Hello there

Hello @JonasTeuwen

is anybody there ?

Apparently not.

yeah, what's up ?

Um. Nothing.

you're a computer scientist , right ?

So I consistently claim, at least.

:D i claim to be an absolute beginner on my profile

are you into numerical analysis or approximation ?

Not really. Programming language theory mostly. I understand floating-point stuff well enough to compile arithmetic expressions, but that is all.

i have a computer engineering degree and trying to switch to mathematics

Can anyone here answer a Galois Theory question?

Possibly

But why not just ask it in the main forum?

Well, my question is actually regarding an answer that was given here.

Ok

What about it

It seems that arturo assumes 1st that $f$ can be factored into $m$ distinct irreducibles, which is what I thought he was trying to show. And also that the roots $\alpha$ and $\beta$ that he chooses are roots of distinct $q_{i}$'s

The second problem I guess is just a technicality that can be dealt with, but how does he assume that $f$ can be factored into the desired $m$ distinct polynomials?

Well, it looks to me like he factored f into the m irreducibles and then SHOWED that m was the desired value he wants

Because a polynomial ring over a field is a UFD

What do you mean?

@DylanMoreland I slightly recall this--do you know anything about category theory?

@AlexYoucis Yes. You are right about that. Sigh. For some reason, that didn't click for me.

@DavidK Make sense now?

@AlexYoucis Yes. I feel a bit dense now. I don't know why I understood it when you typed it, but not when he did. (shakes head)

haha, yeah man, it could just be one of those days

hello there

hey

what's up ?

Nothing much man, how about yourself?

nothing much here neither

what are you interested in ?

what do you mean?

i mean in math

I don't know man

lots of stuff

algebraic number theory, algebraic geometry, homological algebra, category theory

you seem to be and algebra guy

an algebra guy **

right

haha

have you done any numerical analysis or approximation stuff ?

@AlexYoucis It depends on what you mean. It's a language I know how to use because it comes up.

hi @Dylan

But on its own I find it kinda boring. What I'm trying to understand these days is all sort of built on Tannakian formalism ("the category of representations recovers the group"), for example, but I can't bring myself to actually read anything on it.

Hi Akram.

what's up @DylanMoreland

I am grading. Then I'm going to do more algebraic geometry exercises to get ready for my oral exam.

Nothing exciting.

cool

Not at all.

the only i chance i have to study math is to do those stuff

Do you like it?

numerical no , it doesn't seem math for me :( , and i don't know much about approximation so i'm still wondering

because it's engineering school not pure math school

i am looking for an area that's common between their interests and mine , you know

Why not ask someone there?

it sounds like a community wiki , doesn't it ?

I meant at this school to which you're referring.

Here, I don't know what would happen.

yeah , i am trying there too

so , what are you interested in ?

It's not clear to me what approximation as a sub-discipline is. It could very well mean different things to different people.

So it seems to me that asking the people you'd actually work with is the only way to be sure.

People are generally really excited to talk about their own stuff.

Number theory.

Algebraic number theory, I guess.

yeah

number theory is huge

That's part of the appeal.

yeah ?

But everything is probably huge in some sense.

yes

in mathematics people could be interested in a single problem or even a single part of the problem

But I think we get to use a lot of tools. Fun tools. And I think that numbers are good motivation.

I like manifolds, for example, but proving something about a manifold doesn't sound so exciting to me on its own. If that manifold tells me something about a Galois group, then that's different.

yeah

i do understand what you mean

I don't know why that's enough, to be honest.

It's equally useless to the world.

do you think so ?

i have been thinking about it as well

you still there @DylanMoreland ?

Looking at papers, sorry.

Alright

good talking to you

I don't go around thinking that what I do is useless. But it's hard to justify an alternative view

bye

seems kinda self-serving

well

i think application is the thinnest slice of knowledge

It was mostly a joke.

maybe that's how the world is build

I try to just avoid the topic.

okay :)

Oh, I'm not saying stop talking about it.

so why do you wanna avoid it ?

I don't know if it's a profitable use of time.

is your study profitable then ?

I mean in the sense that it doesn't help you. It's like sitting around thinking about, I don't know, death.

emmm

does math depress you that much?

lol

Couldn't think of anything else that fit the "large unsolvable issue" bill.

Actually, there are a lot of those.

what are you interested in @anon ?

