The Iron Man hyperspace formula really works (hypercube visualising, Euler's n-D polyhedron formula)
On the menu today are some very nice mathematical miracles clustered around the notion of mathematical higher-dimensional spaces, all tied together by the powers of (x+2). Very mysterious :) Some things to look forward to: The counterparts of Euler's polyhedron formula in all dimensions, a great mathematical moment in the movie Iron man 2, making proper sense of hupercubes, higher-dimensional shadow play and a pile of pretty proofs.
00:00 Intro
01:17 Chapter 1: Iron man
06:05 Chapter 2: Towel man
11:16 Cauchy's proof of Euler's polyhedron formula
17:37 Chapter 3: Beard man
22:16 Tristans proof that (x+2)^n works
26:16 Chapter 4: No man
28:52 Shadows of spinning cubes animation
28:42 Thanks
Here is a link to a zip file with the Mathematica notebooks for creating the cube and hypercube shadows that I discuss at the end of the video in chapter 4.
www.qedcat.com/cube_hypercube...
If you don't have Mathematica, you can have a look at pdf versions of the programs that are also part of the zip archive or you can use the free CDF player to open the cdf versions of the notebooks.
Something I forgot to mention: There is also another purely algebraic incarnations of this process of growing the cubes. It comes in the form of a recursion formula that connects the different numbers of bits and pieces in consecutive dimensions. That recursion formula is also present at the bottom of the "iron man page". Have a close look :) Also, in the Marvel movies the cube that Tony Stark is holding in the thumbnail of this video is called the Tesseract. Probably worth pointing out that "tesseract" is another name for a 4-d cube. I also built an easter egg into the thumbnail that plays on this fact:
imgur.com/a/psIy28k
The formulae for n-d tetrahedra and octahedra can be found on this page;
people.math.osu.edu/fiedorowi...
Here is a link to my video on solving the 4d Hyper Rubik's Cube
• Cracking the 4D Rubik'...
Another proof of Moessner for cubes using cubical shells Anthony Harradine and Anita Ponsaing
www.qedcat.com/StrikeMeOut.pdf
Here is a really nice video on the 120-cell that I only mentioned in passing.
• 120-cell
Noteworthy from the comments:
Today's video was "triggered" by a comment made by Godfrey Pigott on the last video on Moessner's miracle in which he pointed out that (x+2)^n captures the vital statistics of the n-dimensional cube.
Z. Michael Gehlke There is an easy way to see this: (x^1 + 2*x^0) describes the parts of a line; all of the cubes are iterated products of lines: n-cube = (1-cube)^n. Therefore, all cubes are described by iterated powers of (x^1 + 2*x^0)^n. (Me: Nice insight. Of course needs some fleshing out to make this work on it's own, like in the comment by ...
HEHEHE I AM A SUPAHSTAR SAGA I came up with an even simpler visual proof. Take a cube of side length x+2. This cube has a volume (x+2)^3. Now, slice the cube six times. Each slicing plane is parallel to a face and 1 unit deeper than the face. Don't throw away any volume. What you're left with is an inner cube of side length x (volume x^3), 6 square pieces of volume x^2, 12 edge pieces of volume x, and 8 corner cubes with volume 1 each. Adding up these volumes gives you the original (x+2)^3 volume, so it's proven. This works in any dimension.
Here is a link to an animation of this idea that I put on Mathologer 2, as a reward to those of you who who are keen enough to actually read these descriptions. • 3rd proof that the coe...
Typo: The numbers of vertices and faces of the dodecahedron got switched.
Today's music is Floating Branch by Muted.
Enjoy!
Burkard
German mathematician: "Here's another kitten, in a cube. Very cute. Feeling revived?" Quantum mechanics students: "NO ERWIN, PLEASE, NOT AGAIN!"
QM students : "Iron Man, please don't, we know your Erwin in disguise."
Kitten killing lessons were my favorite at math classes actually
@@sitter2207 ZAP THEM lol
love cats so a kitten is always good
@@francisgrizzlysmit4715 Same here. 😻
You have a gift for showing us what math is really about. It's pure amazement, wonder, curiosity and entertainment. Thank you for capturing the essence of math!
This!
I couldn't agree more, all I feel is amazement watching this
What are you sending to him that is so amazing, wonderful, curious, and entertaining?
Meanwhile school: a + b
As he hails satan with 6's.
