I think my favorite Johnson solid has to be the Snub Disphenoid. The idea that a "digon" (line) has a use case at all as a polygon, despite being degenerate, is just so funny to me.
yes! i get a weird sense of joy using degenerate cases in math, such as for example, 0! = 1actually being intuitive if you think about it, there really is exactly one way to arrange 0 items in a line on your desk after all.
Son: "dad, why is Daisy called like that?" Dad: "because you mother really loves daisys" Son: "i love you dad" Dad: "i love you too Great Rhombicosidodecahedeon III"
Dad, why is Daisy called like that? Because when she was young a daisy fell on her head. And how did you come up with my name? No further questions whilst I'm reading, brick.
I can't describe my panic at the Dungeons & Dragons table looking at my dice and realizing that there were so few regular platonic solids. I bothered my DM about it for weeks. And then finally I saw in a video showed there are very many regular platonic solids as long as you don't care what space looks like, and that put my mind at ease. A good collection of *almost* regular objects is going to seriously put my mind at ease. I should make plush versions of these solids to throw around during other hair pulling math moments. Yeah this is really giving context to the wikipedia deep dive I tried to do. Lots of pretty pictures but they didn't make sense until you showed the animations.
If you want more dice, the catalan solids all make nice fair dice. The disdyakis tricontrahedron makes a particularly great dice, with 120 sides you can replicate any "standard" single dice roll by just dividing the result, since 4,6,8,10,12,20 are all factors of 120.
Plush solids would be so cute! Might want to use mid- to heavy-weight interfacing on the faces so they don't all turn into puffy balls when stuffed with polyfill… although that could be cute, too, especially if you marked the edges somehow, e.g. by sewing on some contrasting ribbon or cord (you could ignore this step or use different colors for the adjacent faces). Now I want to make some 😂 I sewed some plushie ice cream cones recently and have been itching to make more cute things.
I just started watching this channel and I love how you can visualize and explain all this information in a way that is easy to understand. Great video! 😁
rhombic dodecahedron is my favorite among all these guys. i like how unfamiliar it looks even though it has cubic symmetry. and its 4d analogue, the 24 cell, is completely regular! i wish i could look at it, its beautiful
Incredible video, great work on it all! A lot of new names for solids I never knew before A giant grid of all of the solids as a flowchart of different operations to get to them would be a hella cool poster tbh
I had a weird math panic attack when I learned there weren't more platonic solids and that Jan Miseli video really put my mind at ease, and then went even farther and blew my mind a few times. Great video. And his stuff on constructed languages has taught me so much about linguistics that just keeps coming up in my regular language study, it's awesome. Love that guy.
if you take the deltoidal hexecontahedron. and force the kite faces to be rhombi, you get a concave solid called the rhombic hexecontahedron, and it is my favorite polyhedron
this is fast becoming my favorite video on youtube. i'm so happy to see that there are other people out there who care this much about polyhedra. the disdyakis triacontahedron is also my favorite, it's like a highly composite solid! just as 120 is highly composite! this is closely followed by the rhombic dodecahedron (because it's like the hexagon of solids!) and then the rhombic triacontahedron. this video has taught me so much, like how snubs work, and the beautiful relationship between the archimedean and catalan solids. not to mention half triakis (i had always wondered how someone could think up something as complex as the pentagonal hexacontahedron.) and johnson solids! i hadn't even heard of them before this video! thanks for educating, entertaining, and inspiring me! i'm so glad i stumbled across this. 120/12, would recommend
A few years ago I was very intrigued about a very similar thing, but with tetrominoes, aka tetris pieces. It's well know that there's only 5 ways to connect 4 squares on a plane, with 2 of them being chiral, hence the 7 tetris pieces we all know, but once you start to dig deeper you start to have so many questions. What about 5 squares? 6 squares? 7? What about other shapes, like triangles? Or maybe cubes in 3D, aka tetracubes? What if you keep only squares, but allow them to go in 3 dimensions (they are called Polyominoids)? Turns out there's lots of ways one could extend the idea of tetrominos, by either using different shapes, getting into higher dimensions or simply changing the rules of how shapes are allowed to connect.
