTamaroff just checking on your terminology :)

robjohn

@PeterTamaroff That's right, you have a decreasing chain of non empty sets... okay

cassandra0

@OldJohn, do you have an insight on this?

33 mins ago, by cassandra0

* $\nu(x) = \sum_{p \text{ prime} \le x} \log(p)$
* $\psi(x) = \nu(x) + \nu(x^{\frac{1}{2}}) + \nu(x^{\frac{1}{3}}) + \ldots$
* $\log([x]!) = \psi(x) + \psi(x/2) + \psi(x/3) + \ldots$

Old John

@cassandra0 looks vaguely familiar from Hardy and Wright ... what is the problem?

cassandra0

2:04 PM

I just don't see why the last equation holds

I've been trying examples and they do match up

Old John

OK - will do a bit of checking ...

cassandra0

wait don't go to the trouble it's ok

I'll try more examples and see if I get anything

Old John

2:15 PM

@cassandra0 what do you get for the value of $\psi(10)$?

cassandra0

well $\sqrt[4]{10}$ = 1.778.. so $\psi(10) = \nu(10) + \nu(3.162277..) + \nu(2.1544) + 0 + 0 +\ldots $ $= (l(7)+l(5)+l(3)+l(2))+(l(3)+l(2))+l(2)$

7.8320141...

Old John

so ... $3\log 2 + 2\log + \log 5 + \log7$?

cassandra0

yes

Old John

(better to leave it as logs, I think)

cassandra0

interesting to collect like term like that

Old John

2:19 PM

I am convinced it is true now - just need to justify the equivalence of the 2 sides

must be something to do with contributions from prime powers dividing $x!$, I think

peoplepower

Why don't we take exponentials and compare with $\sum [n/p^k]$ which represents the greatest power of $p$ dividing $n!$.

Old John

@peoplepower yep - I was about to suggest the formula for the greatest power of $p$ dividing $n!$ :)

and notice that $p<x^{1/2}$ means the same as $p^2<x$ etc.

cassandra0

$e^{\psi(x)} = \prod_{p^r \le x} p^{r}$

peoplepower

You can also look at $e^{\psi(x)}$ as the product of $p^{\alpha}$ (over p, now) where $\alpha$ is maximal such that $p^{\alpha}\leq x$.

Now, how do $e^{\psi(x)}$ and $e^{\psi(x/n)}$ relate, isolating a prime?

cassandra0

oh I see

the if $p^{\beta_p}$ is in $n$ then we'll have $p^{\alpha-\beta_p}$ in the second one

so it cuts out some primes

peoplepower

2:31 PM

What do you mean by "is in $n$"?

cassandra0

higest prime power dividing n

peoplepower

Doesn't work.

For instance 5<7 but 5>7/3.

cassandra0

ah

peoplepower

I think we are interested in the factorization of $n$ with respect to $p$ though.

Since $p^{\beta}\leq x/p$ implies $p^{\beta+1}\leq x$.

cassandra0

yes that seems a good way to do it just prove it for every prime

oh I thought of something

consider the prime powers in x, then the prime powers in sqrt{x} are the just the same but with the indices halved

e.g. if x = 2 * 3^2 * 5^3 then $\sqrt{x}$ has 3 * 5

that's example is not really right but I think the statement is true

peoplepower

2:39 PM

Is that relevant? I'm not seeing how we can use it yet.

cassandra0

it helps me understand $\psi$ better, but I don't know a way to use it

peoplepower

Indeed if the $p$ component of $e^{\psi(x/n)}$ is $p^{\alpha}$ and that of $n$ is $p^\beta$ then that of $e^{\psi(x)}$ is $p^{\alpha+\beta}$.

Thus, find $n$ such that $p^1$ is the highest power less than or equal to $x/n$.

Only problem is that we can take $n+1$ and get a different answer at the end. :(

cassandra0

Ithink I was wrong about $\sqrt{x}$, but instead (I think OldJohn siad this) that if $p \le x^{1/r}$ we would have $r \log(p)$ in $\psi(x)$

one for each the $\nu$ that $p$ still lives in

peoplepower

Yes.

Peter Tamaroff

@peoplepower If $A$ is countable, does it have measure $0$?

I mean lebesgue measure,

Old John

2:49 PM

@PeterTamaroff yes

Peter Tamaroff

@OldJohn How does that follow?7

Old John

If $A$ is countable, we have $A$ listed as $a_1, a_2, \dots$

cassandra0

just cover teh countable set in intervals that decrease with order \epsilon/n^2

Peter Tamaroff

@OldJohn OK.

Old John

then cover with intervals ... what @cassandra0 said :)

Peter Tamaroff

2:50 PM

We take $\epsilon/2^n$ nbhds?

