thanks @EnjoysMath, great minds right?

rehi @Ted

rehi, a @Balarka

I showed Mike my answer and he says he's glad topology is dead

ROFL.

That was not charitable of him.

He's commenting on how hilariously incomprehensible the formula is but it's actually something really dumb, I am sure

I remember reading about locally flat stuff reading Samelson's proof back from the 60's sometime that justified (in a setting more general than smooth topology) that Poincaré duality corresponded to intersection.

This is exactly how old papers by eg Brown or Bing or ... on geometric topology reads

@TedShifrin Ahh nice

When I started in grad school, I kept bugging everyone about why (in the smooth setting) Poincaré duality corresponded to transverse intersection. Stallings tried to do it at the end of our algebraic topology course, but flubbed it. Bott/Tu had a nice exposition later.

Ultimately, one cannot avoid the Thom class, I've concluded.

Haha. Do you have the Samelson reference? I might actually try to read it

Bott/Tu is pretty slick about it

Oh, that was one of the things I threw out when I retired. Let me see if I can google and find it.

@BalarkaSen @TedShifrin Hi.

Hi @feynhat

hi feyn

@BalarkaSen Up early? or didn't sleep?

Guess

lol, i just checked the transcript.

Nice.

a Balarka is incorrigible.

No luck with googling, a Balarka.

Me and Alessandro encountered local flatness while reading Freedman's notes on the proof of 4D topological Poincare conjecture. We barely started, the first few pages are about the Schoenflies problem

Aw. Thanks for looking around!

It's strange. This shouldn't be that difficult.

What do you refer to?

Finding a list of his papers. I'm 100% sure he's the right author.

Ahh OK

I found "On Poincare duality" by Hans Samelson

grr ... I kept putting flat in there

although I did have Poincaré duality

I remember it as a relatively short article, so that might be it.

Cool, looks like a useful article

Of course, I have no access.

Oh I accessed it somehow

LOL

I am not even in university

You're super-Balarka.

This is strange; a few days ago Mike linked some Springer article that I could access but he couldn't

Maybe my device somehow cached the university access permission

Yup.

Or, you're super-Balarka.

A less likely but more desirable possibility, yes

:)

Cool, Samelson defines the topological Thom class using (without mentioning it) the tangent microbundle

Were microbundles alive in the 50s?

If we want to show two paths are homotopic, the definition requires that the the bottom and the top edge of the homotopy square should be equal to the paths. Now, if instead I construct a square in which the top and bottom edge are homotopic to the paths, it should still work, right?

I am thinking of stitching two square at the top and the bottom which take you to the original paths.

Yes, composition of homotopies are homotopies

Or composition of homotopies is homotopies. No, that's not right, neither.

Lol

@TedShifrin You're right! Microbundles I came out in 64

thanks.

Yeah.

Oh, but that Samelson article is 1965. No problem.

@BalarkaSen Russian bookstore?

Ah nice.

@feynhat No I directly got it from Springer

I remembered 60's at the outset. Just not much more. I thought locally flat was in the title, but ...

the Russian bookstore is not for papers. There's a Russian journal library for that

Dinnertime for this bonzo. Good morning, a @Balarka.

Morning, @Ted!

Bon appetit

That's what I meant yes. The Russian journal library.

$0 \to A \to B \to C \to 0$

why do we say $B$ is an extension of $C$ by $A$ instead of $A$ by $C$

Hi, I have a simple question: If I have m + m^c for some c>0, then how to show that it is equal to m^r for some r with any bound. Do we eliminate m and we get r=c or do we work as following: m + m^c = m(1+m^m^{c-1}). or do we upper bounded and then it is easy to get m^r for some r, e.g. m + m^c <= m^{1+c}.

@BalarkaSen That's Kazakhstani

@BalarkaSen I'll read it later, but I'm disappointed by the lack of push pull arguments

@skullpatrol Hello Pal!

hi pal @Knight

@skullpatrol What are gear systems in your bike?

In some motorbikes, the first gear shifts below and rest of them goes up, while in some other motorbikes all gears shifts down

One down, three up.

@Knight

$\text { Explain why } \vec{a} \downarrow \vec{c}=\vec{a} \downarrow(\vec{b} \downarrow \vec{c}) $ Someone know what this down arrow symbol indicate?

