if i am right, 1.125 hours.

but aren't the logs already of size 200 sm ?

yeah, i also meant that but i thought you meant 'if they were all joined together and then cut.'

but we don't know how many of them there are so it wouldn't be possible to answer that i think

I also think so, but seeing the answer at the back of the book i thought i maybe mistaken, it has something to do with inverse proportionality as you see, so i tried several times anyway.

Hello @AkivaWeinberger! What do you think about my problem 'Several timbers of the length 2 m were cut into small logs of 50 sm in 4.5 hours; how long wolud it has taken if they were cut in 40 sm?' is it solvable?

By sm you mean cm?

Centimeters?

yes

It takes three cuts to cut the 2m log into four 50cm logs -|-|-|-

hi friends

so that's 1.5 hours per log per cut

here's a random question: why do we care about non-matrix lie groups?

It takes four cuts to cut the 2m log into five 40cm logs -|-|-|-|-

so that would be 1.5*4=6 hours

all the books go out of their way to define lie groups in terms of manifolds, but then they immediately say all the """""important""""" lie groups are matrix lie groups anyway

so like, what's the actual point in doing this?

What's an example of a Lie group that can't be expressed as a matrix Lie group?

the one my book gave was $

As a baby version of that, I like defining groups as permutation groups than the general thing

oops

thank you very much! @AkivaWeinberger

@BalarkaSen Yeah but it's not hard to show they're equivalent

Was that Cayley's theorem?

Conceptually group actions are pretty nontrivial

@AkivaWeinberger right

Yes

@BalarkaSen but often they're used as introduction

I mean, their example, not the concept of a group action itself

the first group anyone encounters is the symmetry group of the triangle

@AkivaWeinberger I think the universal cover of SL2(R) or something should do it

math.stackexchange.com/questions/2783974/… hi i did this question.i want to know i did this correctly. can anyone help?

@LeakyNun Right, true

was $\mathbb{R}^2 \times S^1$ with the product $(a,b,\theta)(c,d,\phi) = (a+c,b+d, e^{iad}\theta\phi)$

where $S^1$ is the unit circle in the complex plane

is it easy to prove that it is not a matrix lie group?

apparently no

because they wait 3 more chapters to do it

hmm

I dunno, I'm trying to learn this stuff in a way that isn't just "something something smooth groups and tangent spaces at the identity"

Starting lines of thoughts: if you want to embed the universal cover of SL2(R), let's call that G, in M(nxn)(R) then taking the derivative gives a finite-dimensional representation of sl2(R) (Lie algebra of G = Lie algebra of SL2(R) = sl2(R)).

I didn't know Balarka knows Lie algebra as well

balarka knows everything for some reason

Only if

I just know them as the tangent space at identity of a Lie group, like Samuel said

@BalarkaSen why don't you like algebra?

and do you like geometry?

I'm too bad at it. Maybe I should work on it

I like it but I can't necessarily do it

Atiyah is your friend ^^

Right I should get back to that book

how much have you done?

which atiyah book is this?

First three chapters, give or take, minus some nontrivial exercises. Upto localization

@SamuelYusim atiyah-macdonald, something something commutative algebra

oh, that one's good

@BalarkaSen I think you should read chapter 7

I glanced at it occasionally when I was learning that stuff

I have forgotten so much math. I haven't done stuff in months

@SamuelYusim same goes to you

everyone should read chapter 7

@SamuelYusim It's short, which is good, but I also felt it was super terse

The exercises made me feel like shit

@BalarkaSen they are difficult. nobody would deny that.

Hi there.

hola

ola

@SamuelYusim i guess an analogy is every smooth manifold can be embedded into $\R^{2n}$ and so in theory you can study manifolds just as submanifolds of euclidean space, but i think a lot of things become harder/not as obvious (e.g. what notions depend on your embedding and what notions are intrinsic to your manifold)

I think what we needed before to justify from $L - \epsilon <\displaystyle \lim_{k\to \infty}{a_{k}}^{1/k} < (L + \epsilon)$ that $\displaystyle \lim_{k\to \infty}{a_{k}}^{1/k} = L$ is that $\epsilon$ had to be arbitrarily fixed.

