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Akiva Weinberger
Akiva Weinberger
13:24
So I was thinking about the problem of,
say two people are dividing a yard, so they're putting up a wall
but they still want to be able to walk from one yard to the other, so they leave a whole in the wall
but they also want privacy, so they each want it such that you can't see into their yard from the other.
And there's a lot of ways to do this, but it was interesting thinking of the different shapes you can put
user image
Like this, which has a big pillar in the middle
(You can't see from the top half-plane into the bottom half-plane unless you're inside the structure in the middle, but you can still walk from one to the other)
Secret
Secret
user image
Akiva Weinberger
Akiva Weinberger
or this thing
user image
Eran
Eran
Let $X$ be a set, $\cal{E} \subset \mathbb{P} (X)$ and $\cal{M} = \sigma(\cal{E})$
Secret
Secret
I wonder what does the general solution to the yard problem look like...
What do all the possible fence configuration have in common geometrically?
Akiva Weinberger
Akiva Weinberger
user image
or this thing (which is kinda like the inverse of the first one)
(And you can also divide it in half if you're OK with the assymetry)
(which would look kinda like ーコー)
Ninja hatori
Ninja hatori
13:34
any application or motivation to study quadratic forms
Secret
Secret
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This might be the common feature in all these fences
a hole sanwiched between two walls
Akiva Weinberger
Akiva Weinberger
I kinda want to turn this into an optimization problem but I dunno what quantity I'd want to optimize
Secret
Secret
well... for -( O )-, that... might be the above hole component split into two halves
All of these configuration cab be made to equally divide the yard into congruent pieces, so that does not seemed to be an interesting to optimise
what about... the length of fence used, as that is a practical consideration
People will like to use as less resource as they can to achieve a task
Thus one possible optimisation parameter is the total length of fence used
subjected to the constraint listed in the problem
Akiva Weinberger
Akiva Weinberger
If you have really thick walls, you can get away with this:
user image
(If you're playing Minecraft or something, where everything's made out of 1m x 1m x 1m cubes)
Secret
Secret
that seemed to be the most optimised perimeter possible
any turns with only make things longer
Akiva Weinberger
Akiva Weinberger
13:42
With infinitesimally thin walls, you can still approximate the "thick wall" solution like this:
user image
but that seems kinda ugly to me, I dunno
Secret
Secret
Is it the most optimised? It seems longer to me
Akiva Weinberger
Akiva Weinberger
The most optimized one is probably the - ]-- one
(i.e. half of the "I"-shaped one I drew, which I realize is kinda hard to approximate with keyboard characters)
With infinitesimally thin walls, anyway.
I don't think this has any practical application
Like, nothing's wrong with just using doors, right?
Secret
Secret
lol yup
(and you can lock them if you want to)
But I suppose for certain garden designs, if you want to conceal something without using a door, then such geometry will be useful
There are also public toilets that are built using similar principles thus no doors needed. You see many of these throughout the world
Lozansky
Lozansky
Imagine a spherical shell of radius $R$, carrying a uniform surface charge $\sigma$, set spinning at $\mathbf{\omega} = \omega \hat{z}$. Now I'm interested in the magnetic dipole moment of the sphere and there are two ways that I see to approach this:

1) Write down the current density $\mathbf{K}(\mathbf{r})$ and compute $\mathbf{m} = \dfrac{1}{2} \int (\mathbf{r} \times \mathbf{K} )\text{ da}$. With $\mathbf{K} = \sigma \mathbf{v} = \sigma (\omega \times \mathbf{r}) = \sigma \omega R\hat{\phi}$ and $\mathbf{r} = R \hat{r}$ so $\mathbf{r} \times \mathbf{K} = \sigma \omega R^2 \hat{z}$ toge
First result is wrong, second is correct
Where does approach 1) fail?
Akiva Weinberger
Akiva Weinberger
No idea, I know nothing about electricity
but maybe there was a spherical integral somewhere and you forgot the $rdrd\theta$ or something?
Wait, that's not spherical coordinates, that's polar coordinates
Lozansky
Lozansky
13:52
Surface element of a spherical shell is $R^2 \sin \theta d\theta d\phi$
Akiva Weinberger
Akiva Weinberger
Arright
Can't help you then
@Secret Hey, the second one I drew actually has a redundant segment: the small vertical segment on the bottom left isn't needed.
