@Ottavio The Weyl tensor becomes $R - s/(2n(n-1)) (g \mathsf{KN} g)$ on an Einstein manifold, because the middle term vanishes. Vanishing of this object is a necessary and sufficient condition for the manifold to be conformally flat.

You can thus prove $\Bbb{CP}^2$ is an Einstein manifold which is not conformally flat very easily from here.

Because $R$ being proportional to $g \mathsf{KN} g$ would mean it has constant sectional curvature, which is only true in the complex directions on $\Bbb{CP}^2$. The sectional curvature swings between $1$ and $4$ if you vary over all planes (NOT strictly quarter-pinched, that forces your manifold to be a sphere by a famous theorem)

I am going to $\mathsf{KN}$ from now because $\bigcirc \!\!\!\! \wedge$ is a pain in the ass

I don't like KN how about like

lame MSE doesn't have any good approximations either

what are you doing man

i want a better symbol

$㋬㋩㋫㋑⧁⧀ⓥⓋ⎉㉠㉦$

i thought a lot about it but couldnt find it

$\huge{㉦}$

Nah

$g \mathbin㉦ g$

Just need to rotate $\huge{Ⓥ}$

Oh wow it's as bad as $\huge{\bigcirc \!\!\!\!\!\!\!\!\!\vee}$

i tried rotating with a style in chat, doesnt work

Hey

This will be pretty if it rotates

which, the $\vee$?

hmm what is it lol if not vee

$$\require{HTML} \style{display: inline-block; transform: rotate(180deg)}{\large{\bigcirc \!\!\vee}}$$

lol i could just turn off mathjax to see it

WTf

LOL

It looks awful

$\require{HTML} \style{display: inline-block; transform: rotate(180deg)}{\large{\bigcirc \!\!\!\!\!\vee}}$

$\large{\bigcirc\hspace{-1.05em}\wedge}$ $$\large{\bigcirc\hspace{-1.05em}\wedge}$$

Yes look at that beauty

$$\require{HTML} \style{display: inline-block; transform: rotate(180deg)}{\large{\bigcirc \!\!\!\!\!\vee}}$$

Absolute beauty

$\newcommand{\KL}{\require{HTML} \style{display: inline-block; transform: rotate(180deg)}{\, \large{\bigcirc \!\!\!\!\!\vee}}}$

you should use yours for an noncommutative operator

$g \KL g$

Um

Why is the spacing bad

come on man i give up

cuz you started with some weirdly spaced thing to begin with

$\newcommand{\KL}{\require{HTML} \style{display: inline-block; transform: rotate(180deg)}{\large{\, \bigcirc \!\!\!\!\!\vee \,}}}$

$g \KL g$

lol

Terrible

no dont do that

use DeclareMathOperator

wait

no, you want binary operator

i suppose \newcommand{...}{\mathbin{blah}}?

Ah

$\newcommand{\calvinstester}{\mathbin{X}}$ $a\calvinstester b$

yup works

$\newcommand{\KL}{\mathbin{\require{HTML} \style{display: inline-block; transform: rotate(180deg)}{\large{\bigcirc \!\!\!\!\!\vee}}}}$

$g \KL g$

Yes, still sort of weird but can be dealt with

but your wedge is not centered on my screen and also why the heck are you rotating a vee

the wedge is perfect on my screen! it touches the perimeter of the circle

you want it to be asymmetrical?

the \wedge gives you a bad result

@CalvinKhor I want the legs of the wedge to touch the circle

Goddamnit

I thought \vee$\vee$ was literally a rotated \wedge$\wedge$

$\newcommand{\notKL}{\mathbin{\require{HTML} \style{display: inline-block; transform: rotate(0deg)}{\large{\bigcirc \!\!\!\!\!\wedge}}}}$

$g \notKL g$

That's fucked, see? It's totally not centered

And the legs don't simultaneously touch the circle

Mine is obviously better

LMAO

no I parse it as visually different

i thought you were trolling hahahahaha

ill show you a screenshot but im too lazy

thats k i trust lol

ill make do with yours

$$R = \frac{s}{2n(n-1)} g \KL g$$

$g \nparallel g$

that's my KN product

$\mathsf{K\!\!\!N}$

lmao

Thats my KN product

Is anyone able to provide me with a sanity check on some vector calculus. I have a gradient type derivative problem which goes as follows: I have an expression $$ \left( \left[\mathbf{A} \times \mathbf{B}\right] \cdot \mathbf{C} \right)^2 $$ and I want to calculate the derivative with respect to $\mathbf{A}$. I get $$ -2 \left( \left[\mathbf{A} \times \mathbf{B}\right] \cdot \mathbf{C} \right) \left( \mathbf{B}\times \mathbf{C}\right) $$.