You'll be pleased to find out (I hope) that the next video is already halfway finished. We are in lockdown again here in Melbourne and as a consequence I've got a bit more time to spend on Mathologer. COVID is not all bad :) Update: I just decided to run an experiment. Went with a descriptive title and thumbnail for a day and a half and now switched to a more clickbaity title and thumbnail. Will be interesting what happens (if anything :)
Love❤❤❤ u sir.Stay safe. Pls make video on Collatz Conjecture.
Do we get a hint of what the next video is about? :)
I still strongly support the Victorian Government and Health team. The other day I heard someone calling them "tyrants", but I think he has no clue. Real tyrants like Bolsonaro let their people die, simply because they consider them inferior to themselves.
Covid tyranny is all bad though!
@@WillToWinvlog Are you violating the rules? You are just prolonging it, you doof!
"And mathematicians wonder why people think they're weird." My mother was a singer, actress, secretary, homemaker, and social butterfly. NOT a math person (that was my dad). One day, I was trying to explain a math problem to her and I needed to pick a small number to use in a simple example. So I said "How about 1?", and she starts laughing. "Why 1? It's so small! Why don't you pick a REAL number?" 😄
:)
At least she did not say something more complex.
Ok, honey. 1.0.
I'd tell her that in a sense the only Real number is 1 as all other numbers are derived solely from 1. Even the transcendentals are derived from 1, by some arbitrary methods. 2 is nothing but the successor of 1, and 0 is hence nothing but the precursor to 1. And the operations we've acquired from that is + and - as 1 + 1 = 2 and 1 - 1= 0. To derive × and ÷ one has to do more steps, but one can derive them as well, and you can do this to fit an arbitrary amount of operations.
@@livedandletdie Wasn't the basis for numbers the empty set, which we denoted as 0. And then 1 is the successor of 0, etc... It has been a few years ago so I might remember wrong,
Ah yes, my favorite mathematicians, iron man and towel man!
:)
Don't forget to bring a towel...
Every mathematician should be as well prepared for galaxy hitchhiking as Euler was.
@@Robert_McGarry_Poems 42
they have a fight triangle wins
15:52 "There's no hidden trickery" I'm not complaining, but I'd say that counting faces is quite tricky, as it relies on topology. To see when we're removing a face and when we're not, is visually obvious and yet non-trivial. And also one needs to be careful not to disconnect the network (as you said, "starting from the outside" should guarantee this).
Very good point. In fact, when you have a close look at what I do in the proof, you may come to the conclusion that the first post-network step of adding diagonals is not necessary at all for the proof to work. Just prune away and you eventually arrive at a single polygon to which V=E applies, and so the V-E+F=F=2 (the inside and the outside of this polygon). But the reason why we are inserting the diagonals is to get more control over what is happening in the proof. For example, it's easier to argue that we can always prune so that the network does not split in two if we are dealing with a network composed of triangles, rather than a completely general one.
@@Mathologer Thanks for the answer! I didn't think about it, but indeed, the exposition as it is already helps in bridging the gap.
Me: *takes out ring, proposes* GF: *says yes, crying* Me: *starts talking about the number of vertices on the diamond of the ring* GF: *takes off ring*
Another video of Mathologising beauty. The 4D cube rotating in space was a delight.
Yes. And it sort of hints at the 2-nested-tori nature of the hypersphere. Fred
@ss It was only the shadow and not the real one. ^^
Plus it’s only a 2D projection of a 3D shadow of a 4d object ! 😄
It’s amazing how algebra and geometry can be connected by such a pretty formula. And the derivation using recurrence is simple and… simply stunning.
I was really worried about the kitten trapped inside the hypercube, but then beard-man appeared and used his Shadow-Squish Super Power and saved the day! What a great story!
I think it was a hyper-kitten, but then all kittens are hyper. Puppies, too.
The entire video I was wondering what the 2 in the (x+2) formula was really referring to. Sooo satisfying to see the recurrence equation at 25:00, makes so much sense!
Finally a math topic I’ve never heard about! Thank you Mathologer, you’re great
Really loved this video thanks. Pascal's triangle is the gift that just keeps on giving. Although strictly speaking the rule here is: " *Twice* the number above left plus the number above right"
If instead of n-cubes, you look at n-tetrahedra, the number of vertices, edges, faces, etc. exactly match Pascal's triangle (with the last 1 in each row removed).
@@WarmongerGandhi is that (x+1)^n ? i think so, hey look i see how the binomial expansion correlates to the pascals triangle and NOW even the higher dimensional triangles.