If we delete that, we have something with only five units of fencing (not counting the main wall).
Is this the most efficient, if we're only allowed to build on one side?
Secret
Secret
Will this work?
user image
Akiva Weinberger
Akiva Weinberger
I guess we need to make some qualifications as to the smallest object required to pass through it
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@Secret Line of sight
Secret
Secret
ah...
In that case, that separation in the middle of the second is is necessary, since the same line of sight can be drawn
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Loong
Loong
That's something we need for radiation shielding design.
Akiva Weinberger
Akiva Weinberger
14:07
No, not that one
The vertical segment to the bottom-left of it @Secret
In any case, I think these are the most efficient, where you can use only one side or both sides respectively
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Sorry for the inconsistent scale; both arcs are meant to have radius 1 (the width of the hole)
On the top one, that's a 135 degree arc, combined with a short unit-length segment
Secret
Secret
sounds legit, I wonder if we can prove there is no more efficient ones.. but then geometry is not something that is easily turned into proofs, hmm...
Akiva Weinberger
Akiva Weinberger
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Did the first one in Desmos to look less rough
Line of sight just blocked
So that was some random stuff
ÍgjøgnumMeg
ÍgjøgnumMeg
user image
design it in such a way that the area inside the triangle is the same as the area outside and then cut off a corner
lol
Akiva Weinberger
Akiva Weinberger
14:23
Heh
ÍgjøgnumMeg
ÍgjøgnumMeg
or, alternatively
Akiva Weinberger
Akiva Weinberger
Yeah, if "no-man's land" is that $1\times1$ square in the bottom-left, then it works
ÍgjøgnumMeg
ÍgjøgnumMeg
hahaha
I mean
Akiva Weinberger
Akiva Weinberger
Dunno why you didn't just draw the diagonal of the rectangle and chop off a corner
But yeah if it's an enclosed space you can just push the hole to the side
ÍgjøgnumMeg
ÍgjøgnumMeg
I'm trying to minimise the amount of space wastage caused by some kind of "line of sight blocking mechanism"
Akiva Weinberger
Akiva Weinberger
14:26
Also, the area inside the triangle is always equal to the area outside
Half base times height
ÍgjøgnumMeg
ÍgjøgnumMeg
I mean, not if you just stick a random triangle in the middle of the yard
this is what I was getting at
cool question tho
Akiva Weinberger
Akiva Weinberger
14:48
imgur.com/a/E6e0GOz
Desmos-ified drawings
 
2 hours later…
Fargle
Fargle
16:33
@TedShifrin: apparently someone's developed a font based on Palatino that has a compatible mathmode font.
It doesn't look half bad.
Alucard
Alucard
can this be? a function takes arbitary large values, but not infinity.
Fargle
Fargle
@Alucard How do you mean taking "arbitrarily large values"? Certainly $f : \Bbb R \to \Bbb R$ by $f(x) = x$ takes arbitrarily large values, but is never infinite.
Semiclassical
Semiclassical
Not really. If it takes arbitrarily large value, then as such you can find a sequence of function values which grow without bound
(And "grows without bound" is about the only way you'd ever say a function takes on infinity as a value)
Corellian
Corellian
test: $\left(\begin{array}{cc} a & b \\ c & d \end{array}\right)$
$\left(\begin{array}{c} 0 \\ 1 \\ 2 \end{array}\right)$
Semiclassical
Semiclassical
an alternative to that is \begin{pmatrix} a & b \\ c & d\end{pmatrix}
Corellian
Corellian
16:42
oh special commands
thanks
Semiclassical
Semiclassical
the drawback is that it doesn't let you right/left justify your columns
Corellian
Corellian
in the 2 x 2 case the upper half of the curvy brackets (parentheses) are invisible. hmm
Semiclassical
Semiclassical
what?
\begin{pmatrix} a & b \\ c & d\end{pmatrix}
Leaky Nun
Leaky Nun

Sandbox

Where you can play with chat features (except flagging) and ch...