@skullpatrol Wow! But I find it hard and dangerous to shift the gear upwards

Start slowly and carefully @Knight

Yes

√-1 2*4 π and it was delicious!

Hi guys, I'm looking for a non-famous theorms that have multiple-proofs. Those theorems should be solved with the knowledge of students in their first/second semster. Is it possible to get some suggestions? I thought of asking them to prove that $3^n=\sum_{K=0}^{n}{n\choose k}2^k$ but I could only think of two solutions (binomial and combinatorics).

@AlessandroCodenotti Oh right

@AlessandroCodenotti Lol

hi chat

hello

Hi Astyx

Hi @Astyx

@BalarkaSen do you have any idea to my question above

That terminology confuses me a lot actually

I was hoping someone has a good answer

I would say $B$ is an $A$-bundle over $C$, the opposite order to what the algebraists say (I think?)

If $B$ is an $A$-bundle over $C$ it makes sense to say that $B$ is extending $C$ rather than $A$, doesn't it?

I guess

you're thickening $C$ by $A$. Makes sense

Lol, imagine if the reason was simply that the possible $B$'s are classified by $\text{Ext}_{\Bbb ZC}^2(\Bbb Z; A)$

@BalarkaSen Why do we say extension of $C$ by $A$ rather than of $A$ by $C$?

Each node in the following graph is a definition or statement used directly or indirectly in the definition of perfectoid spaces, or in the proofs of the required lemmas. Each edge is a use. There are more than 3000 nodes and 30000 edges. The spatial layout and cluster coloring were computed independently by Gephi, using tools Force atlas 2 and modularity.

@LeakyNun I was looking forward to some more Paganini, wtf is this

lmao

this is the anti-rickroll

LOLOL

I feel that making me read lean is definitely a rick roll

(I'm taking another HoTT course this semester though)

cool

next you're gonna tell me there are 100 ways to prove $\Bbb N = \Bbb N$ and all of the proofs are different

Lmfao

Not only are all the proofs different, the proofs that the proofs are different are also different

Ad infinitum

@LeakyNun The contemporary terminology is that $\Bbb N=\Bbb N$ has many inhabitants, you're so antiquated

That's what they call terms of a type?

Dang

@Thorgott Have you gone through Apostle’s Calculus ?

afraid not

Okay.

hello, please how to prove that the function arccos (the inverse function of cos on [0,\pi]) is no even no odd?

Let $X$ be a sequentially compact metric space. Then, every open cover of $X$ has a lebesgue number.

That's true

Suppose $X$ has an open cover $(U_i)_{i\in I}$, which admits no lebesgue number. In particular, for each $n$, there exists a sequence of non-empty sets, $A_n$, for which, $A_n$ is not contained in any of the $U_i$.Considering AOC, we choose $x_n\in A_n\backslash U_i$. Then, $x_n$ has a convergent subsequence, $(x_{n_k})$ such that $x_{n_k}\rightarrow x$ for some $x\in U_m$. Since $x_{n_k}$ converges, there must exists $K$, for which, $k\geq K$ implies $x_{n_k}\in U_m$. Contradiction.

i'm not sure why I can't choose $x_n's$ like that

Why is $x_{n_k}\in U_m$ a contradiction?

because $x_{n_k}$ was chosen to not be in any of the $U_i's$

@AlessandroCodenotti

oh wait

i confused the quantifiers

The $U_i$'s are a cover so it must be in some of them, I'm not sure what you're doing

yeah, I see it now

It's easier if you use that sequential compactness implies compactness in metric spaces and switch to a finite subcover

$x_n\in A_n\backslash U_i$ doesn't make sense. I see.

@lindaOiladali Because the function $\cos^{-1} x$ is not defined for $-x$ for $0 \leq x \leq \pi$

For a function to be odd or even we have to have $f(-x)$ and $f(x)$ defined

Did you figure it out? @topologicalorientablesurface

@AlessandroCodenotti scacchi?

Nah not now

I'm typing a proof for my thesis

@Balarka are you around?

im asharp

lol

Sanity check, I have a countable simplicial complex $K$, I want to realize $|K|$ as a subspace of $\ell^2$ because reasons

@BalarkaSen Mochizuki successfully fills in gap in Corollary 3.12

Wtf

Why @Alessandro

@LeakyNun Ohoho I see what you have there

Not going there

:c

The way to go about it is to put every vertex on a different element of the standard orthogonal basis and then start going "if I have an edge between two vertices, then I take convex combinations of the corresponding basis vectors. If I have a face between 3 edges then I take convex combinations of the 3 vertices etc.", right?

