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00:02
@TedShifrin It's pancreatitis. We need to get her eating and drinking. Using mirtazapine to get her appetite going.
@TedShifrin It's stressful. Some of that might have been responsible for my overnight at the local hospital.
Oh my. I’m sure. Gosh. I’m sorry. :(
These last years are stressful for everyone. But hang in there!
@robjohn Sorry to hear it. It it tough all around.
 
1 hour later…
01:11
Hello,
@copper.hat. :/ Have you applied before Kruskals algorithm for minimum spanning tree please?
There are O(E) operations on the disjoint-set forest?
This is my question though
$E = \Sigma_v (v) = 2m$, where $v$ is vertex of graph and $m$ is total number of edges
a loooong time ago. what is your question?
@copper.hat. hahah :/
Wow. I am just looking to know why we got total $E$ disjoint operations when we sort edges before we start make unions, etc. to find out MST
01:39
Surely you need $E \log E $?
@copper.hat. Thank you!
Why $E$ please?
What is your own interpretation as you understand it please?
No proof is needed
 
2 hours later…
03:39
You need to sort the edges surely?
Suppose that the list of vectors $v_1,v_2,\cdots, v_n$ in vector space over field F is linearly independent. If $\lambda \in F$ is $\ne 0$ then is $\lambda v_1,...,\lambda v_n$ linearly independent?
For any $c_i$'s in F, if $\sum c_i\lambda v_i=0$ then $\lambda \sum c_iv_i=0$
And multiplying both sides by $\lambda^{-1}$, the result is readily observed to be true as all $c_i$'s will be forced to be 0
yeah, so by linearly independence of the v_i's, all the c_i's are zero, you win
But my question (confusion) is: when will characteristic $2$ create a problem?
it won't, for this
can you please give one example where char F =2 will create problem?
I have $u\in F$ then $u+u=2u=0$ so I can't conclude that u=0.
04:22
for this result? i can't
2 is not a nonzero element of F
nevermind, I think I got it :)
there are places where characteristic 2 is different from other finite fields, with bilinear forms and quadratic forms sometimes you really want to be able to divide by 2
finite fields aren't ordered, which messes up stuff involving positivity, and they aren't algebraically closed, which means stuff like jordan form is going to be more complicated, just as it is in R
i'm sure there are clever ways to get to the same or similar results, but the proofs you tend to see in other fields won't immediately work
definition of a field is probably pretty much all I know about fields for now. i am yet to study jordan forms, billinear forms etc. :)
04:38
hmm. so i may be teaching an actual course this spring, not just doing TA work
and now my brain is switching gears from "oh yeah, this is a distant possibility" to "oh shit, this might actually happen"
@Semiclassical great :)
05:06
That should be more challenging , Semiclassic.
05:32
I want to prove that vector space of all real valued continuous functions on $[0,1]$ is infinite dimensional.
Suppose on the contrary that $\displaystyle V$ is finite dimensional. There exist $\displaystyle f_{i}: R\to R 's\ ,1\leq i\leq n$, where $\displaystyle n$ is a fixed natural number such that $\displaystyle f_{i} 's$ is a linearly independent list and spans $\displaystyle V.$

For any continuous function $\displaystyle g\in V$, there exist unique real numbers $\displaystyle r_{i}{}_{g} \in \mathbb{R}$ such that