Old John

@PeterTamaroff that would do

cassandra0

that works too

Peter Tamaroff

So $$\sum_{n=0}^\infty \epsilon /2^n=\epsilon$$ or something of the sort?

Old John

yep

so, for example, the rationals in the unit interval can be covered by intervals of total length as small as you wish

Peter Tamaroff

@OldJohn I was telling robjohn I showed the set of continuities of a riemann integrable function over some closed interval is dense there,

Now I want to show the set of discontinuities is countable.

viz, it has measure zero

or to show it is a null set

peoplepower

2:53 PM

You could also take a sequence of finite sets $A_n$ whose union is the set in question. Then use the formula $m(\bigcup A_n)\leq \sum m(A_n)=0$.

Peter Tamaroff

@peoplepower Hmm... I know nothing about set theory. I just know little random stuff

But I can get through some simple definitions like that of null set

peoplepower

This follows from $m$ being a subadditive function.

N3buchadnezzar

is argon here?

Old John

@PeterTamaroff sounds plausible - but I can't recall the conditions for a function to be Riemann integrable

and I have to go - got to get ready for a new kitchen :(((

Peter Tamaroff

@OldJohn Super sad smiley?

Old John

2:57 PM

@PeterTamaroff yeah - clearing absolutely everything out of the old kitchen is exceedingly boring

but it must be done - later all!

cassandra0

bye

N3buchadnezzar

Todays integral: Prove that $$I = \int_{-\infty}^\infty \frac{\pi}{2} - \arctan(x^2)\,\mathrm{d}x = \pi \sqrt{2} $$

Peter Tamaroff

@N3buchadnezzar I think I already did that.

Once...

peoplepower

I have to sleep sometime today, why not at 10am? ;)

Peter Tamaroff

@peoplepower It is 12am here

N3buchadnezzar

2:59 PM

@PeterTamaroff By parts until you lost your sanity or ? ;)

Peter Tamaroff

@N3buchadnezzar I can't recall now.

peoplepower

@cassandra0 Sorry I did not help you with the entirety of your question. Hopefully you will see what to do from here. It's from a proof of PNT right?

cassandra0

I still don't see the equality but I'll keep going

peoplepower

@PeterTamaroff The times look so similar, but really they are so far!

N3buchadnezzar

Math <3

Exam tommorow

:D

cassandra0

3:08 PM

could we say $$n! = (\prod_{p \le n} p)(\prod_{p^2 \le n} p)(\prod_{p^3 \le n} p)\cdots$$

seems not

hi Argon

Argon

@cassandra0 Hi

cassandra0

sorry I didn't the generating function well yesterday :(

N3buchadnezzar

@Argon See todays integral a few posts up =)

cassandra0

you guys do realize I can't do a single one of these integrals

Argon

@N3buchadnezzar I see it. So far I have $$\int_{-\infty}^\infty \int_{x^2}^1 \frac{1}{y^2+1} \,dy \,dx$$ though I may be off the mark

cassandra0

3:18 PM

wow

N3buchadnezzar

@Argon Clever, but I do not think fubini applies here, since the area is not closed.

Argon

@N3buchadnezzar Ok, I will try something else

N3buchadnezzar

@Argon Is not the expression you wrote slightly off? It gives med $\frac{\pi}{4} - \arctan(x^2)$ which clearly diverges.

Argon

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

N3buchadnezzar

I think I figured it out

@Argon Rewrite $\arctan(x^2)$ as a taylor series, evaluated at infinity

Eg

Argon

3:27 PM

@N3buchadnezzar I had thought of that too

But I didn't like the $\pi/2$

N3buchadnezzar

Because of symetry we have

Argon

I will try it though

N3buchadnezzar

@Argon You already have a $\pi/2$ in the integral...

They cancel!

Argon

Nice. What do we have then?

N3buchadnezzar

$$ \int_{-\infty}^{\infty} \ldots = 2 \int_0^\infty \ldots $$

$$\arctan(x) = \frac{\pi}{2} - \frac{1}{x} + \frac{1}{3x^3} - \frac{1}{5x^5} + \ldots$$

You do the rest ^^

cassandra0

3:35 PM

I just can't see this identity at all

N3buchadnezzar

@cassandra0 Well the taylorseries to $\arctan(x)$ you know right?

cassandra0

sorry I mean the prime numbers one

N3buchadnezzar

Ooooh, sorry. Please do not ask me! Ask John or Rob!

@Argon The x=0 messes things up...

Argon

@N3buchadnezzar x=0? Where?

N3buchadnezzar

@Argon $ \displaystyle \int_{x=0}^{x = \infty}$ (Please do not hurt me for using this definitition)

Argon

3:42 PM

@N3buchadnezzar Hahaha :)

N3buchadnezzar

as x tends to zero the whole thing blows up

Argon

@N3buchadnezzar That would be a problem. 1 sec

This is the expansion at infinity, right?