2
Semiclassical
Semiclassical
displays fine on my end
The main reason for array is when you want to do stuff like tables or piecewise functions
for doing matrices, pmatrix/bmatrix/vmatrix are sufficient
Corellian
Corellian
16:47
seems to be a problem in Firefox browser
Semiclassical
Semiclassical
weird
Corellian
Corellian
Not just chatjax, anywhere it's a latex render of brackets with certain dimensions. Oh well
Semiclassical
Semiclassical
I use chrome, so i wouldn't know
Alucard
Alucard
how does a echolonform of a hypermatrix look like? (where are the zeroes?)
Rithaniel
Rithaniel
So, question worded as follows: Let $(X,\tau)$ be a regular topological space and $F$ a closed subset of $X$. If we define an equivalence relation $R$ on $X$ via the partition $\{x|x\in F\}\bigcup (\bigcup_{y\notin F}\{y\})$ Show that $X/F := X/R$ is Hausdorff.
I think I'm missing something, because I don't know if this should necessarily be Hausdorff.
Michael.P
Michael.P
17:08
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user image
The problem and the solution. Can anyone rephrase the solution, because I really don't get it
mercio
mercio
which part do you not get ?
Michael.P
Michael.P
Specifically, in the third step, are we replacing in the expanded (1+x)^{n+m} for n+m over l ?
Semiclassical
Semiclassical
the point is that you're looking for which terms in the left-hand side are of order L (writing it like that to disambiguate from 1)
and the only way to get terms of order L is when k+j=L
mercio
mercio
and also they are not explicitly finishing the proof by pointing out that the coefficient of x^l on the right is binom(n+m,l), and that the coefficient of x^l on the left is equal to the coefficient of x^l on the right
Michael.P
Michael.P
And we see that by looking at the power of x^k * x^j ?
Semiclassical
Semiclassical
17:16
yes.
Martin Hopf
Martin Hopf
Find the next one in the sequence: 11, 23, 47, 2351, 4703,...?
Michael.P
Michael.P
The problem is that these powers will overlap several times
0 1 2 3 4 5 ... n+0
1 2 3 4 5 ... n+1
...
m m+1 m+2 ... n+m
mercio
mercio
when you expand the product you get sum for k=0 to n of sum for j=0 to m of binomial(n,k) * binomial(m,j) * x^k * x^j
and x^k * x^j is x^(k+j)
and so when you look at the coefficient of x^l you only look at the terms of the sum where k+j is l
Semiclassical
Semiclassical
@MartinHopf note that the terms are increasing rapidly, probably too fast for a polynomial function to be what the asker had in mind
But do you notice anything about how each term relates to the next, in terms of their overall size?
Martin Hopf
Martin Hopf
2*11+1=23
2*23+1=47
Semiclassical
Semiclassical
17:21
yeah, but then 47*2+1=95
but what I was going to suggest doesn't help much either. The change from the third to the fourth term is so big
Michael.P
Michael.P
@mercio umh, okay. There will be a special case when the equation we're proving will make sense, what about all of the 'superfluous' values of k+j that don't fit into l
Martin Hopf
Martin Hopf
50*47+1=2351
Ninja hatori
Ninja hatori
0
Q: about exact sequenceof witt group of rational

Ninja hatori I want to understand this lemma. $|l|<p $ is clear. But why < $pn_1n_2m$ > - < $prm$ > $=$ < $pn_1n_2m$ > -<$lm$> -<$prm$> mod $L_{p-1}$ is unclear 2nd step all other steps after and before that are clear.

linear-algebra abstract-algebra commutative-algebra bilinear-form
Semiclassical
Semiclassical
@Michael.P Those won't fit into a particular value of l. But you're not considering just one value of l, but all possible ones
@MartinHopf sure, but that 50 is pretty arbitrary
Rithaniel
Rithaniel
(it took me way too long to determine that "regular"referred to separation.)
Semiclassical
Semiclassical
17:24
the most I noticed is that, when you shift all the numbers up by one, then they're all multiples of 12
11=12*1-1
23=12*2-1
47=12*4-1
2351 = 12*196-1
4703 = 12*392-1
Martin Hopf
Martin Hopf
2*2351+1=4703 that is the first result.