$\displaystyle g=\sum _{i=1}^{n} r_{ig} f_{i}$
I tried to repeat arguments as in my post here (math.stackexchange.com/questions/4251699/…)
but that won't work as set of all continuous functions on $[0,1]$ is of cardinality continuum.
I meant that there exist $f_i$'s such that $f_i:[0,1]\to \mathbb R$ are continuous functions.
indeed. it might be simpler to exhibiit an infinite set of linearly independent elements of C[0,1]
hmm
I somehow forgot polynomials.
The problem is solved now :) I always have 1,x,x^2,...
or, to avoid infinity, to produce for any n, an n-dimensional subspace of C[0,1]
and now you have remembered them :)
Thanks a lot Leslie :)
@Koro What about $f_n(x) = x^n$.
Or $g_n(x) = \sin 2 \pi n x$?
05:40
that's what I said @copper. Indeed, $f_i(x)=x^i$ solve the problem. By the assumption of finite basis, $i\le m$ for a fixed natural number $m$. So the vector space is not spanned by the $f_i$'s hence $f_i$'s can't be a basis.
@copper.hat i didn't think of that. I'm not sure if it works. I'll think about this one.
if it's finite dimensional, so is its dual, and yet it's pretty easy to write down arbitrarily long lists of linearly independent linear functionals on C[0,1]
@leslietownes I'm yet to cover dual space, so I'll archive this comment for now :)
I meant $f_\beta(x) = \max( \beta x,1)$ for $\beta >0$.
i suppose it isn't 1000% obvious that the monomials are linearly independent. you do need to know that the zero function is only induced by the zero polynomial. not that it's hard to prove but it is often taken for granted
It is uncountable and straightforward (by differentiating) to show that they ar eli.
not just eli, but they are li.
05:51
@copper.hat if these $g_i$'s are li (not proven by me yet) then $5=\sum r_i g_i(x)$ for all $x$ which is a contradiction as this does not hold when $x=1/2$.
it only remains to show that $g_i$'s are li
What $g_i$ are you referring to, the $\sin$s?
I have many sins/
@copper.hat yes
Where are you pulling the $5$ from?
$f(x)=5$ is a continuous function on $[0,1]$ so if $g_i$'s are basis of $V$ then one should be able to write $f$ as linear combination of $g_i$'s.
I never claimed that the collection was a basis, just that they are li.
You can show that any finite number of them are li, hence you cannot have a finite dimension.
But why not shoot for uncountable.
I am not even drinking yet!
05:58
@copper.hat yeah, so if the are LI and V is finite dimension (supposing this on the contrary) with dim $n$ then $g_1,g_2,...,g_n$ are LI and this list is of right length (dim V=n, as we assumed on the contrary). But we know that $f(x)=5$ is continuous on $[0,1]$ so there must exist real number $r_i$ such that $f=r_1 g_1+...+r_n g_n$, that is $5=\sum r_i g_i(x)$ for all $x$, which is a contradiction as at $x=\frac 12\in [0,1]$, we have 5 on LHS and 0 on RHS.
So our assumption that V is finite dimensional is wrong.
i'm not sure that it's possible to 'write down' a linear algebra basis for C[0,1]. 'write down' meaning, without appealing to AC or something.
linearly independent sets are by contrast easy to find.
@Koro I think you can just suppose $\dim V = n$ and pick $n+1$ li elements $g_k$ and then conclude a contradiction.
yes, that's also fine :)
Arguing that countable set is a basis is likely to get your hand slapped...
Or bitten by an angry hamel in the desert.
I need some wine. A Hamel basis is a what a basis is called in an infinite dimensional space.
To distinguish from other sorts, such as Schauder.
@copper.hat oh my God 😅
06:04
i call them linear algebra bases. i suspect hamel would be embarrassed by his name being associated with that.
I think you meant camel? @copper
the basis of truth
like people calling the indicator function of the rationals the dirichlet function or weierstrass function or whatever they call it.
it was a bad play on words. i excel at bad plays on words.
that is a characteristic of indicators with no character
some things don't need to be named after people. i feel very strongly about this. for more, consult the 3 hour episode of my podcast, leslie speaks, on this issue.
06:06
wow, that could be deep if you smoked the appropriate substance
it is handy to have a name, albeit we all know that the name rarely tells the truth.
complete normed space does not have the haughty ring of banach
and hilbert. almost a cartoon.
we can have banach spaces. a list of acceptable things named after people appears around the 2:30 mark in the podcast.
ok, i must go and prepare for my son's departure.
my wife & daughter are heading to la (yes, the real la) next week so i will be in truly pitiful shape next week.
i was pretty deep in the bag by that point, it's mostly me just reading off names of things while you hear ice cubes clinking against glass in the background. the last 15 minutes are me snoring.
good luck with all of that.
breaking every shred of irishness i have, i told my son that i would miss him. he looked at me as if i had blown a noseful of covid snot in his eyes.
i hope you pummeled him with a coal shovel to sort of even out the universe a little.
06:10
i am ready for a clinking ice cube.
just one sentence without a f** typo, ffs.
there, the only such sentece
i have only hit each of my children once, hard.
when they bit my stomach and drew blood.
while drying them after their bath.
through my t-shirt (in case tsa/cps are listening)
suddenly it all became clear to copper
vs code vs vim
i guess you didn't have some garlic or a cross handy.
the hatred, the snide remarks, no slippers and cool beers for dad as he gets home from a grueling day in the basement.
vimffs
vs code is for people who like visual silliness
microsoft programmers and the like
console ❤❤❤
the like the look of a blue screen
damn it, i used to flip switches on a pdp8
no namby pamby ascii rubbish.
06:15
$ touch con
unicode is a good example of what is wrong in the world with all these woke symbols.
mathematica vs matlab?
vs make your own
def not mathematica
at least matlab started with fortran
before degenerating into c/c++
"degenerating"
c: the power of an assembler with the readability of an assembler
c++: bjarn on some form of hallucinogenic drug
i need some legal ssistance
what does libel mean?
ok. there are folks here who want to talk to me about something. good night folks!
06:23
Good night @copper. Thanks for helping me today :)
@Koro I suspect I was more noise than help, but I appreciate your words :-)
Bye
@copper.hat no, that $g_n$ example helped and is also an exercise for me (as I said, I've not yet proven $g_n's$ to be LI yet) :)
06:59
$g_i$'s are indeed LI because $\{g_i: 1\le i\le n\}$, where $g_i(x)=\sin (2i\pi x)$ is an orthogonal set over $[0,1]$.
07:17
Is runtime cost of recursive Fibonacci related to golden ratio?
To me it seems somewhat exponential.
08:00
When we write $H^2(G,k^\times)$ what is the implied action on $k^\times$ normally?
As in the one that makes $k^\times$ a $G$-module
 