@BalarkaSen Because I want $|K|$ to come with an easy to work with metric I think

I'm deciphering a proof of Gromov, so this $\ell^2$ business is clearly the best way to do things

@AlessandroCodenotti Yeah this sounds right to me

Wait, are you sure that the faces won't self-intersect in that way

yes

Yeah I see it now.

OK

Because the interior points of different faces have at least a different nonzero coordinate

Right.

Cool

This is just the usual embedding of a finite simplicial complex inside the full simplex of equal number of vertices inside $\Bbb R^{|V|}$

And taking a direct limit thereof

Right, but I really care about having the $\ell^2$ metric here

Got it.

The result by Gromov is that $X$ has asymptotic dimension $\leq n$ iff for all $\varepsilon>0$ there is a uniformly cobounded $\varepsilon$-Lipschitz map into a simplicial complex, the idea is that you start with a nice cover of the space given by asymptotic dimension $\leq n$ and then you map $X$ to the nerve of the cover by sending points in a single set of the cover to a vertex, things in two of them to the corresponding edge etc.

Ah

But having picked this metric on $|K|$ makes it easier to check Lipschitzness and coboundedness

Of course that makes sense

It's obviously $\varepsilon$-Lipschitz in the standard simplicial metric (since you're collapsing small open sets in the cover to points), but I see it's an issue to write that down lol

Good idea to work in $\ell^2$

yo, is $\Bbb R^{3,1}$ a symmetric space. Why or why not?

What's the standard simplicial metric exactly?

Every face is isometric to the standard $n$-simplex

Ah ok

Just like the graph metric but higher dim

Right

What a very Gromov idea

He was the one to come up with all of this stuff

Any suggestions on an introductory text for cobordism stuff ?

lmao someone clicked my link and joined

@BalarkaSen

and made no moves

oh that was me I thought that mochi had actually done it

notme

Lol @geocalc

trollz

@BalarkaSen how about correspondence?

OK

I've invited you

@Knight please is there a relation with the function cos ?

@LeakyNun accepted

@AlessandroCodenotti yup

Hello all!!

We know what $x\notin A$ express. I am wondering if this proposition: $\neg(x\in A)$ can be proven or is a definition which is an equivalence from the first one, or perhaps is a property called "Negation equivalence". What do you think? Thanks!!

@manooooh The first is just a shorthand for the second

@topologicalorientablesurface good. That is known as the lebesgue number lemma by the way

@TobiasKildetoft thanks for the quick answer!! Okay, so "shorthand" means "equivalence", right?

No, equivalence is a formal concept

So what is the meaning of "shorhand"

shorthand means we invent a new piece of notation for convenience

Oh, that's nice

And $\neg(x\in A)$ is a property or definition?

That way, we get to form readable statements that don't end up being several pages long

It is a statement

which can be true or false

So it is not a proposition, unless we know which $x$ is and which $A$ is, right?

right

$x\not\in A$ is defined to mean the same thing as $\lnot(x\in A)$

@Thorgott thanks! A student asked "How do I prove that the complement of the negation (of a set) is the same as the negation of the proposition?", so I ran into your help

Oh I'm going to ask a silly question. So for example if we have to show that $A\subseteq A\cup B$, we all know that we start from for all $x$, $x\in A$. Then $x\in A\lor x\in B$, hence $x\in A\cup B$. This "$x\in\text{some set}$", all of them are NOT consider a proposition?

@BalarkaSen @AlessandroCodenotti world champion defeated

Guys question: suppose we have to prove $C\subseteq A\cup B\to(C\setminus B)\subseteq A$. Is the same as?: $$C\subseteq A\cup B\to\forall x((C\setminus B)\subseteq A)\tag{1}$$ or?: $$\forall x(C\subseteq A\cup B\to(C\setminus B)\subseteq A)\tag{2}$$

damn @Leaky

@BalarkaSen hype

What is negation of a set, @manooooh?

And how are you writing a $\forall x$ sentence in which $x$ never appears again?

@TedShifrin $\overline{A}=A'=\mathcal{U}\setminus A=\{x\mid x\in\mathcal{U}\land x\notin A\}=\{x\notin A\}$

And you don't start with "for all $x$, $x\in A$" unless $A$ is your universe.