I've been interested in that also! Not counting reflections, there are 12 pentominoes, and it's a classic puzzle to arrange them into a rectangle. You can actually make 4 different types of rectangle, 3x20, 4x15, 5x12, and 6x10.
Thanks! Great video. Have you ever looked at the geometric net of these kinds of solid. I know the cube has 11 possible nets. I would like to see a video that dives into the possible nets of some of the other shapes as well.
Thank you so much! I do have some degree of experience with the nets of the catalan and archimedean solids after making them all out of paper. Some of them I even modified to fit better on 1 piece of paper!
my favourite solid has always been the truncated octahedron because it evenly tiles space with itself, and it has the highest volume-to-surface-area ratio of any single shape that does so. its the best single space filling polyhedra! if you were to pack spheres as efficiently as possible in 3d space, and then inflate them evenly to fill in the gaps, you get the truncated octahedron
I dont think thats quiet true. The shape you get when inflating spheres is a rhombic dodecahedron. You can see this by looking at the number of faces. The truncated octahedron has 14 faces but a sphere only has 12 neighboring spheres.
Watching this for the 17th time. Thank you for getting this all this down into one video. I can tell you worked really hard to put all the faces together for this one. 🎉
I saw descriptions about these solids at high school, and couldn't grasp many concepts yet getting really intrigued. Your explanation was excellent. Thank you sooooo much!!
Really fantastic video! You did a beautiful job with the visuals and in organizing the explanation. I have shown it to a wide range of viewers - from a 7 year old to a guy with a phd in math. Everyone loved it and had the same basic reaction - it was entrancing!
pentagonal hexecontahedron is clearly my favorite with it's "petal" sides if you consider 5 faces connected on their smallest angle, or heart shaped sides, if you only consider 2 faces
Wow, haven't seen so clean, concentrated and convenient explanation, without unnecessary effects it's even easier to understand. Your format is my favorite among others since I went in for geometry 11 years ago. My suggestion for next topic is "3D Honeycombs" because it's logical continuation of solids. There are "regular" ones which consist of the same solids you were talking about in this video. The particularly brilliant thing is there were found some irregular (!) 3D honeycombs. Most of them are of similar polyhedra, both convex and not. The only irregularity in them were the colors which cube faces had or something like this. But maybe there are some of them I missed which look like 3D version of Penrose tiling. Edit: Pentakis Dodecahedron is my favourite solid (the second one is Icosahedron) because it's one of the roundest solids which consists of equal polygons.
The Dice Lab is a company that makes some unusual ones. Their large set has a truncated tetrahedron, truncated octahedton, rhombic dodecahedron, deltoidal icosahedron, disdyakis dodecahedron, deltoidal hexecontahedron, and disdyakis triacontahedron.
I've been looking into these solids for years, but had no idea what the process of discovering them was. Half-truncation is one hell of a leap, especially for someone born a few thousand years too early for computers. It's amazing he found them all
The hebesphenorotunds (last one explained 27:03) looks really similar a gem-cut. Think about the side with the 3 pentagon down into the socket and the hexagon outside and visible.
My favourite catalan solid is the pentagonal hexacontahedron. I find it very pretty how the flower patterns with 5 petals interlock to make chiral corners at the boundary.
I love this video! I'm glad that I found your videos. I have a love for mathematics and geometry, and it's cool someone made a video about platonic-y solids! I liked the video "there are 48 regular polyhedra" by jan Misali and this is the type of stuff I like. I think you would like that video, too.
@@feelshowdy It's not 100% accurate, because not all of the Bejeweled gems are platonic or almost platonic solids of course, but I wanted to include all of them in the comment since they're all so equal to each other.
I watched this whole video and found at least five of my new favorite solids. They will never beat my favorite shape, the snub disphenoid! Also, please make a video on some of the near miss johnson solids.
I am a particular fan of the disdyakis triacontahedron because it is the largest roughly spherical face-transitive polyhedron, so it's the largest fair die that can be made (ignoring bipyramids and trapezohedrons)
Amazing video!!! Very in depth and yet easy to follow, I really enjoyed some of the smaller details like sphericity!! i look forward to your future uploads!!! -from another friend of Blahaj ;)
Your color choices for each polyhedron are lovely. This whole video tickles my brain wonderfully. I want a bunch of foam Catalan solids to just turn over in my hands.
