• You are currently viewing our forum as a guest, which gives you limited access to view most discussions and access our other features. By joining our free community, you will have access to additional post topics, communicate privately with other members (PM), view blogs, respond to polls, upload content, and access many other special features. Registration is fast, simple and absolutely free, so please join our community today! Just click here to register. You should turn your Ad Blocker off for this site or certain features may not work properly. If you have any problems with the registration process or your account login, please contact us by clicking here.

MBTIc Math thread

ygolo

My termites win
Joined
Aug 6, 2007
Messages
5,986
For Merkw, Urchun, nemo and other Mathmos....

What are some fascinating mathematical observations, theorems, conjectures and other things you've come across?

I've not gone too in-depth in too many sub-fileds but I find a lot of math facts fascinating.

Here is a short list:
1) The fact that there are many mathematical statements that are implicitly "undecidable."
2) The fact that group theory is so incredibly versatile at capturing symmetries in the universe.
3) The intimate connection between Gaussians and sinusoids.
4) The central limit theorem, linear regression and other reasons the Gaussian is so "natural"

I figure if one of us lists something another finds fascinating, we can take turns explaining (attempting to) them to each other, and or exploring the idea in depth when we find it fascinating but don't really understand it yet (most on my list are in the second category).

What do you say?
 

The_Liquid_Laser

Glowy Goopy Goodness
Joined
Jul 11, 2007
Messages
3,376
MBTI Type
ENTP
Heh mathematics is so vast I wonder how many topics will be brought up that most of the rest of us are not familiar with. For example I don't think I've ever encountered Gaussians (or if I have, then I have forgotten). Here are some things off the top of my head that I find interesting:

*Formally I believe that a set is defined to have cardinality Aleph1 if its cardinality is equivalent to the cardinality of the power set of Aleph0. I have seen it mentioned that the cardinality of the real numbers is Aleph1, but I don't think this has been proven. (Or if it has been proven I would like to know.)
*I find terms like real, irrational, and imaginary to be amusing. For example the real numbers have some features that seem unrealistic. Both the rationals and irrationals are dense within the real numbers, but the rationals have the same cardinality as the natural numbers, while the irrationals have the same cardinality as the real numbers.
*Fractals - I just think they are neat. They represent well ordered chaos to me.
*I've seen a hypercube which is an abstraction of a forth dimensional object, but I'd like to see more elaborate forth dimensional representations.
*I've found Flatlands to be an interesting book. It is a simple fictional book about how a three dimensional person would interact in a two dimensional world. It is implied that one can extrapolate how a forth dimensional object would be observed by three dimensional people.
 

ygolo

My termites win
Joined
Aug 6, 2007
Messages
5,986
Heh mathematics is so vast I wonder how many topics will be brought up that most of the rest of us are not familiar with. For example I don't think I've ever encountered Gaussians (or if I have, then I have forgotten).

I'm sure you've come across them.

Gaussians are often called "normal distributions" (though I usually reserve this for the mean=0, std. dev.=1 Gausssian of 1 dimension) or "the bell-curve."

Gauss may is one of the greatest mathematicians to ever live (Euclid and Euler may be the only ones more influential). So I like calling the curves Gaussians.


Here are some things off the top of my head that I find interesting:

*Formally I believe that a set is defined to have cardinality Aleph1 if its cardinality is equivalent to the cardinality of the power set of Aleph0. I have seen it mentioned that the cardinality of the real numbers is Aleph1, but I don't think this has been proven. (Or if it has been proven I would like to know.)

This wikipedia article covers the Continuum hypothesis fairly well


*I find terms like real, irrational, and imaginary to be amusing. For example the real numbers have some features that seem unrealistic. Both the rationals and irrationals are dense within the real numbers, but the rationals have the same cardinality as the natural numbers, while the irrationals have the same cardinality as the real numbers.

I always found these things pretty cool. There was a puzzle about getting out of hell some day by guessing the pair of numbers the devil was thinking about. It's rather simple, but it proved that this set (a pair of integers) is countable (and therefore had the same cardinality as the numbers used to count) . Of course, it is a short hop to rationals being countable.

The matching of real-numbers to irrationals is a bit less obvious, but the cut Dedekind cut formulation of rational numbers seems to make it pretty clear.

The "real" numbers have quite a bit more application that the integers or rationals, since most sciences assume a continuum (at least at mid to large scales).

*Fractals - I just think they are neat. They represent well ordered chaos to me.
*I've seen a hypercube which is an abstraction of a forth dimensional object, but I'd like to see more elaborate forth dimensional representations.
*I've found Flatlands to be an interesting book. It is a simple fictional book about how a three dimensional person would interact in a two dimensional world. It is implied that one can extrapolate how a forth dimensional object would be observed by three dimensional people.