Fixing it arbitrarily it yields to $\displaystyle \lim_{k\to \infty}{a_{k}}^{1/k} = L$

@loch my question is whether any particular thing is actually easier, I guess

So somehow I want to say that the $n$-dimensional representation of $\mathfrak{sl}_2(\Bbb R)$ extends to an embedding of $\text{SL}_2(\Bbb R)$ in $M_{n \times n}(\Bbb R)$ by exponentiating it, or something.

By composing with the covering $p : G \to \text{SL}_2(\Bbb R)$ you get another embedding of $\text{SL}_2(\Bbb R)$ in $M_{n \times n}(\Bbb R)$ which induce the same map on the Lie algebra, so these have to be the same embeddings. Aka, if $\iota : G \to M_{n \times n}(\Bbb R)$ was our original, $\iota = \iota_0 \circ p$ for some embedding $\iota_0 : \text{SL}_2(\Bbb R) \to M_{n \times n}(\Bbb R)$.

But... that can't be an embedding because $p$ squashes stuff - it's a nontrivial covering map

Something like that

Which one is SL2 again?

ad - bc = 1

Ah

so it's closed

If what I said is going to work it's going to work for (a nontrivial cover of) any non-simply connected Lie group I think

Eh, no, something more is needed. Clearly false for S^1.

Unsure.

I'm working through the proof that $L^{p_2}(E) \subseteq L^{p_1}(E)$ when $1 \le p_1 < p_2 \le \infty$ and $E$ is of finite measure. In this proof, the author defines $p = p_2/p_1 > 1$ and claims that $f \in L^{p_2}(E)$ implies $f^{p_1} \in L^p(E)$. My only problem is, how is $f^{p_1}$ a well-defined real-valued function? If $f$ takes on negative values and if, e.g., $p=1.5$, then $f^{p_1}$ would be complex.

it suffices to consider nonnegative functions @user193319

@0celo7 Because $f$ can be expressed as a difference of nonnegative measurable functions, right?

no, because $f\in L^p$ iff $|f|\in L^p$, by definition

Oh, I see! I'm surprised the author didn't mention this reduction, since he's painstakingly detailed in other proofs. Thanks!

@SamuelYusim hm i don't really know lie groups all that well - so im not sure. i think it's also not clear what you mean by your question.. what properties about lie groups do you care about? personally one reason they're important is because they are important examples of manifolds so..

I mean, same here. I really just want some confirmation that yes, this is a thing people make actual use of, and not just a generalization for the sake of generalization

Yup Lie groups are fun and important and natural

"important"

Let's see if I can come up with an example

non-matrix lie groups...I think one of Thurston's geometries is not a matrix group @SamuelYusim

Wow, it's a Balarka.

well - even if there didn't exist lie groups that are not matrix lie groups (which is false) - then what you would have is an equivalent definition - and often you'll find different (equivalent) definitions being useful in different settings!

The loch finally comments (after bazillion number of times of popping in and out during downtimes)

@SamuelYusim Off the top of my head, I think one of the unifying stories for me has been the geometry of Lie groups. Every compact connected Lie group $G$ has a Riemannian metric (you know what those are, right? Otherwise read it just as "metric") that's compatible with the group structure (read: $d(x, y) = d(gx, gy)$). Under that, you get a geometric theory in which the geodesics (locally distance minimizing paths) of $G$ are the 1-parameter subgroups, i.e., homomorphisms $\Bbb R \to G$.

Which is kinda nice

You need bi-invariant for that, I think, Balarka.

Yeah I was shoving the detail under the rug

"compatible" really means bi-invariant

@BalarkaSen the new pdp video is disgusting

The rug is bumpy today.

Question: How does bi-invariance of the length metric interact with the bi-invariance of the Riemannian metric? Does the former imply the latter? I'd think so.

Hi everyone

Hi demonic @Alessandro

@0celo7 Let's see it.

sup nerds

Hi Eric.

@SamuelYusim Yes, to answer your other question, the universal cover of SL(2,R) is not a matrix group and is hugely important

ahhh that's good

In general, I don't have a good grasp of how one recovers Riemannian metric from the length metric. Taking a derivative something something.

Maybe one of you can teach that to me

ohhhhhhh of course it's important, I've seen it in quantum group stuff

@BalarkaSen let $c$ be a curve with tangent $v$, then $$|v|=\lim_{t\to 0}\frac{d(p,c(t))}{|t|}$$

$p=c(0)$

by polarization you get the metric back

@0celo7 Ah, great, then recover the inner product by the polar-fuck

sniped.