The video ended smoothly and the resding our minds at the boring part with a bitter sweet picture of a cat made the end a refreshing end for the video with that music making it happy and giving us a refeshed experience.
Tristan's proof is exactly multiplying by x+2. Wonderful. I wonder if there's a link between these generating functions and the genus of the figure they define.
Love your stuff and how much fun you seem to have presenting it....I get lost pretty easily because I'm old but enjoy the journey....anxious to see what you have up your towel next
My favorite channel strikes again! I've been going through the Mathologer backlog, waiting patiently
Es un placer ver, escuchar y entender! Muy bien logrado Mathloger! 👍 Esperamos el próximo. 😀
Amazing stuff as usual!! Thanks Mathologer :) Especially the spinning projections in 29:06 completely blew my brain up. I think it's because we're so used to interpreting overlapping lines on a 2D plane (on the page) as faux-3D objects, that interpreting them as just what they are (lines) when they move around basically short-circuits my brain.. once again, well done Burkardt :D
Great video! Lots of other KZheadrs might have stopped after giving one explanation but you really went the extra mile with the animations and multiple proofs. Thank you for sharing this with us!
"I'd like to finish off the video" he says roughly half way through the video...
Thank you, Mr. Mathologer. You explain the geometric meaning of mathematical formula precisely. We are happy to see more.
I love your approach to math. You take such complicated topics and make them so intuitive and easy to understand conceptually. I love you :D
Thank you for this, this answered and sufficiently explained questions about extra dimensions I didn’t quite know to ask yet but had visualized in my head all this time. Pretty beautiful
The animation at the end is a thing of beauty. It lets me intuitively understand what it means. Thank you.
Thank you. Your work is reaching into the future. My students LOVE watching your videos even if they just grasp the very edges of what you're talking about. They continue to think about your videos long after they have watched them. Thank you to you and all your team. Please keep up these great works!
What a nice surprise! I've been hoping you would release another video soon!
My God that was mindblowing, this channel has me obsessed!!! Everytime I watch a Mathologder video, I can't wait to explain it to everyone I know (though they aren't math nerds like me :D)
Love the higher dimensional and geometry based videos!! Very inspiring and helpful!
WOW, very inspiring. Easy to understand. TOP animations. Thank you!
Im always fascinated by your discussion of proofs!
This video has made me understand the visual used to describe a tesseract even if it isn't what a 4th dimensional object would truly look like. Thank you!
Great work as always. I hope you will show us the astonishing beauty of math for years
I reckon the Iron Man title is more enticing than the +/- title. I had not cheched the video before, seemed such a dense, intimidating subject. Now it's like discovering an easter egg of the MCU, seems worth enduring the hard maths somehow.
That animation of the rotating 3D and 4D cubes was very illuminating. Thank you for doing these videos.
Very satisfying and beautiful! btw, I love binge-watching your videos:)
Beautiful stuff Mathologer!
I studied maths for six years after my high school degree and, still, I learned so much in this video! Thank you Mathologer for all the wanders you bring us. :)
Wow! Which degree did you get at high school?
@@ainsworth501 I got the degree called Baccalauréat which is what you get the year you turn 18 in France. I don't know what the equivalent is in other countries.
Amazing class!!!!!!!! Unforgetable! (and the final music is chilling:)
Woot woot, tidying up my list of things to watch before the year is done!
I love this guy! Keep 'em coming!
10:12 just out of curiosity, how do we differentiate between higher dimension convex and concave polyhedra??
A shape is convex if, given any two of its points the line segment connecting the two points is fully contained in the shape. This definition of convex works in all dimensions :)
@@Mathologer Well, assuming being on the boundary counts as being “inside” the shape. :)
@@Mathologer what an elegant definition! So simple, yet bulletproof.
Although technically, Euler's polyhedron formula also works perfectly for non-convex (concave) polyhedra, as long as they don't have any holes.
You do need a notion of "inside" of the shape, which is uncontroversial but does rely on some other theorems. Every simple closed (hyper)surface embedded in R^n partitions the space into three connected components: the surface itself, a bounded component called the interior, and an unbounded component called the exterior. This is a consequence of the Jordan-Brouwer separation theorem. So then we can say that a polytope is convex if it is simple and every line segment connecting two endpoints in its interior lies entirely in the interior (i.e. every point in the line segment is in the interior of the polytope).
That was amazing. Wow! My mind is blown! The feelings & emotions I am experiencing is indescribable.