Semiclassical
Semiclassical
sure, but then why is 2351=50*47+1 relevant?
mercio
mercio
I hate those kind of questions
Semiclassical
Semiclassical
same
for instance, I hate the one that showed up here: fivethirtyeight.com/features/…
Michael.P
Michael.P
@Semiclassical so how do I prove it -_-
Semiclassical
Semiclassical
17:27
9, 10, 19, 24, 31, 40, 51, 64, 79, 90, ?
@Michael.P By understanding how polynomial multiplication works. Try multiplying out (a0+a1x^1+a2 x^2+a3 x^3)(b0 +b1 x+b2 x^2) and see which terms end up being what degree
The answer to the above? It's A9, because the pattern is (N+2)^2 in hexidecimal
Martin Hopf
Martin Hopf
start instead with ord(2,x)=11 the multipicative order of x in base 2=11.
Semiclassical
Semiclassical
if we're going to have to go to something as abstract as that, then I'm really not interested
The more arbitrary the pattern, the less I care.
Martin Hopf
Martin Hopf
thes smalles number of multiplicative order of 11 in base 2 is: 23
Semiclassical
Semiclassical
I think the pattern may have something to do with the fact that you've got (23)51 and (47)03
but I honestly can't bring myself to care
Martin Hopf
Martin Hopf
what is the smallest number with multiplicative order of 23 in base 2 then?
Semiclassical
Semiclassical
17:34
What?
base 2 isn't a group or a ring or anything. so i have no idea what you intend by multiplicative order
Martin Hopf
Martin Hopf
see en.wikipedia.org/wiki/Multiplicative_order
Semiclassical
Semiclassical
That's modulo 2, not base 2
And even so that doesn't help a whit, since 11^1 is already 1 mod 2. So the multiplicative order of 11 mod 2 is 1.
Every odd integer has multiplicative order 1 mod 2.
Martin Hopf
Martin Hopf
yes, and ord_23(2)=11
Semiclassical
Semiclassical
That's the multiplicative order of 2 mod 23.
Ninja hatori
Ninja hatori
@mercio math.stackexchange.com/questions/2960986/… have a look at it
Semiclassical
Semiclassical
17:43
So now I guess you'd want to do ord_x(2)=23
Martin Hopf
Martin Hopf
yes, that is right.
Semiclassical
Semiclassical
well, the multiplicative orders of 2 mod odd integers is listed here: oeis.org/…
Ted Shifrin
Ted Shifrin
Hi DogAteMy, @Semiclassic
Semiclassical
Semiclassical
hi
Fargle
Fargle
Hey @Ted.
Ted Shifrin
Ted Shifrin
17:45
Hi @Fargle. I saw your Palatino note.
MatheinBoulomenos
MatheinBoulomenos
Hi @Ted
Ted Shifrin
Ted Shifrin
Hi Mathein
Rithaniel
Rithaniel
Heya Ted
Ted Shifrin
Ted Shifrin
Heya Rithaniel ... Nice $\Theta$.
MatheinBoulomenos
MatheinBoulomenos
finally taking an algebraic geometry class! there was an interesting exercise on the first sheet, but they changed it and made it easier
Ted Shifrin
Ted Shifrin
17:48
LOL ... You could still do the more interesting version :)
MatheinBoulomenos
MatheinBoulomenos
so the hard direction that one had to show was that if the Zariski topology on $k^{n+m}=k^n \times k^m$ agrees with the product topology of the Zariski topologies for some $n$ and $m$, then $k$ is finite
Ted Shifrin
Ted Shifrin
Yeah, otherwise you can have varieties that are not fibers of the obvious projections.
Martin Hopf
Martin Hopf
sorry for the misstype: the smllest k such that 2^k = 1 (mod 23) is 11 so ord_23(2)=11
Ninja hatori
Ninja hatori
@LeakyNun are you there math.stackexchange.com/questions/2960986/…
Semiclassical
Semiclassical
yeah, ignore it
looks like it's the right pattern
i.e. order_47(2)=23, order_2351(2)=47
MatheinBoulomenos
MatheinBoulomenos
17:53
@TedShifrin I used the compactness of $k^m$ to get that the projection $k^n\times k^m \to k^n$ is closed and then constructed a subset of $k^n$ that is proper, closed and dense
Semiclassical
Semiclassical
and ord_4703(2)=2351
so i guess the task is to find x such that ord_x(2)=4703
Fargle
Fargle
@Ted I sent a sample of it to your email. I rather like it.