I sniped you years ago when I gave you this as an exercise.

oh did you

rip

snipped ✂️ ✂️

It's someone's theorem that continuous isometries of Riemannian manifolds are smooth, this is the first step of the proof

Accurate

Isometry means of $(M,d)$ in the first instance

and of $(M,g)$ in the second

Probably Meyers-Steenrod

Interesting

@0celo7 great so it's a hentai simulator

yes

kind of a lame video imo

@BalarkaSen If $M$ and $N$ are orientable, $M$ is spin, and $M$ covers $N$, is $N$ spin?

Hm I know that spin manifolds are covered by spin manifolds but...

I am doubting if that's true

@SamuelYusim actually an example where i think the advantage of knowing things about lie groups is clear is for example if you want to prove that $U(n+1) \rightarrow U(n+1)/U(n) \isom S^{2n+1}$ is a fibre bundle (which is an important bundle in topology!) - in the sense that I think trying to prove this knowing what the group is confuses things imo, but where general facts about actions of lie groups give you the result.

neat

you guys are so nice and helpful

@SamuelYusim the representation theory of Lie groups/Lie algebras is important for holonomy, quantum mechanics, ...

yep yep yep

guys, what is meant by: "the integer part of $1/2N$"? (where $N$ is some natural number)

@0celo7 I guess he answered my question :P

→ 8 messages moved to Trashcan

@BalarkaSen welcome back

:-)

Hey hey hey

Constant vigilance, eh/

yeah, what happens in physics stays in physics

good luck with that agenda

I have a space $X$ such that for every point $x \in X$, $x$ lives in a linear subspace $S \subset X$ of vector space dimension $n$; however, it's possible for two different points to live in subspaces of different dimension Does this make $X$ a topological manifold? I don't think so, since the definitions I've come across seem to require a "global", "uniform" dimension. If not, is there a name for such a space?

I have a general question regarding notation in linear algebra for linear transformation may I ask this question here?

@Jon yes

Can I use math jax here?

yes

but you need to check the room description to enable rendering on your side

it will still render on our sides

@Jon: Is the linear operator mapping vectors in $\Bbb R^2$ to vectors in $\Bbb R^2$ or elements of $\Bbb R$?

hey @TedShifrin

heya @Antonios

how're things in SD

doing fine, except for my deteriorating disks/vertebrae in my neck :)

Hello everyone!

are any of your algebra students passing, @Antonios?

howdy Demonark

@TedShifrin the course is done (semester ended yesterday - I'm FREE), but uh the ones I knew the best did relatively well

well, congrats on doneness ...

forgive me if I already mentioned it, but I'll be teaching linear algebra this summer for a 6 wk course

that should be fun

what kind of linear algebra? Strang style? proof style?

and hi @Daminark s

uh, well "my" style hahaha, but it's supposed to be a first course, à la row reduction I assume

they don't have a standard text and syllabus?

Its from $L:V to V$ to itself so $R^2$

no syllabus has been sent to me yet... lol

though i'm about to inquire re. that

Right, @Jon. So $f(x)=3x$ makes sense, but what you wrote doesn't.

What you wrote is a perfectly nice linear map $\Bbb R^2\to\Bbb R$.

Are you sure?

The wedge sum and the free product of two topological spaces would have the same fundamental group by Van-Kampen, right? Because one is $\pi_1(X)*\pi_1(Y)$ and one is $pi_1(X) \substackl{\{\text{point}\}}{*} \pi_1(Y) = \pi_1(X) * \pi_1(Y)$?

LOL, yes, @Jon. I'm quite sure.

@Antonios: 6 weeks isn't long. How many hours a week?

2 hours per day, 4 days a week

Ted, check your mail.

That's a tough pace for the students.

I know no other way to solve other than using the method I just mentioned.

What is free product of topological spaces, @GFauxPas?

It aligns with the book therefore it must be right.

And rightly so.

@Jon: If you don't want to listen to an expert, then go ahead and do it by yourself.

Daily classes are a time

@TedShifrin One of my primary complaints about this school is that very little attention is paid to the teaching of undergrads. It might be worse than berkeley in that regard.

aaaah whatever you understood my question, thanks

In the REU we had one like that, really helped that our professor had a 5 minute break after about an hour and a half

Sorry then what is x then if not a vector?