I was expecting this to be like a reduced version of Jan Misali's video about the 48 regular polyhedra... what a fantastic surprise! I love geometry, those were some great explanations.
after watching jan Misali's platonic solids video and vsauce's strictly convex deltahedra video, seeing some concepts i got from there return here was nice and cool, like a callback from across my brain :3
This is the type of video I hope gets preserved after the internet gets destroyed or restricted or some great data loss happens within UA-cam’s servers
Thank you for such an interesting video. A lot of these I was hearing about for the first time and I found great joy in hearing you pronounce the name, getting surprised that this one is longer than the last one, and then laughing as I struggled to pronounce the name myself. My favorite was either the “Snub Dodecahedron” or the “Pentagonal Hexacontahedron”. The Snub Dodecahedron looks so satisfying having a thick border of triangles around the pentagon, but there was something about that Pentagonal Hexacontahedron that I found really pretty. I think it’s because of the rotational symmetry. Again, thank you for taking the time to make such interesting and engaging videos. I look forward to watching another one.
I LOVED this video!! I am a huge geometry nerd and learning about polyhedral families and the construction methods to generate new ones makes them all feel so intertwined and uniform. If I may request, please do a video on higher dimensional projections into the third dimension like fun cross sections of polytopes through various polyhedra. TYSM
There is another category of almost platonic solids where you only use property 1 and 2 and don't care about the verticies being identical. These are the triangular bipyramid, pentagonal bipyramid, snub disphenoid, triaugmented triangular prism and gyroelongated square bipyramid, otherwise known as the irregular deltahedra.
i'm honestly surprised that you've explained it this well, i was able to keep up pretty much the whole time,, i was so shocked that i could understand what was happening i want to commend you for the use of color coding for things like rotundas and cupolas, you've done an amazing job at making this more digestible and it was very helpful excellent job on the video, kuvina
Let's face it most underrated youtuber I have ever come across (is you)! Well done and Thank You, you are a wonderful edgeucator c: who always gets even very complicated points across, not to mention the volume of information in each video is enormous!
Just discovered your channel and am loving it. You are covering all my favourite topics. I personally find the Catalan solids more beautiful than the Archimedean ones.
This channel is going onto the list. Hopefully once this nightmare of a degree (math) is done I'll have time to get through these interesting videos/topics.
My favorite Catalan solid is the 30-sided rhombic polyhedron based on the Golden Ratio because I figured out how to make it in Sketchup. It is closely related to the icosahedron and dodecahedron.
If you're into Sketchup and geometry then you might find a few videos I've done on my channel to be interesting. Also, you guys know the Sketchup team does a livestream every Friday? Fun times..
Even as someone who knew where most of this was going in the first half, I didn't realize why you were delaying explaining the relationship between the cube, octahedron, and cuboctahedron until you started talking about duals.
And the real fun (and actual research) starts when you go to higher dimensions. The higher dimensional Archimedean solids are called uniform polytopes, and noone so far has been able to classify them. Same for edge-transitive polytopes. There are lists that are conjectured to be complete, but no one knows. Conway found a new uniform polytope in dimension 4 (the grand antiprism) which had to be added to the list, so no one knows whether there is not something else we have missed so far.
4:37 You can also make a rhombicuboctahedron by expanding a cube, which is done by moving the faces away from the centre and then connecting them with rectangles on the edges and whichever polygon is needed on the corners. The same can be done but by rotating each face and connecting them with triangles instead of rectangles to make a snub cube
This UA-cam video has earned a spot in my all-time top 100, and definitely on the upper end of that 100. I’ve been watching YT since 2007. You’re seriously underrated, so if it helps, you’ve earned a new subscriber.