Please say approximation. That would help us a lot.

yeah :D

nope, I find approximating stuff, in general, boring. I like number theory. but to really go far in it you need to know complex analysis, general topology, commutative algebra and representation theory, blah blah blah.

and I'm still working on all that

how about Numerical stuff @anon ?

not much difference to me

but doesn't approximation theory seem pure math from some prospectives ?

not my kind of pure math

It's definitely serious math.

Ah, approximation. I love it.

I'm no good at it yet though.

yeah ?

I come here mainly to find new problems for asymptotic analysis, estimation, that kind of thng.

i need your help then

I can certainly take a look.

@MarianoSuárezAlvarez Ah! You are someone who may be able to help me! Do you mind if I ask a quick (not forum worthy) category theory question?

shoot

So, just in case this isn't standard terminology to you, call a category C "balanced" if every bimorphism (epi and mono) is an isomorphism.

Is there a way to prove that an abelian category is balanced without appealing to the embedding theorem?

I assume not.

there surely is

Oh! Do tell

I'd have to think a bit, but I am sure you can prove it without embedding

Ok, well if you think of something, I'd love to hear it!

Thanks for the input!

have you checked the usual sources, like MacLane's book on categories?

Sure. And Mitchell's Theory of Categories, as well as several other sources

Presumably if you don't have to use the embedding theorem it probably works for preadditive categories

since I don't see, off hand, how the existence of kernels/cokernels or products/coproducts

would be helpful

Well, maybe kernels and cokernels

filtered groups are a preadditive cat. yet there are monic epis which are not isos there

Hmm

What about preabelian then?

what is preabelian?

If no broader class of categories is balanced then I feel like we need embedding theorem

has products/coproducts and kernels and cokernels

the embedding theorem can't be needed

Why do you say that?

Morally?

the embedding theorem is an afterthought of the theory

almost nothing depends on it

Right--except that it makes everything easier haha

suppose $f:a\to b$ is monic and epic

then $0\to 0\to a\to b\to 0$ is a short exact sequence

apply the functor $\hom(-,a)$ to it

we get a short exact sequence $0\to\hom(b,a)\to\hom(a,a)\to\hom(0,a)$ so that $\hom(b,a)\to\hom(a,a)$ is an epi of abelian groups

in particular, there is a $g:b\to a$ such that $gf=1_a$

composing on the left with $f$ this gives $fgf=f=1_bf$, so, since $f$ is epic, $fg=1_b$.

Yay!

Thanks man! That's great!

this can be proved eons before the embedding theorem :D

True, true

I apologize

I didn't think hard enough before I asked

Thou Shalt Not Take Freyd's Theorem In Vain

lol

Although, it's fun to bash stuff on the head with when you're like

"eh....probably true"

Hey Mariano

Just wanted to say that I'm a big fan.

heh

@MarianoSuárezAlvarez I was thinking about the title you showed me "a Theorem is simply a very organized family of examples," and have a question about its relationship to proof?

to poof? :)

I liked poof :D

sorry about the typo proof*

I know, I am just kidding :P

poof there goes my question :-)

haha

praxeology.net/you-want-proof.PNG would make more sense with poof

what was the question?

Could the proof of a theorem then be considered as a "convincing" of the reader of the validity of the truth of the "family of examples"?

sure

@robjohn Hi.

hello

In real mathematical practice (as opposed to what the people studying logic and proof theory study) a proof is an argument which will convince the reader

lots of times, papers do not contain complete arguments

:-)

that is why it is difficult to write good proofs

it requires taking into account who the reader is

@anon, why did you delete the answer!?

shhhhhhhh

heh

@anon it's okay, it is hard to search for deleted answers :-)

@robjohn, you have to s/theorem/proof/ in that, though

@MarianoSuárezAlvarez That is true.

The theorem is the conclusion to the proof

That is what I wanted to know, thank you.