N3buchadnezzar

@Argon Indeed

Jayesh Badwaik

@N3buchadnezzar what are you guys doing?

N3buchadnezzar

@JayeshBadwaik $$ \int_{\mathbb{R}} \frac{\pi}{2} - \arctan(x^2)\,\mathrm{d}x = \pi \sqrt{2}$$

Argon

3:48 PM

Is Fubini really futile here: $$\int_{-\infty}^\infty \int_{x^2}^\infty \frac{1}{y^2+1} \,dy \,dx$$?

Jayesh Badwaik

@Argon don't we have to show the integral of the absolute value is finite in the first place?

cassandra0

hi @amWhy

Jayesh Badwaik

@N3buchadnezzar Use
\begin{align}
\frac{\pi}{2} - \arctan(x^2) = \operatorname{arccot} (x^2)
\end{align}

Argon

$\arcot$

What is it?

$\operatorname{arccot}$

Use \operatorname{}

Jayesh Badwaik

Yeah

I thought arccot would be defined for sure?

;-)

Anyway, after this substitute $x^2 = \cot \theta$

Argon

4:13 PM

@N3buchadnezzar wolframalpha.com/input/…

The answer seems to be $\frac{\pi}{\sqrt{2}}$

N3buchadnezzar

@JayeshBadwaik Clever

Argon

Indeed

Jayesh Badwaik

@N3buchadnezzar Well, every dawg has his day. :-)

Argon

What's another fun one?

N3buchadnezzar

$$\int_0^1 \log(t) \log(1-t)\,\mathrm{d}t$$ ?

^^

Argon

4:24 PM

Hmmm...

Symmetrical

N3buchadnezzar

Compare it to

$$ y = \sqrt{1/4 - (t-1/2)^2} $$ ^^

Peter Tamaroff

@JayeshBadwaik Sir,

Jayesh Badwaik

@PeterTamaroff Dawg,

Peter Tamaroff

@JayeshBadwaik Me has a question,.

Jayesh Badwaik

@PeterTamaroff Speaketh,.

Peter Tamaroff

4:29 PM

@JayeshBadwaik Let $f:V\to V$ be a linear transform, and $dim V=2$

Jayesh Badwaik

okay.

Peter Tamaroff

Then $f$ is nilpotent if and only if $f^n=0$

One direction is trivial by defintion

Consdier the other. Say $\dim V=n$ and $f$ is nilpotent

Jayesh Badwaik

okay. And you want to prove that $f^n = 0$?

Peter Tamaroff

then there exists an $s\in \Bbb N$ suh that $f^s=0$

@JayeshBadwaik Yes.

I'm advised to think if the inclusions $Ker(f^i)\subseteq Ker(f^{i+1})$ are strict or not

Jayesh Badwaik

@PeterTamaroff I am still not getting you, what does $f$ is nilpotent imply other than $f^k(v)=0$ for some $k$?

Peter Tamaroff

4:35 PM

@JayeshBadwaik Nothing more than that

I have proven that $f$ can't be neither mono neither epimorphism

Jayesh Badwaik

@PeterTamaroff Then isn't it just a matter of definition? If you go into matrices, then a non-zero matrix with determinant zero is nilpotent.

Peter Tamaroff

@JayeshBadwaik Well, the thing is to prove that $k=n$

If $\dim V=n$ and $f$ is nilpotent, then $f^n=0$

Jayesh Badwaik

@PeterTamaroff No, $k \leq n$ where $k$ is the $\inf$ of all such $k_i$

Peter Tamaroff

@JayeshBadwaik ?

Well, yeah

Hehehehe

@JayeshBadwaik I mean that $n$ is one of the solutions

"solutions"

So the thing would go

Jayesh Badwaik

@PeterTamaroff This is strict I think.

Peter Tamaroff

4:38 PM

Let $\dim V=n$ and $f$ nilpotent. Then there exists $k$ such that $f^k=0$,. Consider the set $K=\{k:f^k=0\}$. By the well ordering principle $K$ has a least element $k'$. We wish to prove $k'\leq n$

Jayesh Badwaik

@PeterTamaroff okay, I am inclined to kick in linear independence at this stage.

cassandra0

how would I show $\nu(x) - \nu(x^{\frac{1}{2}}) + \nu(x^{\frac{1}{3}}) - \nu(x^{\frac{1}{4}}) + \ldots \le \nu(x)$?

Peter Tamaroff

@JayeshBadwaik I'm all eyes.

@cassandra0 You should study from some book...

Apostol's Analytic number theory is good, I guess.

Ilya

strangely, I have not found an answer to this question by a quick search

is the Cantor space separable?

cassandra0

I just want to prove this

Peter Tamaroff

4:42 PM

@Ilya This is offinle brubeck.jdabbs.com/the-cantor-set/separable

Ilya

I saw that, Peter

Peter Tamaroff

@cassandra0 And what theory do you know that you think will do?