I am not sure if the order of the second vector product is correct

@MikeMiller is an expert in vector calculus

he can help you for sure

lol

write it in coordinates

The second vector product is a number scaling a vector. It doesn't make sense to write $\vec{v}2$, you've written it in the right order

not an endorsement of your answer which I haven't thought about

dude you're onto something

what if

we think of the the vector space

as acting on the base field

@MikeMiller thanks for that. So if it was the same problem except without the square it would be $$ - \left( mathbf{B} \times \mathbf{C} \right) $$, is that correct?

I mean I don't really know what you mean by derivative with respect to $A$ here. I would say that your thing is a function $f(\bf A) = [\bf A \times \bf B] \cdot \bf C$. But the derivative of a function $f: \Bbb R^3 \to \Bbb R$ isn't a vector

is it possible to upload image in chat room ?

Instead it's a linear map

Something that you plug a vector into to get an output

@ronakjain Didn't you ask this earlier today and get an answer

please you tell me i have just completed 100+ reputations

@MikeMiller the representative from riesz rep?

Ah sorry. I have a scalar potential and I'm calculating the gradient (in the same sense that we would calculate the gradient with respect to Cartesian coordinates) of the potential with resect to $mathbf{A}$. I have a number of these type of expressions popping up and just making sure that I haven't lost my mind.

@CalvinKhor I just wanted that said

@ronakjain Nah I think you should look at the last time you asked this and check the answer you got then

fair

i could not find that . The answer is lost in chats.

all these answers, lost in chats... like tears in rain

Please tell me are you able to upload image in chat room. is there any upload image option in your chat option. I am not having such option instead i have completed the 100+ reputation criterion.

@Rumplestillskin OK, fair enough. Yeah the gradient w/r/t A is B x C.

If i get 100+ reputation in mathematics than will i be able to upload image in other sites also.

I would write this out carefully but I feel like we'd have a language barrier

@ronakjain Yes I am able to upload images in the chatroom

@MikeMiller What is requirement for that option.

Who's to say

@MikeMiller Thanks!

Love this panel

I'm skeptical of your minus sign though

Here's how I would explain it in my language

The derivative of F(A) = [A x B] * C at A is DF_A(D) = [D x B] * C; I want the vector v so that [D x B] * C = v * D. (By definition this is the gradient of F at A) This follows from the vector triple product identity [D x B] * C = [B x C] * D, so

Hey Mike Miller. Please tell me what will i have to do for upload image option.

@Rumplestillskin $A\times B\cdot C = \epsilon_{ijk} a_j b_k c_i$, so $$\partial_{a_l}(A\times B\cdot C) = \partial_{a_l}\epsilon_{ijk} a_j b_k c_i = \epsilon_{ijk}\delta_{lj} b_k c_i = \epsilon_{ilk} b_k c_i = \epsilon_{lki} b_k c_i = (B\times C)_l $$

Jesus christ Calvin

Get a room

lol

@ronakjain "Do you really want to hear? It gets complicated!"

Why ? You just tell me the requirement for the option.

why do it geometrically when it comes out so easily by direct computation

dIrEkt cOmpUtaTioN

also apologies for all subscripts...

So it sounds like the answer is no

I'll accept that

Please tell me i really require that option. I am new to stackexchange chat.

You must simply continue diligently, without ever truly knowing if you have the option

@CalvinKhor hence @Rumplestillskin you have an extra minus sign

@CalvinKhor @MikeMiller many thanks !

@Rumplestillskin yw!

Hallo goyuz today we're going to do a prank where I pretend to cheat on my gorlfriend. Seek that upload button and smash sobscroibe

Thanks

@BalarkaSen Can you present a (sufficiently nice, which you may determine; certainly includes metrizable) topological space with a computable countable amount of data in the following sense?

@CalvinKhor then just for sanity if we had the following problem $$ [(A \times B) \cdot C]^2$$ then the derivative with respect to $B$ ( all quantities assumed to be vectors ) would result in the following ( using index notation ) $ 2 (\epsilon_{ijk} A_j B_k C_i ) (\epsilon_{ijk} A_j \delta_{lk} C_i) = - 2 (\epsilon_{ijk} A_j B_k C_i ) \epsilon_{lji A_j C_i} $?