The proof of a theorem then can be considered as a "convincing" of the reader of the validity of the truth of the "family of examples."

most theorems identify classes of objects which have some property

the hypotheses describe the class of objects

"a continuous function on an interval is Riemann integrable there"

sometimes, the "class of examples" of the theorem consists of exactly one object

or 5, like the platonic solids

in fact, lots of theorems arise in precisely that way: you are interested in some property of a class of objects, you find one example which has it, and you study in detail exactly why it has that property

@MarianoSuárezAlvarez A definition (or axiom) would then be considered as a statement that you can not ask why ? it has that property?

no

(generally) a definition just captures a set of features of a class of objects

an object can be a group or not

You lost me...

but interesting definitions capture a set of features of objects which are sufficiently rich that you can learn a lot from those objects knowing only that they satisfy the definition

the reason why we define the abstract notion of group

is not that we are interested in the abstract notion of group

but because we are interested in a lot of objects which happen to satisfy the definition of group

initially, people worked with groups without given them that name

the set of permutations of a set is sufficiently interestng that one can study it without abstracting it into "groups"

but then people noticed that a small set of properties of the set of permutations of a set were enough to prove a lots of other of its properties

you can always ask why, because definitions are motivated

Why is unique in that way in that it can be asked forever.

sadly, people have this idea of axioms as selfevident truths or something along those lines

which is an idea completely strange to a mathematician

the axioms of groups are not selfevident in any possible sense

they are possible properties of objects

and the definition of a group singles out those objects which satisfy its properties

but the very fact that we need definitions makes it explicit that the "axioms" are not self-evindent and much less "true"

Are not the real-number properties statements about numbers that are accepted as true? and that form the basis for computation in arithmetic and in algebra.

no

there are other systems of "numbers" which do not have the same properties as the real numbers

there are fields which are non-archemdian, or not orderable, or orderable but not complete

or of positive characteristic

the axioms for the real numbers, though, are special in that one can prove that there is a unique object which satisfies them

we say that those axioms are "categorical"

but one has to prove that

at some point, one has to construct a set, define operations in it (addition, multiplication), and check that it has the properties we want it to have

this was done by people like Dedekind, a long while ago

(usually, one sees the "construction of real numbers" when one studies real analysis)

Weierstrass is also in the group

@MarianoSuárezAlvarez When you say that those axioms are "categorical" do you mean that the axioms only apply to those objects in the category of your construction?

no

:(

a set of axioms is categorical if they are only satisfied by one object (up to isomorphisms)

there is exactly one «complete ordered field»

hmm..

Another example: it is a theorem of Steinitz that the conditions «algebraically closed field of characteristic $p$ and cardinal $\kappa$» (with $p$ a prime or zero and $\kappa$ an uncountable cardinal) is also categorical

this has the consequence that every time you have two algebraically closed fields of the same cardinal and the same characteristic, they are isomorphic

I appreciate your time and effort in explaining these concepts to me, thank you. You have given me a lot to think about.

a simpler example: there is only one «real vector of dimension 15» up to isomorphism

we are happy when we find a categorical set of properties for an object, because it means we really know it :)

anybody into numerical analysis ?

it is usually best to simply ask your question

lots of people hate numerical analysis but may be able to help you anyways...

i hate it too :)

so asking for people who are into NA is not the best plan!

@Akram : shoot...I am not into NA but would be glad if i could be of some help

Can you help me with Galois Theory?

it is usually best to simply ask your question

don't ask for help, ask your question

(moreover, untill one sees the actual question it is imposible to know if one can help or not!)

Here is the problem statement: "Exhibit an explicit isomorphism between the splitting fields of $x^{3}-x+1$ and $x^{3}-x-1$ over $\mathbb{F}_{3}$."

I can't seem to make any progress on this.

I've been trying to find a root of $x^{3}-x-1$ in $\mathbb{F}_{3}[x]/(x^{3}-x+1)$ but this doesn't seem to be the direction I want to go in...

I have no idea what I'm doing

well the root you are looking for (assuming the cubic is irreducible over $F_3$) is the coset $x + (x^3 - x + 1)$

DO you know the degree of the extensions?

You mean $[\mathbb{F}:\mathbb{F}_{3}]$ ?

yes

Isn't it 3?

the splitting fields of some cubic polinomials have degree 6

I do know that $x^{3}-x+1$ and $x^{3}-x-1$ are factors of $x^{27}-x$.

Hrmm.. Well they are also factors of $x^{9}-x$.

they are?

Modulo 3.

what's the quotient of x^9-x by x^3-x-1 ?

Just so we are clear $\mathbb{F}_{3}\cong\mathbb{Z}/3\mathbb{Z}$.

sure $F_3$ = {-1,0,1} where 1+1 = -1.

@MarianoSuárezAlvarez I mis-read my writing.