So negation = complement. But you said complement of the negation?

G'day, a @Balarka, @Leaky

Hi @Ted!

Suppose a polyhedron's dihedral angles are all right angles. Must the faces be parallel to some coordinate axes?

@Akiva Uh, what about like a cube but a diamond

I mean some coordinate axes, like you can rotate them

Oh upto rotation OK

Yeah

Cool q

what dimension?

3D

(I know the answer FWIW)

whats the answer

I think you could use duals for this

No @BalarkaSen

fun

how

Physics lovers try this one

nobody is a physics lover here

@akiva can't you just unpack the polyhedron using the net

hmm

okay, so take the net of the cube. then all faces are parallel to the euclidean planes y-axis. all angles are right angles as well

Might have more luck over at the physics SE chat (the h bar)

this is the only euler platonic polyhedron with all dihedral angles being right angles and therefore. Now gotta extend this to non-regular case

okay I think the answer is yes akiva

wait no it's gotta be no

because if you embed the cube into $\Bbb R^2$ via the net and look at the preservation of the dihedral angles. This is the only polyhedron that preserves the angles after embedding into $\Bbb R^2$

the dodecahedron net does not work

@geocalc33 I don't understand what you're doing

The dihedral angles are the angles between the faces. How can you see them from the net?

DogAteMy, how is the semester going?

Wow

I just discovered $\varpi$

Who in the heckery would ever use that

(the code is \varpi)

Spivak uses it all over his grad diff geo text.

That being the Comprehensive Introduction?

@BalarkaSen Hikaru Nakamura analyzes Anish Giri's win against Magnus Carlsen

Yup. At least I remembered it from there.

I see @Ted. Strange

He uses it (sometimes?) for principal bundle projections.

Urk

He even did it in chalk on the blackboard, as I recall from the dim recesses of my memory.

Did you ever get a response to your answer on that locally flat thing?

Yeah the person accepted the answer after a brief annoyance about a topology issue

I am editing the answer to provide the geometry anyway

Don't want to be a dishonest Thurstonite

Cool :)

say you have a compact 2-manifold that evolves, and satisfies a differential equation.

for example bessel functions on a disk satisfying the bessel differential equation.

once you solve your diff eq. then it's great. but what if at the boundary of the disk, the diff eq is undefined because the oscillations just blow up so to speak

Use a mollifier?

(I remember there being some PDE arguments that used mollifier functions to smooth things out on boundaries)

why is $\varpi$ coded as varpi ?

How is it a $\pi$ ?

The top part is the same

$\tau$ That's weird I'd expect it to be a \vartau if anything

does compactness in general topological spaces always imply sequential compactness?

No

@BalarkaSen this is unreal, Hikaru now has 7500 viewers live on Twitch due to both the pandemic and the xQc effect

and the fact that it's Sunday night

@BalarkaSen oh, but its true for second countable hausdorff spaces right?

@topologicalorientablesurface second countable compact Hausdorff spaces are metrizable and in metrizable spaces compactness and sequential compactness are equivalent

@BalarkaSen oh alright, I didn't know they were metrizable

Urysohn metrizability states that second countable regular spaces are metrizable. Compact Hausdorff spaces are regular

Normal, even

I didn't know about uryshon. Thanks! @BalarkaSen

Let $X$ be a topological space. $A\subseteq X$ is connected if and only if for any disjoint, open sets $U,V\subseteq X$, we have $A\subseteq U\cup V$ implies $A\subseteq U$ or $A\subseteq V$.

Is this true?

What do you think?

I think yeah, but i'm unable to show forward direction

Well, what does it mean for $A$ to be connected?

@Thorgott can be expressed as the disjoint union of two, non empty open sets

which implies $U\cap A=\varnothing$ or $V\cap A$ = $\varnothing$

If $A\subseteq U\cup V$ then $A=(U\cup V)\cap A$ = $(U\cap A) \cup (V\cap A)$

can't*

then $A\subseteq V$ or $A\subseteq U$

okay got it

nice

yup, I mean't can't. oops

alright, for the backwards direction, I suppose for a contradiction, $A$ is disconnected, so $A=U_A\cup V_A$ where $U_A\cap V_A=\varnothing$ and $U_A=U\cap A$ and $V_A=V\cap A$ for some open sets $U,V$ in $X$

So, $A\subseteq U\cup V$

yo sanity check, if you have a solution to a d.e. of the form $f(x)=g(x)h(x)j(x)$ what tools can you use to build back up to the d.e.?