I'd love to see a video about tessellation of 3D space with golden rhombohedrons and what they build (such as the rhombic triacontehedron) and then combine that in the same video with looking at the dual polyhedra of the various related solids using the icosadodecahedron as the glue that fits the whole picture together. Quasicrystals are something a lot of people are interested in and these relationships are critical to quasicrystals because of the 5-fold symmetry (ie the golden ratio) and space-filling aspects of them. There's a sort of progression of the solids (via dual polyhedra?) that inspired Kepler to write mysterium cosmigraphicum and write the three laws of planetary motion based upon orbital resonance and its relationship to these geometries. I really feel like you could give these subjects a good treatment!
I hate to be that guy but 15 seconds in, the icosahedron is labeled as a dodecahedron. That's the only thing I could think of that was wrong with this video. Amazing work!
I think my favorite Johnson solid has to be the Snub Disphenoid. The idea that a "digon" (line) has a use case at all as a polygon, despite being degenerate, is just so funny to me.
yes! i get a weird sense of joy using degenerate cases in math, such as for example, 0! = 1actually being intuitive if you think about it, there really is exactly one way to arrange 0 items in a line on your desk after all.
its also funny to say "Snub Disphenoid"
Yeah! I once tried designing a Rubik's-cube-like twisty puzzle with the snub disphenoid. It bent my brain.
I like the snub disphenoid, partly because the name is silly and partly because Vsauce mentioned it, mostly because I think it's pretty.
@@Buriaku"... you must realize the truth."
"And what is that?"
"It is not the snub disphenoid that bends, it is you."
Son: "dad, why is Daisy called like that?"
Dad: "because you mother really loves daisys"
Son: "i love you dad"
Dad: "i love you too Great Rhombicosidodecahedeon III"
Nah you should have named him "Disdyakis Triacontahedron"
Dad, why is Daisy called like that?
Because when she was young a daisy fell on her head.
And how did you come up with my name?
No further questions whilst I'm reading, brick.
Isn't the last johnson solid the shape of a diamond.
@@taxing4490Oh no
@@TheCreator-178 Should have called it gyroelongated pentagonal birotunda
I've watched this once, twice opposite, twice non-opposite and three times and I still don't really understand all of them
Vastly Underrated Comment
understandable
"twice non-opposite"
What? It’s sight readable.
Spectacular video!
I also enjoyed Jan Misali's video about "48 regular polyhedra" which talks about some of the ones you excluded at the beginning
same
I came here to mention that video, lol.
@@KinuTheDragon same
same
Same
This was so chilling and exciting.
And also as an origami person, I was basically thinking of how to construct each one!
The most important thing I noticed in this video is a new way to get to irrational numbers and ratios via geometry
I can't describe my panic at the Dungeons & Dragons table looking at my dice and realizing that there were so few regular platonic solids. I bothered my DM about it for weeks. And then finally I saw in a video showed there are very many regular platonic solids as long as you don't care what space looks like, and that put my mind at ease. A good collection of *almost* regular objects is going to seriously put my mind at ease. I should make plush versions of these solids to throw around during other hair pulling math moments.
Yeah this is really giving context to the wikipedia deep dive I tried to do. Lots of pretty pictures but they didn't make sense until you showed the animations.
d10 and percentile dice are pentagonal trapezohedrons
If you want more dice, the catalan solids all make nice fair dice. The disdyakis tricontrahedron makes a particularly great dice, with 120 sides you can replicate any "standard" single dice roll by just dividing the result, since 4,6,8,10,12,20 are all factors of 120.
Plush solids would be so cute! Might want to use mid- to heavy-weight interfacing on the faces so they don't all turn into puffy balls when stuffed with polyfill… although that could be cute, too, especially if you marked the edges somehow, e.g. by sewing on some contrasting ribbon or cord (you could ignore this step or use different colors for the adjacent faces).
Now I want to make some 😂 I sewed some plushie ice cream cones recently and have been itching to make more cute things.
can't wait for when we figure out a way to make dice in the shape of the star polyhedra
I can describe your panic:
trivial
For dice, face transitivity is much more important than corner transitivity, so Catalan solids are much more useful.
magic man*
I just started watching this channel and I love how you can visualize and explain all this information in a way that is easy to understand. Great video! 😁
pixel land guy
rhombic dodecahedron is my favorite among all these guys. i like how unfamiliar it looks even though it has cubic symmetry. and its 4d analogue, the 24 cell, is completely regular! i wish i could look at it, its beautiful
It's even better when you realize it can tile 3d space! That's something most Platonic solids can't even do
@@nnanob3694 hey, this guy gets it! :)
with the music buildup at the end i was hoping for a scrolling lineup of all of the polyhedra lol. amazing explanation and 3d work btw
15:21
It must be my birthday!