Keith Devlin should be name "math evangelist of the decade," imo. Your list seems like a list of the books he's written. :)
 

Urchin

New member
Joined
Sep 12, 2007
Messages
139
MBTI Type
INTP
Enneagram
5w6
I really like LeGrange's theorem and everything it implies, especially regarding groups of prime order. I think proofs by induction and proofs by contradiction are attractive.

Whenever I use the floor function, I feel dirty.
 

nemo

Active member
Joined
Jan 21, 2008
Messages
445
Enneagram
<3
I freeking love analysis and set theory. When I was a wee-lad taking algebra for the first time, I was completely appalled that a function was capable of taking a segment of the real line and mapping it to a curve that was longer than the original segment. Take, for instance, f(x) = 4/3*x. When x is between 0 and 3, the arc-length of the function is 5. How does it take something of length 3, and just by mapping points linearly, turn it into something of length 5 without ripping or taring anything?! Impossible!

Needless to say, when I finally got into an analysis course I was in heaven. And then Cantor's Diagonalization proof blew my mind.

The Banach-Tarski paradox is vaguely related, although even more absurd when you first hear about it.

Another oddity that freaks people out at parties is Gabriel's Horn, an object with finite volume but infinite surface area. Imagine: you can fill it full of paint, but never have enough paint to cover the surface! What's nice about this is it only takes knowledge of basic calculus to figure out, and if you're clever you can find the higher-dimensional variants as well.

A cool fact I proved accidentally while taking a number theory class is that the radius of the circle inscribed by any Pathagorean triangle is always an integer.

Actually, number theory might be my favorite subject of all within mathematics. I took my first class in it after about a year of grueling, highly-technical mathematics and physics courses. I described the sensation of being introduced to the subject for the first time to my friend (who's an astronomy major) to be akin to studying astrophysics for an entire year, deep within a library, buried in a dizzying pile of books, and then walking outside for the first time and seeing the stars again. That sort of simple beauty is greatly enhanced once you've been exposed to how enormously complicated life is.

My other love within math is dynamics and probability, which is probably what I'd go into if I went to graduate school. There's immensely interesting overlaps in the theory of zeta functions, spectral theory, ergodic theory, and dynamical systems, which all sort of tie together my interests in number theory, dynamics, and probability; although I admittedly am mostly ignorant of what they are, exactly.

I haven't taken abstract algebra or complex analysis yet, but my advisor says I'll love them. I've read a great deal about both topics, but I've been too busy lately to self-educate myself much. How have you guys liked those courses?
 

ygolo

My termites win
Joined
Aug 6, 2007
Messages
5,986
I really like LeGrange's theorem and everything it implies

That's on my short list of favorite theorems, if not at the top.


I haven't taken abstract algebra or complex analysis yet, but my advisor says I'll love them. I've read a great deal about both topics, but I've been too busy lately to self-educate myself much. How have you guys liked those courses?

Complex analysis is like real analysis but confined to R2 and making specific use of the definitions of e and i. Should be fun for you. I never took a real analysis class (advanced calc. and complex analysis were the closest I got) because I was Discrete Math major. I bought a couple of Real Analysis and Topology books later, but I haven't gotten around to reading them yet.

After spending that much time in analysis-land, abstract algebra will be a cake-walk for you. It is a lot of fun too, a lot of applications to number theory (and to seemingly every branch of mathematics).

I got math as an auxiliary degree while focusing on computer engineering. So I missed out on a lot of the analysis classes. Part of me wants to go back to school for a math degree focused on analysis.

I especially want to cover some heavy-duty set theory, topology, real analysis and measure theory.

Another part of me want to go back and study non-linear dynamics, chaos theory, catastrophe theory and the like. After spending time as an EE masters and all the assumptions of linear dynamics, I can't help but wonder how the non-linear world is described.
 

Urchin

New member
Joined
Sep 12, 2007
Messages
139
MBTI Type
INTP
Enneagram
5w6
After spending that much time in analysis-land, abstract algebra will be a cake-walk for you. It is a lot of fun too, a lot of applications to number theory (and to seemingly every branch of mathematics).

I'm still in high school, but I worked most of the way through an abstract algebra book last year, and I'm working through real analysis now. I feel like I've got my brain half-dipped into something metaphisical when I understand a really abstract concept. There's nothing else like it.

I also did a tiny bit of number theory last year. I picked up most of what I learned to help with a problem I was trying to crack.
 

ygolo

My termites win
Joined
Aug 6, 2007
Messages
5,986
A cool fact I proved accidentally while taking a number theory class is that the radius of the circle inscribed by any Pathagorean triangle is always an integer.