I am sick of this Riemannian shit

I am estimating all day

finally! Let's do some honest ggt

Everything is a 4th order Taylor series

I dunno GGT man it's scary

But it's beautiful

True

I mean the results in Riemannian geometry are awesome. But trying to read a proof of one and my eyes are rolling off the sockets sideways and dangling off my face

lol

I don't know any Riemannian geometry

And I'm fine with that

Let $X$ be a topological space. $A\subseteq X$ is connected if and only if for any disjoint, open sets $U,V\subseteq X$, we have $A\subseteq U\cup V$ implies $A\subseteq U$ or $A\subseteq V$.

hints for backwards direction?

I suppose $A$ is disconnected. So, $A$ can be expressed as the disjoint union, of two non-empty open sets, $U_A,V_A$ i.e. $A=U_A\cup V_A$ In particular, $U_A=U\cap A$ and $V_A=V\cap A$ where $U, V$ are open in $X$. So $A\subseteq U\cup V$.

I think you want to assume that $A$ can be expressed as such a disjoint union (and ultimately derive a contradiction)

You have $A\subseteq U\cup V$, now apply the hypothesis

@Thorgott I can't apply the hypothesis

$U$ and $V$ may not be disjoint

right?

That was the idea

I can't push through 2 pages of calculations

I suck

Going to watch Twin Peaks instead and try to work it out on my own afterwards. This is horrible

ohh, I see the issue now

a little bit of googling reveals the implication is apparently false

I'm not good at coming up with good questions for this site so I'll throw my newest question out here: is there such a thing as an inverse cofinality function? What I mean is that if $cf(\aleph_\omega)$ goes to $\aleph_0$, is there a function from $\aleph_0$ to the next cardinal that is cofinal with $\aleph_0$, and so on? So we would have $icf(\aleph_0) = \aleph_\omega$ and then the next number in the sequence would be a number that is cofinal with $\aleph_\omega$.

@SergeyDylda It seems false to me, but I could be being stooopid.

@Thorgott what would be a counter example?

because on main, im told its right

For example, there is a global nowhere-vanishing $2$-form on $S^2$, but it cannot be written as the wedge product of two global $1$-forms. Ah, but it can be written as the sum of such, using partitions of unity. So this makes me think what you said should work in the smooth category but not in the analytic/holomorphic category.

Notice that nLab does this only in the smooth category. What they say is the definition of the deRham complex is not the way I've ever seen it. And in the holomorphic category, you should be able to write down a counterexample easily.

@topologicalorientablesurface math.stackexchange.com/questions/271441/connected-subspaces

Quick question, in the assertion "A module $M$ over a commutative ring with $1$ is flat iff every relation on $M$ is trivial", what is the definition of a "trivial relation"?

I came up with this when reading Lemma 10.38.11, Stacks Project.

@TedShifrin Oh, okay. That makes more sense, it seems kind of confusing what's written on nLab, I'll try to research this more.

Yeah, it takes partitions of unity to make local things global so that their definition works. I don't like it.

Do you want me to post a counterexample in the holomorphic/algebraic category? I can work one out.

In fact, I guess I know a simple example.

Would appreciate if you could, you can post it as an answer to my question and I'll mark it answered.

OK, will do shortly.

Ted, I have a potentially non-question. I forget how the topological degree proof of the fundamental theorem of algebra goes, but something along the lines of letting $p(z) = \sum_{i=0}^n. a_i z^i$; lifting $p$ to. $\hat{p}$ by letting $\hat(p)(\infty) = \infty$, we get a continuous mapping. $\hat{p}: S^2 \rightarrow S^2$. Finally, $\hat{p}(z)$ is homotopic to $\hat{z}^n$, the latter being $n$ to $1$, thus the prior having the same degree, thus hitting $0$ in the codomain $n$ times.

But IIRC, there was a $S^2 \setminus \{0\}$ somewhere?

You're confusing two proofs.

The degree proof on $S^2$ is one. The other is the winding number proof mapping to $\Bbb C-\{0\}$, where you homotop to $z^n$ on a large circle.

I need to homotop in the degree proof too, no?

But I don't think you need to miss anything there. You're not arguing that a winding number is conserved.