So, they are factors of $x^{27}-x$ NOT $x^{9}-x$

@DavidWheeler Yes. $1+1=-1$.

Ok :)

Then the degree is 3

well, to my way of thinking we have two finite fields of order 9.

Right. Yes I agree. @MarianoSuárezAlvarez

if a is a root of $x^3 - x + 1$, we can write down all the elements of this field: 0,1,-1,a,a+1,a-1,-a,-a+1,-a-1.

similarly, if b is a root of $x^3 - x - 1$ we have a similar list for the "other field"

a has to map to one of the 6 terms involving b, and we know it isn't b itself, since b doesn't satisfy the same cubic a does.

@DavidWheeler I see what you are saying I think.

you could just use brute force to find out which of b+1,b-1,-b,-b-1,-b+1 satisfies the cubic a does.

oh dear, excuse me, we have quadratics to account for, as well our field has 27 elements, duhh

@DavidWheeler Oh good.

I have been trying to figure out where 9 came from. fhew

@MarianoSuárezAlvarez We know that there are only 5 finite subgroups of $SO_3$ up to isomorphism?

there and infinitely many actually

the cyclic ones and the dihedral ones

and three more

(not five, because dual polyhedra give the same group)

@MarianoSuárezAlvarez I don't know where to find a proof that there is a finite subgroup of $SO_3$ that acts on a platonic solid

it is quite non-trivial :D

it is usually constructed as follows: consider all planes of symmetru of the solid

and consider the group generated by the reflections in that plane

@MarianoSuárezAlvarez Ok, I have never seen this before

this is contained in O(3)

now look at the intersection with SO(3)

of course you need to show that there are symmetry planes

@MarianoSuárezAlvarez I'll let you edit my answer and put it in there :D

and that there are enough so that this group acts transitively on vertices, and that the group is actually finite :D

Well at least I just didn't say by euler's formula, it follows...

haha

Well all the others just went, "by euler's formula...."

this is the beginning of the beautiful theory of reflection groups

@MarianoSuárezAlvarez It's been a while now that I've thought about groups

Coxeter, whom Will mentioned, is one of the champions of that subject

sooner or later gonna have to start thinking about it when the galois group of a field extension is defined in class

Yeah HSM Coxeter is famous

I am tired after all those exams

@MarianoSuárezAlvarez When I start doing those exercises on direct limits maybe I may need your help....

Look what I found on wiki

@DavidK i think $a \mapsto b^2 - b$ is the isomorphism you need.

Proof by rearrangement of four identical right triangles of a a very organized family of examples known as the Pythagorean theorem.

a large square, side a + b, containing four identical right triangles. The triangles are shown in two arrangements, the first of which leaves two squares a^2 and b^2 uncovered, the second of which leaves square c^2 uncovered. The area encompassed by the outer square never changes, and the area of the four triangles is the same at the beginning and the end, so the black square areas must be equal, therefore a^2 + b^2 = c^2.

@DavidWheeler This seems like it should be so easy, but I have no idea what is going on here. I'm basically trying to find a map that permutes the roots of $x^{3}-x+1$ and $x^{3}-x-1$ ?

ok, if we consider just the first polynomial, we get the splitting field by adjoining a (which is actually $x + (x^3 - x + 1)$) to $F_3$.

Ok

we get the 2nd field by adjoining b to $F_3$, where b is a root of $x^3 - x - 1$.

we want to show these two fields are isomorphic, right?

I'm sorry for being dense, but don't I want $$\mathbb{F}_{3}[x]/(x^{3}-x-1)\cong\mathbb{F}_{3}[x]/(x^{3}-x+1)$$ ?

So $a$ is a root of $x^{3}-x+1$ in $\mathbb{F}_{3}[x]/(x^{3}-x-1)$ right?

that's the same thing.

we can embed $F_3$ in the quotient ring, by mapping 1,0,or -1 to the cosets of constant polynomials.

@DavidWheeler Ok. Good.

any coset in the quotient ring has the form $c_1 + c_2x + c_3x^2 + (x^3 - x + 1)$ for $c_1,c_2,c_3$ in $F_3$, right?