@Ilya =P

Ilya

btw, added you on facebook

cassandra0

???

Peter Tamaroff

@Ilya Me?

Ilya

4:43 PM

aha

check out your requests

Jayesh Badwaik

@PeterTamaroff I suppose it might be easier to show the stuff for matrix, and then use isomorphism of any vector space of dimension $n$ to $F^n$

@Ilya sorry. Victim of the moving chat.

Ilya

np :)

Jayesh Badwaik

:-)

cassandra0

I got it each $- \nu(x^{\frac{1}{n}}) + \nu(x^{\frac{1}{n+1}})$ is $\ge 0$.

Jayesh Badwaik

@Ilya Cantor space is countable in itself? Countable union of finite sets? And it is dense.

Peter Tamaroff

4:46 PM

@JayeshBadwaik How so?

Ilya

@JayeshBadwaik the first thing about the Cantor set is that it is uncountable. Even in itself

Peter Tamaroff

@JayeshBadwaik I mean, this proof, not the isomorphism

@Ilya I don't see it

Ilya

@PeterTamaroff Cantor set is $\{0,1\}^\mathbb N$

Peter Tamaroff

@Ilya I know, I mean your FB request!!!

this is getting messy"!

cassandra0

@Ilya, that's not the Cantor set I have in mind

Peter Tamaroff

4:47 PM

@cassandra0 What is yours?

It must surely be homeomorphic

cassandra0

en.wikipedia.org/wiki/Cantor_set

Jayesh Badwaik

@Ilya Hehe, I went strolling. Sorry (again!).

Old John

If the Cantor set consists of all base 3 "decimals" with only 0 and 2, then isn't the collection of all such "decimals" which terminate a countable dense subset?

Ilya

@OldJohn dense sunset - that's shall be romantic :)

Peter Tamaroff

@cassandra0 Well, that is it, yes.

Old John

4:48 PM

:)

Peter Tamaroff

@Ilya Heheh

Old John

I must be in a romantic mood :)

Jayesh Badwaik

:-)

cassandra0

@OldJohn, I managed to understand this log[x]! thing

Ilya

@OldJohn seems so, thanks

Jayesh Badwaik

4:49 PM

@PeterTamaroff I had proved it sometime back, it is in Artin. Let me recall.

Old John

@cassandra0 well done! - I bet it was something to do with showing that the highest power of $p$ dividing both sides was the same

Jayesh Badwaik

@OldJohn Yes, nice. :-)

cassandra0

yes exactly that

what happened was I was staring at 10 * 9 * 8 * 7 * 6 * 5 * 4 * 3 * 2

the prime 7 occurs once because it's in the bigger half, but the prime 5 occurs twice because it's in the lower half

and then you just do that sum it over powers

Old John

and 3 occurs three times because it is in the lower third etc.

cassandra0

yes exactly that and then 3^2 is in the upper half so you get 3^4

Old John

4:51 PM

- and an extra one because $3^2 < 10$

yep

cassandra0

$$\sum_m \sum_n \sum_{p^m \le \frac{x}{n}} 1$$

gives the order of each prime

and it's easy to turn the claim into this algebraically

Old John

so you have to convince yourself that this all works for any prime

it is a bit like some of the arguments with p-adic numbers

Jayesh Badwaik

@PeterTamaroff I did it like this $\det( A^n) = (\det A)^n$

cassandra0

yes we are taking the p-adic valuation of $e^{\log[x]!}$

Peter Tamaroff

@JayeshBadwaik I have no determinants yet!

Old John

4:53 PM

@cassandra0 yes - I guess we are :)

Peter Tamaroff

This is CH3, and dets is CH5, I think...

=D

cassandra0

@OldJohn, imsc.res.in/~rao/ramanujan/CamUnivCpapers/Cpaper24/page1.htm

so now I got halfway through page 1

Old John

@N3buchadnezzar - there is a question on main which covers the thing I was talking about the other day: $x$ is its won power series :)

@cassandra0 I suspect that it might not be too hard after you have mastered the first bit :)

Jayesh Badwaik

@PeterTamaroff Hmm. Without determinants, you will get into some lengthy argument of linear independence. I am not sure how. Let $L b_i = a_1i b_1 + a_2i b_2 + \cdots + a_ni b_n$ where $b$ are the basis of course. Something like that, which are basically hypervectors. Let me think.

Ilya

@PeterTamaroff Pitt T. you are, right?

Peter Tamaroff

4:56 PM

@Ilya Yes. Tamaroff

Ilya

@PeterTamaroff then I sent you request

Peter Tamaroff

@Ilya I am /ptamaroff

@Ilya How would Tamaroff be spelled?

In cyrilic

Ilya