Look at that beautiful little chartreuse gremlin spin! Oh, how my heart radiates with joy!
I need a bucket of blocks with solids from each family to play with
3:18 is that my channel
Incredible video, great work on it all! A lot of new names for solids I never knew before
A giant grid of all of the solids as a flowchart of different operations to get to them would be a hella cool poster tbh
Omg I would totally buy that
Someones gotta make that, that'd be so cool!
@@crazygamingoscar7325maybe i can
I don't know why, but polyhedra like these are inherently appealing to me. I just really love me some shapes.
Omg platonic solids
Why did I read this in the “omg I love chipotle” voice??
@@Kona120platonic is my liiiiiiife
> platonic solids
But wait! There's more!
Almost
😑
never before have i ever thought "damn i wish i had a collection of archimedean solids in my house" and then i saw 1:11 and spontaneously melted
I want one too but they cost like 80$ per shape lol
@@funwithtommyandmore they look like paper though, i'm sure an exacto knife and strong enough glue should be enough to recreate them
@@Yvelluap looks like weeks of work I'm not willing to put into some shapes lol
Great now I need a hystericaly elaborate polyhedra family tree diagram >:(
This is an excellent followup for Jan Miseli's video on a similar topic! Thanks for making this!
I had a weird math panic attack when I learned there weren't more platonic solids and that Jan Miseli video really put my mind at ease, and then went even farther and blew my mind a few times. Great video. And his stuff on constructed languages has taught me so much about linguistics that just keeps coming up in my regular language study, it's awesome. Love that guy.
🥜 : cube
🧠 : square prism
🌀 : triangular trapezohedron
🤓: inverted truncated triangular trapezoidhedronakaliod
Supertriakis tetrahedron.
pirax
Me watching this at 2 am, half asleep: “I like your funny words magic person”
if you take the deltoidal hexecontahedron. and force the kite faces to be rhombi, you get a concave solid called the rhombic hexecontahedron, and it is my favorite polyhedron
You'll probably enjoy this puzzle by Oskar can Deventer. ua-cam.com/video/1RExXExkOrg/v-deo.html. The peices are almost rhombuses
There's a rhombic hexecontahedron? I thought it's always a dodecahedron or triacontahedron.
@@FranklinWilliamWelker There is, It's also the logo for wolfram alpha. en.wikipedia.org/wiki/Rhombic_hexecontahedron
What's a rhombic hexecontahedron?
@MichaelDolenzTheMathWizard
en.wikipedia.org/wiki/Rhombic_hexecontahedron
this is fast becoming my favorite video on youtube. i'm so happy to see that there are other people out there who care this much about polyhedra. the disdyakis triacontahedron is also my favorite, it's like a highly composite solid! just as 120 is highly composite! this is closely followed by the rhombic dodecahedron (because it's like the hexagon of solids!) and then the rhombic triacontahedron. this video has taught me so much, like how snubs work, and the beautiful relationship between the archimedean and catalan solids. not to mention half triakis (i had always wondered how someone could think up something as complex as the pentagonal hexacontahedron.) and johnson solids! i hadn't even heard of them before this video! thanks for educating, entertaining, and inspiring me! i'm so glad i stumbled across this. 120/12, would recommend
Thank you so much! This is one of the most in depth comments of praise I've received and it's very encouraging :)
A few years ago I was very intrigued about a very similar thing, but with tetrominoes, aka tetris pieces. It's well know that there's only 5 ways to connect 4 squares on a plane, with 2 of them being chiral, hence the 7 tetris pieces we all know, but once you start to dig deeper you start to have so many questions. What about 5 squares? 6 squares? 7? What about other shapes, like triangles? Or maybe cubes in 3D, aka tetracubes? What if you keep only squares, but allow them to go in 3 dimensions (they are called Polyominoids)? Turns out there's lots of ways one could extend the idea of tetrominos, by either using different shapes, getting into higher dimensions or simply changing the rules of how shapes are allowed to connect.