Semiclassical
Semiclassical
which...yuck
Ted Shifrin
Ted Shifrin
@Mathein: Assuming $m=n$ for the moment, can't you just look at the variety $y=x$?
Martin Hopf
Martin Hopf
so what do you think is next in the sequence: 11, 23, 47, 2351, 4703,...?
Ted Shifrin
Ted Shifrin
17:54
@Fargle: I'd rather see a lot more math ... But that does look fine.
Fargle
Fargle
I'm workin' on it!
MatheinBoulomenos
MatheinBoulomenos
yeah, the case $m=n$ is easier, since you have the non-closed diagonal by non-Hausdorffness of $k^n$
Ted Shifrin
Ted Shifrin
But you can modify that easily enough.
MatheinBoulomenos
MatheinBoulomenos
my proof is probably too complicated :D
Semiclassical
Semiclassical
no idea. from mathematica, i know that it's no smaller than x=500000
MatheinBoulomenos
MatheinBoulomenos
17:56
didn't really have a good idea to show that stuff is not Zariski closed/open other than using a density argument
Ninja hatori
Ninja hatori
@ÍgjøgnumMeg any idea math.stackexchange.com/…
Semiclassical
Semiclassical
(I'm having it compute tables of multiplicative orders of many many many integers and seeing if 4703 shows up)
Ninja hatori
Ninja hatori
@ÍgjøgnumMeg math.stackexchange.com/questions/2960986/…
Ted Shifrin
Ted Shifrin
Ninja: Please don't go pinging everyone who might not be in the room.
Either ask a direct question or wait for someone to answer it on main.
Ninja hatori
Ninja hatori
ok sorry
Ted Shifrin
Ted Shifrin
17:59
@Leaky: There may be a Chinglish origin of that phrase, but of course it's been around in English as long as there have been automobiles.
MatheinBoulomenos
MatheinBoulomenos
@Ninjahatori and please don't ping me thrice in another room after I explained that I'm not knowledgeable about the question; your obstrusiveness doesn't make me want to answer it
Martin Hopf
Martin Hopf
the smallest k such that 2^4703 = 1 (mod x)
Semiclassical
Semiclassical
smallest x, you meaen
Martin Hopf
Martin Hopf
yes,sorry
Semiclassical
Semiclassical
and it seems really big, just based on mathematica work
Ted Shifrin
Ted Shifrin
18:01
Last time I asked number theory experts, they told me that the order of $2$ in the multiplicative group mod $m$ is "unknown" — i.e., no known formula for it.
Rehi DogAteMy
Semiclassical
Semiclassical
I'm testing up to x=4000001 right now.
Martin Hopf
Martin Hopf
in other words find the smallest factor of 2^4703-1.
Semiclassical
Semiclassical
oh, that's easier to do in mathematica I think.
Ted Shifrin
Ted Shifrin
If the number doesn't exceed capacity
Martin Hopf
Martin Hopf
the sequence so far: 11, 23, 47, 2351, 4703, (the smallest factor of 2^4703-1), ...
Semiclassical
Semiclassical
18:02
well, mathematica can compute 2^4703-1 and print out the number
Ted Shifrin
Ted Shifrin
Oh, then it should factor it
Semiclassical
Semiclassical
and it comes up false when i test for primality
Ted Shifrin
Ted Shifrin
howdy, a @Balarka
Rithaniel
Rithaniel
Quick question: Suppose we start with $\mathbb{R}$ with the standard metric topology and define an equivalence relation $\leftrightarrow$ s.t. $x\leftrightarrow y$ iff $(x-y)\in\mathbb{Q}$. Is it fair to say that it's trivial to show that $\mathbb{R}/\leftrightarrow$ has the trivial topology (heh, trivial to show trivial), or does that claim warrant a proof?
Balarka Sen
Balarka Sen
Hi
Ted Shifrin
Ted Shifrin
18:04
What do you mean by trivial topology?