3 hours later…
11:03
that's a very open-ended question
context might help
11:51
Isn't there a default assumption? I think it's suppose to be the trivial action?
12:22
Suppose $f$ is holomorphic on a neighborhood of $\overline{B(z_0,r)}$, where $z_0$ is a zero of $f$. If $f$ is identically $0$ on the boundary of $B(z_0,r)$, does it follow that $f$ is $0$ on the whole disc?
Is this just an application of the identity theorem?
it's hard to make default assumptions in the absence of context
if $G$ and $k$ have nothing to do with one another, this is bizarre and nothing but the trivial action makes sense, but usually expressions like that come up within a context such as Galois cohomology when $G$ is a Galois group acting on $k$ or something of the sort..
Hmm...the assumption that $z_0$ is a zero doesn't seem necessary...
@user193319 yes
you can also argue using Cauchy's integral theorem
Ahh, interesting. Thanks!
if you know the stronger version thereof, it actually suffices to assume $f$ is holomorphic on $B(z_0,r)$ and continuous on $\overline{B(z_0,r)}$
12:29
Oh, that makes sense. Thanks for pointing that out!
13:19
Why resizing array with the following sequence $3k, 5k, 7k, 9k, ... $ for some positive constant $ k$ is more intuitive than $2k, 4k, 8k, 16k, ... $ please? Here we resize an array one it gets full by either of the sequeces. You can only follow on of the sequences, however, $3k, 5k, 7k, 9k, ... $ is recommended as it it adopts to higher frequency of add calls to array. What do you think please if you have any thought?
13:33
Trying to figure out what the “usual” terminology for this. Suppose I’ve got an (ordered) list of N distinct elements. Then the identity permutation is obviously the only one which leaves the list unchanged.
Now suppose some of those elements are identical. To be precise: n1 are type 1, n2 are type 2, and so forth
Then the number of permutations which leave the list unchanged are n1! n2!…
@Semiclassical. Thank you, but here, I am looking to see as to why the 3k,5k,7k,9k,... sequence is a better choce to consider when array is full and you want to resize it (increase size to acoomodate new elements once it's full)
Um
I wasn’t talking about your problen
:/
Sorry
It was very close though
I’ll take your word for it
:/
14:15
imagine you have a sequence of positive integers and positive or negative counts in pairs. E.g. (2,3), (1,-2), (2,-2), (1,2) which means 3 twos, -2 ones etc. I want to know if there any of the integers end up with a non-zero count. In this case 2 gets count 1 and 1 gets count 0 so the answer is yes. if I just let c equal the sum of the counts and z equal the sum of the product of the integers and counts I get c = 1 and z = 2
to answer my question about whether any of the integers have non-zero count, is it enough to check of c = z = 0?
14:52
is the following true? let $D_1,D_2 \subset \mathbb{C}$ be domains, and suppose $f : D_1 \rightarrow D_2$ is a conformal isomorphism , let $\gamma$ be a closed curve in $D_1$ and $a \notin Im(\gamma)$ a point in $D_1$, then $n(\gamma,a) = n(f \circ \gamma, f(a))$
if $f$ is just a conformal map this is false
15:46
I forgot what a conformal isomorphism even is, but an orientation-preserving homeomorphism will suffice
16:29
@Thorgott its just a biholomorphism
im able to see this when $\gamma$ is null-homotopic in $D_1$, using the argument principle.., whats the proof for $f$ an orientation preserving homeomorphism
also im not assuming $\gamma$ need be $C^1$ or even rectifiable
just needs to be continuous
 