@MikeMiller In what sense?

I assume you were writing something

$3 + \omega_0 = \omega_0$

I think I nice way to think of ordinals when doing arithmetic is thinking of them as queues

$\omega_0$ is a queue of infinite length

$3+ \omega_0$ is the exact same shape, a queue of infinite length

$\omega_0 + 3$ on the other hand is different. It's a queue of infinite length, but then there's "somehow" a cut and an extra little line of $3$ behind the infinite length queue

Essentially, we can relabel the $3 + \omega_0$ case so that it looks identical to the $\omega_0$ case, whereas we can't do the same with the $\omega_0 + 3$ case

Ok... so it's not a commutative f...field.... In other words, it matters where the union is placed?

Yeah, ordinal arithmetic isn't commutative

The wikipedia article on ordinal arithmetic is actually very nice for understanding this in my opinion

Wow interesting, thank you

I actually read it but I have some mistrust for wikipedia in general

@BalarkaSen That message didn't send on my end so I gave up

Anyway the answer is probably no

@Rumplestillskin It might be too late, but I think your minus sign is wrong. After all, $(A\times B)\cdot C = (B\times C)\cdot A$.

Then the derivative with respect to $A$ is obviously $B\times C$. Perhaps @MikeM already did this.

yeah Mike and Calvin pointed that out later

I'm always late to the party.

I like being late to the party

Cut to the food

That's what I care about

Well, some parties if you're late you miss all the food.

The parties I have been to either consisted of haranguing people in the initial segment or a bunch of stoners and drunkards getting smashed. I always got the food.

Just in lieu of coming late

In lieu of?

Or in view of?

in view of, thanks

Count on me to be obnoxious.

I thought that was my job.

It's your secondary job. Your primary one is worst humor.

@Rumplestillskin that notation is kinda a mess now, you can't repeat an index more than twice. But $[A\times B\cdot C]^2 =[(-B\times A)\cdot C]^2 = [B\times A\cdot C]^2$ i.e. its symmetric in $A,B$ so you should get the same formula in the end. i.e. $\nabla_B [A\times B\cdot C]^2 = - 2 (A\times B\cdot C)A\times C = 2(B\times A \cdot C)A\times C$ (this last one is just exchanging $B\leftrightarrow A$ from the previous formula)

where the subscript in B denotes the variable that is being differentiated in.....sorry for choice of notation lol

@CalvinKhor Oooops, I knew that but was being a bit hasty! Perfect! Thanks for that!

@Rumplestillskin yw, sorry I was busy and left the room

@TedShifrin Of course! Excellent thank you also

@CalvinKhor No worries that was very helpful! All the best

:)

rehi @Ted, @Edward

yo @Balarka

sup

stacks.math.columbia.edu/tag/05JA

@EdwardEvans maths is a big lie

lol

Hi all! Is U(N) a subgroup of the compact version of the symplectic group, USp(N)?

USp(n) is all nxn matrices A with quaternionic entries such that $A^* A = I$ where $A^*$ is quaternionic conjugate transpose. Complex numbers are in particular quaternionic and complex conjugation of a complex number is it's quaternionic conjugate, so yeah

U(n) embeds in USp(n)

@BalarkaSen ok thanks!

Here's a fact I learnt a few days ago. USp(2)/USp(1) is an exotic 7-sphere

It's homeomorphic but not diffeomorphic to S^7. I didn't know exotic spheres could be homogeneous spaces

@EdwardEvans do you know anything about completion?

in a first countable space do sequences and nets capture the same information?

Sequences already capture closures in first-countable spaces and those capture the entire topology

what if we're in a group with a countable neighbourhood basis at 0?

and "information" includes the uniform structure?

Is anyone amount you a jee aspirant ?

Hey @feynhat

Hi. 'sup?

What are quaternionic analytic functions $f : \Bbb H \to \Bbb H$? Would we just want that $df$ commutes with $I, J, K$?

Polynomials with quaternionic coefficients are examples, yes?

Just because $df$ is obviously multiplication by a quaternion, so a quaternionic linear map

Why can't we just use the limit of the difference quotient?