I've been interested in that also! Not counting reflections, there are 12 pentominoes, and it's a classic puzzle to arrange them into a rectangle. You can actually make 4 different types of rectangle, 3x20, 4x15, 5x12, and 6x10.
Gonna be printing some of these. A+ infodump. Super well done
Platonic solids
Familial solids
Romantic solids
the kepler-poinsot polyhedra are sexual solids
Dude WTF 💀
Okay then sorry
Sexual solids- **gets shot**
Alterous solids
This is a most excellent video! As a 3d puzzle designer and laser polyhedra sculptor, this helps show the relations between the shapes. ⭐
Thanks! Great video. Have you ever looked at the geometric net of these kinds of solid. I know the cube has 11 possible nets. I would like to see a video that dives into the possible nets of some of the other shapes as well.
Thank you so much! I do have some degree of experience with the nets of the catalan and archimedean solids after making them all out of paper. Some of them I even modified to fit better on 1 piece of paper!
my favourite solid has always been the truncated octahedron because it evenly tiles space with itself, and it has the highest volume-to-surface-area ratio of any single shape that does so. its the best single space filling polyhedra! if you were to pack spheres as efficiently as possible in 3d space, and then inflate them evenly to fill in the gaps, you get the truncated octahedron
So basically it's a 3d version of the hexagon
I dont think thats quiet true. The shape you get when inflating spheres is a rhombic dodecahedron. You can see this by looking at the number of faces. The truncated octahedron has 14 faces but a sphere only has 12 neighboring spheres.
youe could well be right, im no polygon-zoologist @@Currywurst-zo8oo
I want a toy set that's just all of these solids,
not sure what i'd do with them,
but it seems cool...
Watching this for the 17th time. Thank you for getting this all this down into one video. I can tell you worked really hard to put all the faces together for this one. 🎉
I saw descriptions about these solids at high school, and couldn't grasp many concepts yet getting really intrigued. Your explanation was excellent. Thank you sooooo much!!
this is by far the best video I've seen on the topic! it's incredibly well explained
My Euler! This channel is a gem!!!
these shapes are really cool, we enjoy how ridiculous the names get lol
i really liked all the solids constructed with lunes! my favourite has to be the bilunabirotunda, it's just so pretty
Really fantastic video! You did a beautiful job with the visuals and in organizing the explanation. I have shown it to a wide range of viewers - from a 7 year old to a guy with a phd in math. Everyone loved it and had the same basic reaction - it was entrancing!
I have been trying to find a good explanation of Johnson Solids for YEARS and this one finally satisfies me. Thank you :D
You should make a video about tilings and hyperbolic tilings.
Now I wish I had hundreds of magnet shapes, so that I could make these in real life. They look so collectible.
pentagonal hexecontahedron is clearly my favorite with it's "petal" sides if you consider 5 faces connected on their smallest angle, or heart shaped sides, if you only consider 2 faces
Beautiful very well done and well paced video! I love it and thanks!
I LOVE WATCHING EDUCATIONAL GEOMETRY VIDEOS MADE BY NON BINARY PEOPLE ‼️‼️‼️‼️‼️‼️‼️‼️‼️‼️‼️‼️
Wow, haven't seen so clean, concentrated and convenient explanation, without unnecessary effects it's even easier to understand. Your format is my favorite among others since I went in for geometry 11 years ago. My suggestion for next topic is "3D Honeycombs" because it's logical continuation of solids. There are "regular" ones which consist of the same solids you were talking about in this video. The particularly brilliant thing is there were found some irregular (!) 3D honeycombs. Most of them are of similar polyhedra, both convex and not. The only irregularity in them were the colors which cube faces had or something like this. But maybe there are some of them I missed which look like 3D version of Penrose tiling.
Edit: Pentakis Dodecahedron is my favourite solid (the second one is Icosahedron) because it's one of the roundest solids which consists of equal polygons.