Amazing video, resparked my interest in higher dimensions and got me researching again!
Oh my god, just yesterday I was wondering exactly about that: how many "elements" (vertices, edges, ...) do n-dimensional cubes have! And now you made a video on it!
Wow!! I derived this amazing formula years ago but it never occurred it could be obtained by a generating polynomial. :O Thank you as always to the Mathologer team! Fun facts: the dimension, m of the most numerous bits of an n-cube converges to n/3 as n increases. This can be shown by setting the derivative of 2^(n-m)*(n choose m) wrt to m equal to zero, while using the derivative of f(m)^g(m) and Sterling’s approximation. For a large n, we get a bell shaped curve presumably due to the DeMoivre-Laplace Theorem.
The video was interesting as usual. And then you conjured Euler's formula out of thin air! Wow!!
this is the most beautiful video I have ever seen and felt
I just love this channel and the way things are shown, and I also really like the shirts, this one from Space Invaders is really cool, especially because I'm from the oldies and I love this game!!! congratulations for this beautiful educational channel!!!
Incredible as Always!
The most beautiful math video I have seen in the web ! Thank you ! Thank you ! Thank you ! 😀
Always excited for a new Mathologer video! I especially enjoyed the final animation (not counting the closing credits!) of the spinning 4d cube. It helped to conceptualise the otherwise imperceptible nature of the hypercube. Hope you and family are well and flourishing in the current lockdown. Otherwise come back to South Australia where the total # of covid cases have jiggled between 2 and 4, over the past few weeks! 😎
Fantastic! I have had so much fun over the last couple years telling my students, "maths is broken". I often show your videos to help create that bigger picture feeling about math.
Every video is beautiful miracle. Thank you The Kind Mathgician ))
2:43 you enlightened me. This is probably the first time I can truly visualise an hypercube. It has as faces ... 8 cubes in 8 parallel 3d universes, and they are crossing 2 by 2 on 3d cubes, and 3 by 3 on lines ...This formula is soo visual !!!
Very nice as always!
I thought of a 3d version of your 3d polyhedron formula proof before it was mentioned. I'm slightly proud that it's an actual proof and not just something I initially thought *could* work.
Just wanted to say this is one of the most interesting and entertaining channel I'm following. Each video brings out my curiosity and a smile on my face. Thank you! And as for this specific video I happen to have a copy of the book "Euler's gem" on my nightstand, a real spoiler 😆
Yes, a great book :)
Amazing video SIR!!!🙏🙏🙏 ...as always inspirational ...
Another great video! Thank you. BTW that rotating hypercube at the end is a torus whose surface rotates around the poloidal axis while remaining fixed on the toroidal axis. An interesting video would show rotations about both axes simultaneously.
woah, it's not often that i upvote a 30 minute video in the first minute, but that cube thing is just too cool!
thank you. i actually wondered the same question many years ago and ended up using similar techniques to figure out how many m-dim 'objects' in a n-dim hypercube. and then i proceeded onto simplexes as well as cross-polytopes. re-inventing the wheels, i know. but the feeling of figuring out all of those things by myself is still one of my most precious moments.
The video was on point! You've not lost your edge. Let's face it, the video was excellent.
One of the most beautiful videos i have ever seen
Lieber Professor Polster, ich habe noch nicht das Video bis zum Hälfte gesehen, aber schon hat das Video ein LIKE von mir verdient. Herzlichen Glückwünschen.
Always LOVE Your stuff..!!!
Thank you for uploading such beautiful videos on mathematics sir, it really helps to understand the beauty of studing such a fascinating subject which is considered dull otherwise.(by many)
I have no words. Fantastic stuff! Love seeing all the connections. Ah, I guess I did have some words after all :P
If mathematics is one side of the video, the music is the other. Thank you for both astonishing mathematic topic and making me discover so great music.
Just in case you are interested today's music is Floating Branch by Muted.
I'm one of your student in the class of the nature and beauty of mathematics at monash university, i really love your teaching style and i review your videos from KZhead channel quite often. Thanks a lot for showing me how beautiful that math can be.
This is astounding, the tying together of something so prosaic as (x+2)^3 to a deep understanding of multidimensional cubes. Plus kittens.
at the end when you started rotating the shapes, the projected 3D shape looks 3d in the shadow because we are viewing it on a 2d screen, that really made the 4D projection click for me. Great work!
The music in this video is great, and also the video is great.