Should be equivalent I think if there is any truth to the world

Because for complex analytic maps the difference quotient thing is the same as saying $df$ commutes with $J = (0, 1|-1, 0)$

(Cauchy-Riemann equations)

@BalarkaSen I think even "differentiable" for quaternions is not very well understood and people are trying to get analysis to work there. Or maybe I'm completely misremembering a talk from a few years ago

What's wrong with saying $df$ commutes with $I, J, K$ though

Really, just $I, J$ suffices because $IJ = -K$

Don't see an immediate problem

I doesn't even commute with J

Maybe that's a fair point. So even multiplication by $i$ is not analytic

rip non-commutative analysis

There should be some simple workable definition. What if I just demand $df$, as a matrix in $M_4(\Bbb R)$, to be in $\Bbb H$?

$df$ is a quaternionic linear map. That's all.

All quaternionic polynomials are then by definition analytic

sounds reasonable

OK question

that's analogous to the complex definition

Do these have an open mapping theorem

Hi can I ask a combinatorics question?

interesting question, but I dunno

I'd start by figuring out when $df$ is in $\mathbb{H}$

Yeah it's not clear at all

you should get some PDE

right

why are you even thinking about analytic quaternionic maps

differentiable*

no clue how close these terms are for those maps

The simplest conceptual proof of fundamental theorem of algebra is as follows: A polynomial $f : \Bbb C \to \Bbb C$ is a complex analytic map sending $\infty$ to $\infty$, so extends to a complex map $f : \Bbb{CP}^1 \to \Bbb{CP}^1$. By open mapping theorem it is open, domain is compact so the domain is closed and open hence surjective, so it must have a zero.

I know there's a version of FTA for quaternionic polynomials, and $\Bbb{HP}^1$ is a hypercomplex manifold

It has two obvious quaternionic charts

So there should be a conceptual analogue of this proof

I'd rather develop non-commutative Galois theory for division algebras

what's the FTA analogue for quaternions?

pdfs.semanticscholar.org/13bc/…

The usual topological proof of FTA pushes through essentially

I want an analytic proof

I see

guess you'll have to develop quaternionic analysis

but actually the matrix definition might be problematic

Need to figure out what PDE is $df \in \Bbb H$ man

does that definition actually avoid the "i not commuting with j" conundrum?

It does, right? $f(x) = i x$ is now differentiable, $df = I$

which is in $\Bbb H$

I guess next step is to check $ixj$ lol

what even is that

Come on it has to be linear or something

Just evaluate on $x = a + bi + cj + dk$

Clearly

hmm, so being quaternionic-linear is actually not the same as commuting with the basis vectors

yeah

but shouldn't that be what linearity means

seems not

nah, it has to be what linearity means

what breaks down is that the matrix being in H is not the same thing as being quaternionic-linear

both of these options sound wrong

am I tripping

yeah it's funky what $\Bbb H$ as a module over itself means. Left module? Right module? What the fuck?

$\Bbb H$ is a $(\Bbb H, \Bbb H)$-bimodule

I mean, so, a quaternionic structure on a vector space $V$ should definitely be three automorphisms $I, J, K$ of $V$ such that $I^2 = J^2 = K^2 = IJK = -1$

Three complex structures compatible in this sense

That automatically makes $V$ a $(\Bbb H, \Bbb H)$-bimodule

Let $f\colon\mathbb{H}\rightarrow\mathbb{H}$. If we consider $\mathbb{H}\cong\mathbb{R}^4$ (not canonical, but we fix the most reasonable choice), then we think of f as a map $f\colon\mathbb{R}^4\rightarrow\mathbb{R}^4$, which possesses a Jacobian $df\in M_4(\mathbb{R})$. If $df\in\mathbb{H}$, we get a map $df\colon\mathbb{H}\rightarrow\mathbb{H}$ via left multiplication. This ought to be the derivative of $f$.

Yeah just fix one side, work left-modules.

But $df$ is not $\mathbb{H}$-linear in general

What is $\Bbb H$-linear mean

You mean $(\Bbb H, \Bbb H)$-linear?

no matter which side

You have to compromise one sidedness I think that's the only issue

@Thorgott No I mean what is the definition of $\Bbb H$-linearity according to you

$df(x+y)=df(x)+df(y)$ and $df(xy)=xdf(y)$ for $x,y\in\mathbb{H}$, but that doesn't work anymore

Forget the derivative

A map $T : V \to W$ of left $\Bbb H$-modules is left $\Bbb H$-linear if $T(qv) = q T(v)$?