Demonark: My AoPS class meets 1 hr 45. The first few weeks I tried giving them a break in the middle, and they just got on their phones. So I quit.

it's like $X \times Y$ but without insisting $(x,0)$ commutes with $(0,y)$

@GFauxPas It might be best to not ask questions re. Cappell's problems. It could potentially constitute academic dishonesty.

Though I will admit he was somewhat nebulous about the rules.

@Jon: $x$ is a vector and the function sends the vector $x$ to $3x$. Now check the linearity properties.

Oh but the exam isn't about fundamental groups though?

this is a top I issue and I'm brushing up. but if you say so I hear that

What does it mean for elements of a topological space to commute? Say what?

That question arguably answers one of the problems. Just a caution.

I guess I'll shaddup.

Best to stick to your notes or Hatcher, I think.

@Antonios: You could always try using my linear algebra text. :P

Definitely more aimed at students learning applications and proofs, though.

Ted I think I got the terminology wrong but anyway

@TedShifrin I really want to have fun with the class, but I don't want complaints because this is my income source for the next 2 semesters.

(yay...)

One last question thanks for your time what is $v_1$ and $v_2$ equate to?

Yeah, that's why they should have a standard text and syllabus.

This is always a confusion, @Jon. People write $v_1$ and $v_2$ for two different vectors sometimes, but they also write $v=(v_1,v_2)$ and mean those are the coordinates. You have to have context.

yeah I mixed up my terminology Ted but anyway

well, I don't want to meddle in a do-it-yourself final exam, @GFauxPas.

yeah I'm mailing the dept. as we speak. I forgot to send the mail yesterday lol

My complaint (as associate dept head and chair of curriculum before that) was faculty who ignored the departmental syllabi in the name of "academic freedom." Really fair to students, that is.

I forgot to add that $v= (x_1,x_2)^T$ if that clears up any misunderstanding.

right, I thought it was okay because it's not an exam on fundamental groups or van kampen's theorem, that was last semester, but Antonios is saying that it's related enough to be potentially dishonest, and I see where he's coming from

@Jon: Let $x$ and $y$ be vectors. What is $L(x+y)$?

@GFauxPas: Math is totally cumulative.

@TedShifrin If I deviate from the other course (in the absence of a syllabus) I'll be sure to grade in a way that makes it fair.

$L(x+y)=3\cdot (x+y)$

You're well aware of this after your experience this semester, but it's a matter of what their background is, what the goals of the course are, and what it's supposed to prepare them to do.

Good, @Jon. And $3(x+y)$ can be rewritten how?

I might give out a survey the first day.

I think a lot of them might be econ majors from what a friend of mine who taught this course 2 years ago told me

Oh, so this is a particular service course, not the general linear algebra course, @Antonios?

no no, the problem is that it IS the general lin alg. course

You could start with the catalog description and how it relates to other (similar?) courses.

Oh.

so there will be math majors, physics majors, econ majors

You can say $L(x) + L(y) = 3(x) + 3(y)$ so $v_1 = x, v_2 = y$?

so I think I'll try to send out an email survey as to peoples' majors and so on

Right, @Jon. If your definition you're supposed to check says $L(v_1+v_2) = L(v_1)+L(v_2)$, there the $v_1$ and $v_2$ are two different vectors. Nothing to do with coordinates. This is the confusion I was talking about before.

@TedShifrin So, that class was 2 and a half hours a day, every weekday. We had a break, I imagine some number of people got on their phones, though I don't think Laci especially cared. At least it was a chance to stretch

The course description "Systems of linear equations, Gaussian elimination, matrices, determinants, Cramer's rule. Vectors, vector spaces, basis and dimension, linear transformations. Eigenvalues, eigenvectors, and quadratic forms."

Yeah, Demonark. Totally.

@Antonios: So I'm surmising it's minimally proof-oriented. Probably a book like little Strang. Although with Courant, who knows ...

I might try and write lecture notes more tailored to the course during June.

Besides, Demonark, mine is only one day a week :P

(it starts in july)

Don't work so hard, @Antonios. You're not being paid to do all that, and it's way more time consuming. Just use a reasonable book.

yeah, maybe so.