Martin Hopf
Martin Hopf
the sequence so far 11, (the smallest factor of 2^11-1)=23, (the smallest factor of 2^23-1)=47, (the smallest factor of 2^47-1)=2351, (the smallest factor of 2^2351-1)=4703, (the smallest factor of 2^4703-1)=?,...
MatheinBoulomenos
MatheinBoulomenos
Hi @Balarka
Balarka Sen
Balarka Sen
\o
Rithaniel
Rithaniel
The topology where only the entire set and the empty set are open.
Ted Shifrin
Ted Shifrin
So you're talking about the quotient topology?
MatheinBoulomenos
MatheinBoulomenos
18:07
every prime factor of $2^{4703}-1$ is of the form $1+2n \cdot 4703$, that could speed up the search for the smallest factor by a constant factor
Semiclassical
Semiclassical
nice
Rithaniel
Rithaniel
Yes, the quotient topology being effectively the same as the trivial topology in this case.
Ted Shifrin
Ted Shifrin
Well, you do need to work with the definition of the quotient topology. I wouldn't dismiss this as "trivial." I'd write the few sentences.
Rithaniel
Rithaniel
Okay, will do, then. Danke.
Martin Hopf
Martin Hopf
yes, but consider 2^4703-1 a 1400 digit number ECM factorisation is fast for finding factors in the range of 10^25
your method is fast for finding small factors
MatheinBoulomenos
MatheinBoulomenos
18:11
ah, I know nothing about ECM factorization other than the name and that it is uses elliptic curves
Semiclassical
Semiclassical
yeah, this has quickly wandered into the realm of "beyond mathematica's range"
Ted Shifrin
Ted Shifrin
I thought so, @Semiclassic.
Semiclassical
Semiclassical
ah, this looks handy: alpertron.com.ar/ECM.HTM
Martin Hopf
Martin Hopf
yes unfortunately no factors of 2^4703 have been found. see factordb.com/index.php?query=2%5E4703-1
Semiclassical
Semiclassical
luckily, you can input 2^4703-1 into the above calculator directly
(and anyone who asks what the next number in the sequence after this unbelievably large number is going to be laughed out of the room)
Martin Hopf
Martin Hopf
18:17
with the tool from Dario Alpern it will took about an hour to find a factor >10^25
it will be sure a very large number > 10^40
Semiclassical
Semiclassical
i mean, the largest the factor could be is 2^4072-1 ~ 10^1415
sooooo
MatheinBoulomenos
MatheinBoulomenos
maybe if you run Sage or Magma natively on your machine, the perfomance will be better than with an online tool (I'm no expert at this computational stuff)
Semiclassical
Semiclassical
possibly.
Daminark
Daminark
Hey there ya nerds
Martin Hopf
Martin Hopf
no the largest factor could be < 2^(4702/2)
Semiclassical
Semiclassical
18:21
can't say this seems very appealing though, absent a better approach
Abdullah UYU
Abdullah UYU
Hola
MatheinBoulomenos
MatheinBoulomenos
hi @Daminark
Semiclassical
Semiclassical
I was just using the naive sqrt(2^4073-1) bound, tbh
Daminark
Daminark
How's it going?
MatheinBoulomenos
MatheinBoulomenos
pretty well, thanks. Finally taking an alg geo class. And yourself?
Martin Hopf
Martin Hopf
18:23
yes sqrt(2^4073-1) is about 2^2036
Semiclassical
Semiclassical
that still leaves you having to worry about factorization over integers up to ~700 digits tho
ah, you're right
wait
yeah, alright. (it's closer to 2^2351, amusingly)
But regardless this no longer seems like a good use of time.
Martin Hopf
Martin Hopf
and dont forget the smallest factor can be 2*k*4073+1 with k>0
you're right, nevertheless the sequence has one more element:
11, 23, 47, 2351, 4703, (the smallest factor of 2^4703-1), ...
Alessandro Codenotti
Alessandro Codenotti
@MatheinBoulomenos I know who to ask about sheaves and stuff then :P
Semiclassical
Semiclassical
A good question at this point would be how long it'd take to compute the next term
I suspect the answer is going to be prohibitive.