Today's music is Floating Branch by Muted
God these videos are still great. You're still the best mathematician on youtube, in my opinion!
Very cool (as usual). It would be interesting to see this concept transforming from the discrete to the continuous by comparing/contrasting hypercubes with hyperspheres.
A stunner as always! I’m still waiting for the Abel Ruffini proof to get the mathologer treatment someday :)
Been Watching You Forever, as a Mathematician; You Are My Favorite One On The "Tube" ~
That's great :)
Haven't even watched yet, but when YT showed me a brand NEW Mathologer vid, I immediately smiled.
Damn straight! : ) ... I was at my kids' competition, so couldn't watch immediately.... but a new Mathologer vid is the perfect cherry on top
Absolutely fantastic!
Very nice animation at the end
Ah, nerts. Still over my head. Videos like this make me WANT to learn more advanced math, though! Thank you for sharing your insights, and thank you even more for sharing your unmistakable and infectious love of the subject! We’re so very fortunate to have people like you, OC Tutor, 3blue1brown, etc who create amazing content which inspires curiosity and imparts knowledge (for free, at that) to anyone who seeks it. Imagine what Euler, Gauss, or Newton could have done with so powerful a means of communication!
I remember going through a full and rigorous proof of the euler characteristic formula in graph theory, and all I recall was it being quite a doozy! Enjoyed your mathologerized version very much.
Thanks🙏 man for such amazing stuff for students like us
Saw this video with the non marvel thumbnail a week ago and did a double take now, i love it!
This is a great introduction to generating functions.
I recently did another video featuring generating functions. If you have not seen it yet : kzhead.info/sun/ibCblbR_eYGMmJ8/bejne.html
@@Mathologer After your video I looked up generating functions and watched that video also. As a side note, even though high dimensional hypercubes may or may not be "real," they have real use in communications theory. For example, see Hamming distance. Furthermore, to optimize the probability of communicating a sequence of symbols without error, one performs sphere packing in high dimensional spaces to separate encoded symbols so that error is minimally likely to confuse two symbols. This takes advantage of the fact that in high dimensional space, most of the "volume" is near the "surface" of a polytope. See "asymptotic equipartition property." Anyways, your videos are entertaining, insightful, and fun as always!
It would have been nice to have had this resource when I was a child. My mind could have handled it. But now is all gibberish. Thanks for trying to make this simple and accessible for people.
Watching your videos always pleasure for me.....I really really like your small laughing :) !!!!!
I really like spinning shadow of 3D cube over 2D plane at the end. Really well made to be seen as "parallel" to 4D animation.
I would love to see a video on the Road Coloring Problem! (Great work with this one, by the way)
Never heard of that one. Very interesting concept. Also just had a look at the proof. Doable :)
No commercials - You are my hero.
"How satisfying was that?" .... Very! That was such a perfect full-circle moment!
Just finished watching your quadratic reciprocity video......what a treat. I am a little amateur in mathematics..... would look forward to your video on permutations as you had mentioned there ...it would definitely help in appreciating the complete beauty of the proof (not sure if it's published already)...also sorry for posting unrelated topics to this video.... just wanted to post on an active thread.
Well that was a another truly magical journey in to the beauty of Math
That spinning tesseract (?) at the end just broke my mind! God damn.
Another excellent video.
papa flammy pog
Immer einer der ersten :)
Erinnere mich daran - wie war dein ursprünglicher Kanalname?
@@Mathologer Na aber natürlich :)
@@godfreypigott :^)
The g-conjecture is so cool!
Well, that was exiting. Thank you for providing new videos. This one reminded me at another aspect of Eulers formula: Graph duality demonstrated e.g. by "Euler's Formula and Graph Duality" (3Blue1Brown). We'd love you to talk more (as you indicated) about 'meta-cubes'...
Glad you liked it. This site has the formulae for the n-d simplex and the n-d orthoplex :) people.math.osu.edu/fiedorowicz.1/math655/HyperEuler.html
These geometry videos are always so enjoyable :) Even when the subject is something I thought I understood reasonably well in uni, the videos always help to make it more intuitive instead of just being an algebraic truth. I really hope one day I'll get to see mathologerised versions of Lie groups/algebra. Like it's one thing to sit down and work out that SU(2) and SO(3) algebras are isomorphic but there *ought* to be a way that that's visual right? Given how visual SU(2) and SO(3) are...
Lie algebras and groups are some of favourite playthings. Eventually there may be a video...
That is so elegant!