Then yeah take $V = W = \Bbb H$, $T(v) = \alpha v$ multiplication by a quaternion is not $\Bbb H$-linear

yeah, what else should it mean?

the issue is that $\operatorname{End}_R(R)=Z(R)$, I guess

yeah the issue is algebra is useless here

that's why non-commutative things suck

It is OK to say $df \in \Bbb H$ though. I do wonder what is the restriction it poses

it's still multiplication with a scalar, so it's not a nonsensical generalization

yeah

it's just that multiplication with a scalar and endomorphism as module over itself are the same notion in the commutative case

but the latter would be a stupid requirement here, cause it would mean to ask the Jacobian to sit inside the reals inside the quaternions

correct

i agree

ok, so we agree this is a good definition

What does a typical quaternion look like as a 4x4 matrix man

now write down the PDE

$\begin{pmatrix}z&w\\-\overline{w}&\overline{z}\end{pmatrix}$

now represent each $z,w$ as $2\times2$ matrix

Ah ok and then put $z = (a, b|-b, a)$

This is gonna b a dope PDE

lmao

PDE with 16 equations

you can probably cut some down via symmetry

then check whether it's elliptic

Must be elliptic

ijpam.eu/contents/2014-90-4/2/2.pdf

The decoupled equation is just that each component is harmonic

Elliptic too electric boogaloo

So everything goes through

so quaternionic-differentiable implies quaternionic-smooth already

does it also imply quaternionic-analytic

I mean as a function $f : \Bbb R^4 \to \Bbb R^4$ it's analytic

That forces open mapping right

but why is it analytic?

I mean $\Delta f_i = 0$, $1 \leq i \leq 4$ is an elliptic PDE

do we have a Cauchy formula for quaternionic maps

if $f$ solves that we're analytic

I thought elliptic regularity only implies smooth and not yet analytic?

I always thought analyticity goes through

I mean components are harmonic so analytic

yeah, I guess you can reduce it to the complex case regardless

but then we should also be able to get a Cauchy formula for quaternionic maps, right?

Quaternionic Taylor series should be harder I guess

hmm, actually

yeah because you're dividing by $1/(z - a)$ quaternion

thats annoying af

for quaternionic polynomials, we should use a noncommuting variable

or at least, it makes a difference whether we do or don't

Yeah but doesn't for example $f(x) = ixj$ also have $df \in \Bbb H$

you mean like $ixjx$ could be annoying?

Don't see why

so quaternionic-analytic is a weaker notion than analytic as map R^4->R^4

but we already got the latter by being quaternionic-differentiable

Ah i see ur point

something's afoot

the game?

$ixjx$ is a polynomial in the broader sense, what does it's Taylor series in the narrower sense look like?

surely something isn't right when quaternionic-analytic is suddenly a weaker notion than quaternionic-differentiable

Yeah because R^4 -> R^4 projection to R^3 is quaternionic analytic by our defn?

That doesn't sound right

No I mean

that satisfies coordinatewise Laplacian = 0

but not our initial $df \in \Bbb H$ thing ofc

we need more than coordinatwise analytic for open mapping theorem for sure

I mean $f : \Bbb R^2 \to \Bbb R^2$, $f(x, y) = (xy, y)$ is coordinatewise harmonic but not an open map

how is the projection q-analytic

It's not, it has coordinatwise Laplacian = 0 is what I meant

we need to work much more for open mapping theorem

very annoying

I give up man this is too annoying

but the Laplacian thing works for C, why doesnt it work for H

The real and imaginary parts of a complex map are not just harmonic they are related, one is the harmonic conjugate of the other

You need something like this here

and this isn't the case here anymore?

I dunno

it should be

I mean, you still have the C-R equations

How do you prove open mapping theorem map? $f(z) = z^n g(z)$ where $g$ is nonzero, that's the crucial thing, right?

and $z^n$ is an open map, that's what one needs

We need a quaternionic Taylor theorem like you were saying

This is bullshit man

yeah, so a) figure out Cauchy integral formula for quaternionic maps (hopefully exists), b) figure out whether 1/(z-a) is quaternionic-analytic (hopefully; I assume you actually need to use noncommuting variables for this), c) do the usual trick

I $\Bbb H$ate it man

is there a quaternionic geometric series

What is the quaternionic $1$-form $f(q) dq$?

$(f_1 + i f_2 + j f_3 + k f_4)(dx + i dy + j dz + k dw)$

What the actual fuck

Maybe that's closed

pdfs.semanticscholar.org/e2f6/…

this looks interesting

our definition was wrong it seems

huh