I missed this on the first read.

Generating pythogorean triples in the usual way by setting m and n to relatively-prime naturals...

a=m^2-n^2, b=2mn, c=m^2+n^2,

and calculating the in-radius in the usual way ...

s=(a+b+c)/2=m^2+mn=m(m+n)
r^2=(s-a)(s-b)(s-c)/s=(n^2+mn)(m^2-mn)(mn-n^2)/[m(m+n)]=
(m^2n^4-m^4n^2-mn^5+m^3n^3)/[m(m+n)]=
[m^2n^2(n^2-m^2)-mn(n^2-m^2)]/[m(m+n)]=
[(m^2n^2-mn)(n^2-m^2)]/[m(m+n)]=
(mn^2-n)(n-m) which is an integer.


My way is inelegant as usual. It's been a while since I was a math major, but I think that could be made rigorous.

I'm sure yours was far more elegant, considering you did it by "accident."
 

nemo

Active member
Joined
Jan 21, 2008
Messages
445
Enneagram
<3
I missed this on the first read.

My way is inelegant as usual. It's been a while since I was a math major, but I think that could be made rigorous.

I'm sure yours was far more elegant, considering you did it by "accident."

Oh, I'm terrible. I can "see" a proof almost instantly, but to verbalize it I have to wrestle it out still bloody and kicking and screaming. It can take me weeks to write a proof for something I solved in 2 minutes.

Many of my other friends are much better at it than I am. I figured it was always an ENTP vs. INTx thing.
 

ygolo

My termites win
Joined
Aug 6, 2007
Messages
5,986
Oh, I'm terrible. I can "see" a proof almost instantly, but to verbalize it I have to wrestle it out still bloody and kicking and screaming. It can take me weeks to write a proof for something I solved in 2 minutes.

Many of my other friends are much better at it than I am. I figured it was always an ENTP vs. INTx thing.

I wonder if that is your Ne at work.

I was rather plodding. I would try hard to find counter examples of the theorem I was trying to prove almost immediately. As I kept failing, I tried to notice what was causing that failure and that is usually the crux of the proof I needed. Then I chose a proof strategy that are basic restatements/easy inferences/backward chains form hypotheses and and conclusion. Then I tried to link the "crux" to the two ends of the proof strategy.

If I started having trouble again, I used the source of my trouble to try to construct counter-examples again to what I was trying to prove. If the theorem is true, I would have further trouble constructing counter-examples, and would find another "crux" to the problem and try to link that in (perhaps reconsidering the proof strategy). I could continue like that for hours and hours.

Pretty pedantic huh?

I only immediately "saw" proofs for easy theorems. Of course the more math I know/remember, the easier the inferences/backward chains from the hypothesis/ conclusion was to come up with.

Like in the theorem you mentioned above. The pythogerean generator was a key fact, as was the formula for the in-radius. Those were just things I remembered. I would have been hard-pressed to notice the patterns needed from attempted counter examples to solve that problem through my usual grind.
 

Urchin

New member
Joined
Sep 12, 2007
Messages
139
MBTI Type
INTP
Enneagram
5w6
When writing a proof, I look at the assumptions and try to figure out what they imply. I then look at the conjecture and figure out what would imply it. I try to step inward from either end until I figure out what the linchpin of the proof will be (or the crux as ygolo said). Once I've done that, I pick a method, work from assumptions to linchpin, and then the rest sort of topples into place (hopefully). It's the first parts that are difficult. Sometimes I play a bit with the assumptions, but I try to keep it abstract and avoid playing with specific cases.
 

The_Liquid_Laser

Glowy Goopy Goodness
Joined
Jul 11, 2007
Messages
3,376
MBTI Type
ENTP
Generally when I prove something first I have to believe it is true (working examples and whatnot). Once I convince myself then I try to understand what the statement is saying as completely and simply as possible. I think of the first step and the last step, and then the middle steps tend to come to me all at once (or at least in large chunks).
 

ygolo

My termites win
Joined
Aug 6, 2007
Messages
5,986
How could I neglect linear algebra?

I am absolutely fascinated by Singular Value Decomposition.

Eigenvalue decomposition was interesting, but nothing compared to the power and universality of the SVD.

It is absolutely vital for signal processing and information recovery.

Any favorite theorems in particular, for analysis, topology, or various other branches of math? LaGrange's Theorem (which Urchin mentioned) is my favorite group theory theorem.

Stone-Weierstrass theorem may be my favorite result from analysis, but I haven't studied enough to have a deep understanding of it.

I suppose, by now, you can tell I am more an applied math type.

I haven't studied enough topology to pick a favorite but Baire category theorem fascinates me, though I have close to zero understanding of why that is true.

nemo, do you have any clear picture/understanding of Stone-Weierstrass or the Baire Category theorems?
 