MatheinBoulomenos
MatheinBoulomenos
@AlessandroCodenotti I do like sheaves
Alessandro Codenotti
Alessandro Codenotti
18:31
Good, because I have a lot of confusion
Semiclassical
Semiclassical
I have to wonder if there's the possibility of the sequence hitting the exponent of a Mersenne prime
Martin Hopf
Martin Hopf
thats a good question :)
Semiclassical
Semiclassical
in which case it'd just stop there
Alessandro Codenotti
Alessandro Codenotti
Ah, unrelated random coincidence: my algtop professor was a student of Tom Dieck! And you can see that in his style and approach to teaching algebraic topology
Semiclassical
Semiclassical
I mean, I imagine the probability of this happening is small for this sequence
but I sorta doubt you'd ever be able to forbid it outright
Martin Hopf
Martin Hopf
18:34
for the mersenne primes start the sequence with 3:
3,7,127,?
MatheinBoulomenos
MatheinBoulomenos
@AlessandroCodenotti nice!
Semiclassical
Semiclassical
oh, mersenne primes require that p and 2^p-1 both be prime
Martin Hopf
Martin Hopf
2^3-1 is a Mersenne prime 2^7-1 is so and also 2^127-1 is a Mersenne prime
is 2^170141183460469231731687303715884105728-1 also a Mersenne prime ?
Semiclassical
Semiclassical
given that the largest known one is 2^77,232,917-1
MatheinBoulomenos
MatheinBoulomenos
@Alessandro there's value to both the algebraic Tom-Dieckesque and the geometric Hatcheresque approach, I only had the latter in the lectures and the former just from my own reading
Semiclassical
Semiclassical
18:38
i think the answer is going to be "no one is even remotely close to knowing whether that's prime"
i mean, there's no particular reason to think it should be
Martin Hopf
Martin Hopf
there is no factor known of 2^170141183460469231731687303715884105728-1
Semiclassical
Semiclassical
i don't see any reason, absent other considerations, why one should expect that particular number to be prime
Alessandro Codenotti
Alessandro Codenotti
@MatheinBoulomenos I'm definitely glad I read singular homology from Hatcher since here we just started by defining an abstract homology theory and we will eventually build an explicit one
So that I have some intuition for what's going on
Semiclassical
Semiclassical
it could be, but it's so beyond our computational range that speculating about it just seems futile
MatheinBoulomenos
MatheinBoulomenos
@Alessandro yeah, I can see a point for doing an intuitive/geometric approach first
if you actually want to compute things, cellular homology is nice
Martin Hopf
Martin Hopf
18:46
yes, primes distribution is known, it is very unlikely that it will be prime
Alessandro Codenotti
Alessandro Codenotti
So I've heard, I only learned about singular and simplicial homology
Daminark
Daminark
@Mathein also finally taking an alg geo class so that's something :P
Today we talked some about primary ideals, the fact that ideals can be written as finite intersections of primary ones, and using it to show that projective varieties can be written as a finite union of irreducible ones
Alessandro Codenotti
Alessandro Codenotti
We did stuff about presheaves and sheaves today in alggeo but I can't say I followed a lot of what was going on
Primary decomposition is cool
Daminark
Daminark
In AT we did homology axiomatically, gonna have to redo the computations done in class since they were a bit of a mess
But yeah after this I think we're gonna actually construct homology
Oh also in AG we started talking about the Hilbert function
MatheinBoulomenos
MatheinBoulomenos
19:06
@Daminark oh, so you're doing dimension theory, that's one of the more difficult parts of commutative algebra
Alessandro Codenotti
Alessandro Codenotti
I was actually surprised by how much stuff you can prove just from the axioms
That's definitely a cool thing to see. It has some kind of foundational flavour after all
MatheinBoulomenos
MatheinBoulomenos
yeah, true
we did singular first, then axiomatic, then cellular, than simplicial
Eric Silva
Eric Silva
19:25
sup nerds
MatheinBoulomenos
MatheinBoulomenos
sup @Eric
Eric Silva
Eric Silva
how goes it
MatheinBoulomenos
MatheinBoulomenos
pretty well, and yourself?
Daminark
Daminark
Hello nerd
Eric Silva
Eric Silva
@MatheinBoulomenos aight im kind of bored and stuck in a lecture on hodge theory
but it aint that bad cant reallly complain
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