Yeah that's fair. Our class was only 5 weeks then

I just know I hated the book we used for this course when I was in that position.

mhhhhh.....

Plus exercises ... For linear algebra, it takes time to make up problems where the numbers aren't horrid. (Feel free to steal more from me if you want, @Antonios. :))

What book did you use?

hehe I might just have to.

amazon.com/…

Linear Algebra With Applications 7th Edition by Steven J.Leon

The AoPS linear algebra I'm teaching drives me nuts. They make no efforts to avoid horrendous arithmetic. Why not make the numbers in lecture come out reasonable?

Yeah that's awful lol

$200... Why?

Oh, @Antonios, I've never been fond of Lay. He hides all the geometry.

Leon is a standard book, too, @Jon.

Yeah that was my feeling too, @TedShifrin.

This class was the first one that got my into math actually, I had a graduate student instructor who explained it all in terms of geometry and it really made a lot of sense to me.

It was also the first time I did math that wasn't calc.

@Antonios: They couldn't consider my book because we didn't have enough differential equations stuff in there for the Berkeley curriculum. They didn't ask if we'd modify it ... But I think our book was too proof-oriented.

But the book did nothing for me.

I'm not fond of Lay, but his book is very popular.

Math 54 (i.e. that course) is just a row-reduction fest.

What is a standard book?

Yeah honestly linear algebra was also what got me into the subject as well, so I'd definitely put a lot of emphasis on making it a more interesting/inspiring class

yeah exactly @Daminark feels like paying it forward

I think students should learn to do row reduction (with reasonable numbers), but then feel free to use technology after that (except exams). The issue is to understand the concepts enough to know how to solve problems, not do mindless arithmetic.

Just remember the majority of your students aren't little yous or Demonarks.

They're not going anywhere near advanced math or grad school.

Leon, @Jon, and so is Lay.

yeah, it's sort of frustrating. Because of course I feel like making the course I would have wanted when I was in their position, but it's not what everyone wants.

And it's not what everyone needs.

This is why teaching is a challenge. If all students were isomorphic, it would be very simple.

loll

Yeah the tricky part is when the class is designed to be a service class of some sort, because then the actual practice of it may be kinda boring but at the same time, there will be complaints if you try to teach the class in a way that's more fun but doesn't get to the content that people need to see

of course the real problem is that most people want to slide by without much challenge

because the system only incentivizes good grades, not learning, which is not always the same thing

But undue challenge without any purpose doesn't work.

I'm not even completely sure how to strike the balance of interest and utility in those contexts at the moment

right

@Antonios-AlexandrosRobotis I'm slightly less than sympathetic to people who don't work

I assume that means you sympathize somewhat?

Like, of course don't be too hard

hi

That's why I always did plenty of applications even while I was trying to teach them to learn to write proofs. But that requires office hours to work with the students.

I had related to algorithms math.stackexchange.com/a/913529/200649.

As I said, even at Courant, don't assume your students are little yous and Demonarks. There might be a handful, but most are doing other things.

But I think there's a standard level of work where you can just say look, if you're not willing to put this much effort then take the crap grade and deal with it

How did he write We may use the division algorithm to write T=kC+r?

I think probably I want the class to be challenging, but in a stimulating way. We'll see if I can make it work that way, though.

@Ted How do you get good at advanced Linear Algebra.

@Jon I don't claim to be good at advanced linear algebra, but I think the most insightful thing for me in learning the subject is reading 3 different books bits at a time.

There are a few different perspectives you want to understand before you really start to see the bigger picture.

Honestly I might at some point learn some computer algorithms for matrix factorization, that could be an interesting balance of both being somewhat interesting and useful to know

The division algorithm says that you can do that with $0\le r<C$, @Abhishek. For example, you can divide $17$ by $7$ and get $17 = 2\times 7 + 3$.

@Daminark if I knew that stuff I'd be sure to teach it, but sadly I don't.

I have taught my self linear algebra first through a numerical analysis textbook then the Leon book is this the right way?

That seems to be the most important thing these days as well, lol.

I mean I don't either but I'm also at least a couple years away from teaching

That's important stuff, but probably beyond the scope of this course, @Antonios. That would tend to be in a second, applied course.

@Jon: What is your background and what is your goal?