Hmm. Ahh. Yes.

we just forget about our "old" $F_3$ and write the coset $x + (x^3 - x + 1)$ as a

@RajeshD Hi

Hi

@Rob How are you doin

@RajeshD Fine thanks, and you?

doing ok

@tb I don't understand why I can't define my function on a closed set. For example $e^x$ on $[0,1]$. I'm not sure $e^x$ is analytic and I don't know how to check but it "looks" analytic to me.

analiticity is only defined for functions defined on open sets

it means «the function has a development as a power series around each point» and for that to make sense, the domain of the function must contain an interval centered at each of its points

On the other hand, the function $f:t\in [0,1]\mapsto e^t\in\mathbb R$ is the restriction to $[0,1]$ of an analytic function defined on an open set containing $[0,1]$

(there is no such thing as «analytic from the left» like there is «differentiable from the left»...)

Hello guys!

@MattN what Mariano said.

(Thanks, by the way, Mariano)

np :)

I was wondering does anybody remember the name of the mathematician who derived the general rule for finding $\sum_{i=1}^{n}i^k$ for any k in \mabb{ N}

There was a discussion in M.SE about this. I am not able to find it now :(

Faulhaber.

Thanks @tb

@MarianoSuárezAlvarez Thank you!

@tb So the definition doesn't work. That was a stupid question. But even so: can you tell me why I can't talk about $supp(f) \subset O$ where $O$ is open and $f$ is defined on $O$ and $supp(f)$ is compact for $f$ analytic? If $f$ is defined on an open set but has compact support it does not break the definition, does it?

@MattN Suppose $f$ is analytic and non-zero on the connected open set $O$. Then the set of zeroes is a closed discrete subset of $O$. Thus the support of $f$ is all of $O$ and hence not an interesting notion.

You can talk about it but I don't understand why you would want to do so.

an analitic function never has compact support, unless it is empty

(if f is defined on an open set U, analytic there and with compact support, then it vanishes on an open subset of U, and therefore vanishes identically)

... and we're back to where we started ...

@tb I wanted to take help from you on this answer of mine.

Can I add anything more to that? (To me it looks, I can but I seem to not be able to figure out more about this.)

Hi @MattN

@MarianoSuárezAlvarez Thanks Mariano.

@KannappanSampath Hi Kannappan. How are you doing?

@tb It's ok. I give up.

@MattN Not bad. That's all for now.

Good.

@MattN Will you also look at the answer I linked to tb, please?

@MattN can you formulate what you're actually looking for?

@KannappanSampath looking

@KannappanSampath I can't help you there. I always fall immediately asleep when questions are asked seeking similarities for two manifestly unrelated concepts that happen to bear the same name! There are only finitely many words!

@tb Thank you. Jyrki's comment there is also not comprehensible to me. (about "minimal generating" set for a topology.)

@KannappanSampath Why more to come? Didn't your first sentence answer the question already? Up to you though : )

@tb Hmm, that's right, but we still could show some differences, no?

@MattN I wanted to point out some logical differences between the two. Some facts about topological basis won't make sense at all for basis in Linear algebra, I don't know how I would get that across!

@tb I want to see why an analytic function can't have compact support. And so far it feels like I was told that that's because it can't have compact support or to use the identity theorem. Yes, I can use the identity theorem but then I don't see why, I'm just stupidly referring to a theorem.

Then the remedy would be to understand the proof of that theorem. As I said, it is very easy.

And I outlined the argument yesterday

I'll read that proof. Thank you!

Well, I'll be doing good if I understood Jyrki's comment there and remove the line "More to come"

@tb Help with Jyrki, please.

@KannappanSampath One reason for the utility of bases in linear algebra comes down to the equivalence of two descriptions. Top down: minimal generating set; Bottom up: maximal independent set. There's no immediate analogue for topological bases.

(and, as I understand it, this is the thrust of Jyrki's comment)

Right, I get it. Should I add this to the answer as well?

As you wish. Topological bases are supposed to be small collections on which you have a good handle; they are enough to understand the open sets in a topology. There's no minimality requirement and no independence requirement (and independence would make little sense).

(BTW: By top-down, is it meant that one starts groping in the dark and makes this definition?)

@tb For me minimality makes little sense too... (Minimal with respect to what? Inclusion?)

@KannappanSampath for example, yes.

@tb OK. What others then?

@KannappanSampath No: the idea is that a generating set is "large": a basis is the smallest large set (you go down: the smaller a set, the smaller the chance it generates). Conversely, another intuition is that a linearly independent set is "small": the larger you make a set the larger the chance that it becomes linearly dependent: you go up. Bases mark the "middle" of those ideas.