Urchin

New member
Joined
Sep 12, 2007
Messages
139
MBTI Type
INTP
Enneagram
5w6
This is part of the magic of my childhood. I know it's long, but I promise that it's worth watching.
 

Nadir

Enigma
Joined
Dec 17, 2007
Messages
544
MBTI Type
INxJ
Enneagram
4
This is part of the magic of my childhood. I know it's long, but I promise that it's worth watching.

Thanks for sharing, it is nice.
I like math, but it is always less interesting and engaging to me during the actual, step-by-step functional analysis. (Though I should clarify that I haven't played around with this sphere-warping, topology stuff yet) It's probably because the numbers in any given exercise all exist in a vacuum, and do not really have a point beyond the exercise itself (wonders of high school, I guess). I'm looking forward to a time where they have some other, more tangible significance.
And before anyone asks, yeah, I'm not perfect at maths, though I get by. Blame this disinterest!
 
Last edited:

Nocapszy

no clinkz 'til brooklyn
Joined
Jun 29, 2007
Messages
4,517
MBTI Type
ENTP
Here's a question. I couldn't think of any place more appropriate than here.

I'm not sure of the answer (partly why I'm asking here) but I think I know.

If you can use the numbers 1 2 and 3 in any combination you want, and you're allowed to use any of the 3 as many times as you want, how many sets of three can you get?

I think it's just 3^3 = 27, but I'm not sure. I can't think right now.
 

Urchin

New member
Joined
Sep 12, 2007
Messages
139
MBTI Type
INTP
Enneagram
5w6
Here's a question. I couldn't think of any place more appropriate than here.

I'm not sure of the answer (partly why I'm asking here) but I think I know.

If you can use the numbers 1 2 and 3 in any combination you want, and you're allowed to use any of the 3 as many times as you want, how many sets of three can you get?

I think it's just 3^3 = 27, but I'm not sure. I can't think right now.

Does order matter? If so, it's 27. If not, it's 10. The way I did it was kind of a hack, because there are so few possibilities. I'm sure there's a better way to do it than simply counting them, but I'm not well-versed in probability, and this gets the job done. I guess you could make a tree diagram. That's kind of what I did in my head.
 

Nocapszy

no clinkz 'til brooklyn
Joined
Jun 29, 2007
Messages
4,517
MBTI Type
ENTP
Order does not matter. It can be 123, or 333 or 312 or 223... doesn't matter. You can use any of the three numbers as many times as you want to create as many sets of 3 as possible.

The way I did it was, I thought, to create an actual cube.

Bottom later would look like this
Code:
111
222
333
Next layer should have the similar digits along the opposite axis
Code:
321
321
321
then the top layer would have a sort of a rolling thing going
Code:
123
312
231

And then you can take that, and anywhere you find yourself with 3 in a row, it's a possibility.

I'll see if I can actually put together a cube like this (in paint or IRL or something) and see if it works. Seems like it would 'cause there are 3 variables.
 

Nocapszy

no clinkz 'til brooklyn
Joined
Jun 29, 2007
Messages
4,517
MBTI Type
ENTP
Hmm.... I'm thinking that's not right now. I'm sure it can be turned into a cube, but I don't think that the model I gave is any good.
 

ygolo

My termites win
Joined
Aug 6, 2007
Messages
5,986
If I'm reading you correctly, it is a matter of combinatorics. I may have interpreted you incorrectly but I agree with Urchin.

Think of this way, you have 3 options for a shirt (first slot), 3 options for pants (second slot), and three options for a tie (third slot).

You have three independent choices and three things to choose from for each choice. So yes, it is 3^3.

But the order-independent version can be thought to be equivalent to the following:

You have a giant(infinite) vat of ping-pong balls numbered 1 to 3, and choose 3 ping pong balls from there. You subsequently forgot which order you chose them. How many distinguishable possibilities are there?

It is 10, like Urchin mentioned, but how do you do it more generally? With choosing r balls from n types of balls? That is an interesting question, imo.

The short answer is it is C(n+r-1,r), where C is the choose function.

I tried typing the "star" and "bar" explanation but I didn't like the formating.

So, here is a link.

Nocapszy, if you like these types of questions you'll like Discrete Math (which is the mathematics behind computer science).

The following source has explanations of the basics.
Discrete Math Project - Permutations with Repetition

Also note, that these basics come in four flavors:
1)permutations without replacement
2)combinations without replacement
3)permutations with replacement
4)combinations with replacement

You'll find that transforming your counting problem into one of these is the most likely source of answers. That along with generating functions will fulfill most people's combinatorics type questions.
 
Top