Scientific Computing

is that the background or the goal :P

Data science

The goal

@Ted I'm not sure if you've ever taught that sort of thing but do you think students are interested in algorithm runtime?

@TedShifrin ok

That's in numerical analysis type courses, Demonark, not beginning linear algebra. Plenty of students are interested, but not in an introductory course.

I am still confused though. How does it apply in that case?

Background : just a student.

What do you mean, @AbhishekBhatia? It applies any time you have two integers.

With what math background, @Jon? Calculus? any proofs?

in the diagram what is the relation btw T and C to apply this theorem.

Hmm, if neither that nor the more geometric and/or algebraic content is there then I'm not really sure how to avoid making LA "the dreaded class" (before college I remember being told by some folk that it was one of those boring classes you just had to hold your nose and power through)

He explained the letters in the first sentence of the answer, @AbhishekBhatia.

@Daminark I think for me it was cool to see how you could interpret degeneracy of matrices and all that geometrically

that was what got me interested, like thinking of solutions of linear equations as geometric spaces

Yeah, just cranking solutions of systems of equations mindlessly is not the point.

one would hope not, because gaussian elimination could be taught to high-schoolers at a mechanical level

Math with cs concentration, and perhaps a master in a field of data science.

Wait, @Jon. You're majoring in math? How far have you gotten? I'm totally confused.

Maths with cs is not equal to data science I think it is mostly more statistics. Data science doesn't have theoretical cs.

I guess more like analyzing the time complexity in algorithms like insertion sort. I got one more year then I got my bachelors.

So, my first touch with LA was in the REU class I mentioned above. It started off with graph theory for a bit, then it did LA for about 3 weeks, then some stuff in the intersection. We didn't really emphasize things especially geometrically? Like we were emphasizing how you could go back and forth between linear maps and matrices, but a lot of our earlier proofs didn't necessarily restrict to R, we only talked about inner products much later, that sorta thing

One more year and you're just learning basic linear algebra stuff? Whoa.

Demonark: I object to that sort of linear algebra. I want dot product on day 2.

@TedShifrin so at that point, there just any two integers and he applied the theorem on them

Right.

the cool thing about inner products is generalizing all of the euclidean geometry imo haha

there is not much motivation to apply it at this point.

obviously you know I like algebra, but I think that the geometry of Linear algebra is much more interesting

But so much of linear algebra is about understanding orthogonality of various subspaces.

no geometry is like algebraic geometry :P

I have an MS in CS with conc. in ML.

@Antonios: Not for your students, but you should look at the exercises in the early sections of (either of) my book(s). Lots of that.

LA is quite helpful in ML.

@TedShifrin I will definitely haha, that stuff is great

@TedShifrin but orthogonality and inner product seem to be limited to $\Bbb R$ (and sometimes $\Bbb C$)

I kind of appreciated that somewhat. Like, there was some slight chaos at the beginning because we our professor didn't come until halfway through second week, so first week was graph theory with one of his grad students, and first two days of second week was with someone else

@Ted: Do you know where I should look to see formulas for $\Delta_A([\sigma, \psi])$ where $A$ is a connection and $\sigma, \psi$ are sections of a bundle of Lie algebras? I would guess that the usual slogan "products of harmonic functions are not usually harmonic" is true, but would like to understand it well.

I don't think you can generalize them to arbitrary fields

@Daminark my graph theory is pitifully bad actually

But first two days were just, what's a field, what's a vector space, what's a linear map, rank/kernel, that business

Leaky. I don't care.

@LeakyNun in fairness a lot of the interesting geometry happens in R and C. (though not all)

I have no idea @MikeM. How is the Laplacian intertwining with the Lie algebra structure?

But the two people had different working definitions. Our first guy defined the rank of a linear map to be the dimension of the image while our second guy defined the rank of a set of vectors to be the max number of linearly independent vectors

I've never once referred to rank of a set of vectors, Demonark. Ugh.

I don't like college too much it is too stressful.

Should respect the product structure in some sense. I have a slightly more special case in mind, where $A$ is a connection on a $G$-bundle $E$, and there is an induced connection on $\text{End}(E)$.

I want to learn but how about a bit slower?

Here I mean literally $E \otimes E^*$.

@AbhishekBhatia I sympathize.

data science thing is so vast.

Our existence is a stressful misery. You will never escape it, only accept it.