1 hour later…
17:40
I realized I don't have a particularly convenient argument, but here is a way to go about it: $D_1\setminus\{a\}$ is an open subset of $\mathbb{C}$, hence contains a bouquet of circles onto which it deformation retracts. A small deleted neighborhood of $a$ will be contained inside exactly one of the circles in the bouquet, for otherwise it would be contractible. This furnishes a retraction from the free group $H_1(D_1\setminus\{a\};\mathbb{Z})$ to a direct summand. The loop $\gamma$ defines an element of $H_1(D_1\setminus\{a\})$, which maps to its winding number (upon identifying $H_1(S^1)\
sorry, this isn't lucid at all, but this problem turns out trickier than I was thinking..
 
1 hour later…
18:54
Hi everyone!
I read deltafx is equivalent to (df/dx)delta x. So are both of them same thing only the df/dx is a more accurate. And both are rates like charge per unit area or distance per unit time.
df/dx is also some physical quantity per unit some physical quantity ?
19:33
Hello,

If we have a triangle where all edges have same weight, then can we have a cut where all edges are crossing edges please?
I believe that this is a valid cut and all edges are cross edges, is that correct please?
this looks like one of those diagrams in a high school biology book.
it's the krebs cycle
avra, this may be more my lack of background than anything else, but what is a 'cut' and what does it mean for edges to have the same weight
is this some standard thing that appears in the middle of some proof of some graph theory algorithm i guess just ignore this
@copper.hat. Hahaha
The red path is the cut
So, we can not here have Minimum spanning tree just by relying on light edges (minium crossing edges weights), so having all light edges does not guarantee that we will get MST.
That is what I was trying to prove :/
Thank you anyway
weight of edges is a natural number indicating a value for edge
light edge is supposed to hold the minimum weight and it must be a crossing edge too
19:53
avra, forgive my ignorance, but what is it about a 'cut' that makes what you've drawn different from what you'd get if there was just a straight line between the endpoints of your red curve
20:47
@leslietownes. Appreciate your responses. This is from the question, that all edges are a cut edges, so the read line (cut) has to go through all of them
This is how I understand it :|
what is the significance of a cut going through an edge?
21:19
@Avra I do know a bit about this (it’s related to the classical aspect of Bell’s inequality) and what you should notice is that your cut crosses the bottom edge twice
As such, it’s equivalent to not having a cut over that edge at all
this is what i was wondering. if the purpose of the cut is to separate the graph into two pieces, the two lower vertices seem to wind up in the same piece. so i'm wondering if there is more to a 'cut'
The rule that I’d give: if both nodes belong to the same subset, there’s no cut for their edge
Another way to put it: assign plus / minuses to the nodes, and label each edge with the product of these signs
No matter what you do, you’ll never end up with an odd number of minuses on the edges
You can have no cut edges or two cut edges, but not one or three
If you do it on a 4-cyclic graph, you similarly can only get even number of edges being cut
This leads to some nice polytope stuff, eg, mathoverflow.net/a/128809/55904 @leslietownes
And the facets of those polytopes are Bell inequalities
21:45
@Semiclassical. Thank you!
@Semiclassical. Have you studied graph theory before please?
@leslietownes. Very sharp. Thanks. Yeah a cut produce a cut, so I made mistake up there, sorry
Not a lot, but I have run into how cut graphs relate to Bell inequalities
It’s sorta cute. Suppose, according to some distribution, you picked a partition on a graph
And assign -1 to an edge that’s cut, and zero otherwise
We can then start to ask statistical questions, eg, what’s the expected value of a given edge
And in this way you find inequalities. For instance, suppose you add the values together that you get from the three edges in a 3-cycle
A priori, each value is just some number between -1 and 1, so their sum must be between -3 and 3
But because you can only get an even number of cut edges, the lower bound is actually -1 not -3
And this in essence is bell’s original inequality :)
(Nowadays one usual does this for the cyclic graph on 4 nodes rather than 3.)
 
2 hours later…
23:43
@Semiclassical. Wow!
That is really interesting
Any idea how we can detect that we have odd cycle of a graph (odd number of vertices) using the fact that we store the length of a path at each vertex as we traverse the graph as $d[v]$. So, the equation to detect if we have an odd cycle is $if(d[u] \bmod{2} == d[v] \bmod{2})=> Odd Cycle$

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