Imagine having dice of every single one of these
The Dice Lab is a company that makes some unusual ones. Their large set has a truncated tetrahedron, truncated octahedton, rhombic dodecahedron, deltoidal icosahedron, disdyakis dodecahedron, deltoidal hexecontahedron, and disdyakis triacontahedron.
I've been looking into these solids for years, but had no idea what the process of discovering them was. Half-truncation is one hell of a leap, especially for someone born a few thousand years too early for computers. It's amazing he found them all
The hebesphenorotunds (last one explained 27:03) looks really similar a gem-cut.
Think about the side with the 3 pentagon down into the socket and the hexagon outside and visible.
My favourite catalan solid is the pentagonal hexacontahedron. I find it very pretty how the flower patterns with 5 petals interlock to make chiral corners at the boundary.
Us: How many 3-d solids you want?
Kuvina Saydaki: yes
Truncated Icosahedrons = soccer ball pattern
Yes! I was wondering when someone would notice! 😄
I love this video! I'm glad that I found your videos. I have a love for mathematics and geometry, and it's cool someone made a video about platonic-y solids! I liked the video "there are 48 regular polyhedra" by jan Misali and this is the type of stuff I like. I think you would like that video, too.
Seriously the best use of visual examples in explaining these, I am sure there will never be a better explanation as long as I live.
Bejeweled gems timestamps:
0:06 Amethyst Agate (Tetrahedron), Amber Citrine (Icosahedron), kinda Topaz Jade (Octahedron)
2:38 Ruby Garnet (Truncated Cube)
2:46 Quartz Pearl (Truncated Icosahedron/"Football" shape)
16:12 Emerald Peridot (Deltoidal Icositetrahedron)
20:11 kinda Sapphire Diamond (Halved Octahedron)
OMG thank you for this comment, I was wondering about this!
@@feelshowdy It's not 100% accurate, because not all of the Bejeweled gems are platonic or almost platonic solids of course, but I wanted to include all of them in the comment since they're all so equal to each other.
Why are you calling this ⚽ a football that's obviously a soccer ball there's a giant difference
I watched this whole video and found at least five of my new favorite solids. They will never beat my favorite shape, the snub disphenoid!
Also, please make a video on some of the near miss johnson solids.
I was so happy when you included those 4 honorary platonic solids!
sensational video! Loved the term honorary platonic solids, definitely stealing that one!
My personal favourite is the rhombic dodecahedron! :)
I am a particular fan of the disdyakis triacontahedron because it is the largest roughly spherical face-transitive polyhedron, so it's the largest fair die that can be made (ignoring bipyramids and trapezohedrons)
Amazing video!!! Very in depth and yet easy to follow, I really enjoyed some of the smaller details like sphericity!! i look forward to your future uploads!!!
-from another friend of Blahaj ;)
Your color choices for each polyhedron are lovely. This whole video tickles my brain wonderfully. I want a bunch of foam Catalan solids to just turn over in my hands.
Thank you! I put a lot of thought into the colors so I'm really happy that it goes appreciated!
I was expecting this to be like a reduced version of Jan Misali's video about the 48 regular polyhedra... what a fantastic surprise! I love geometry, those were some great explanations.
Great video - I've been fascinated by polyhedra for decades and I learned some new things here. Well done!
after watching jan Misali's platonic solids video and vsauce's strictly convex deltahedra video, seeing some concepts i got from there return here was nice and cool, like a callback from across my brain :3
I have no idea how you make everything feel so concise and ordered. If I wanted to research this it would be so messy
Fascinating video, thanks for posting. Some years ago I assembled some of the Johnson Solids using Polydron (plastic panels that clip together)
I would love to see a video looking at the stellated versions of some of these and how the math works out for self-intersecting planes in these shapes
ENBY DETECTED!!
LOVE, AFFECTION, AND SUPPORT MODE ACTIVATED!!
This is the type of video I hope gets preserved after the internet gets destroyed or restricted or some great data loss happens within UA-cam’s servers
Had to pause to comment - this video is excellent. Great job. Interesting topic, good visuals, good narration.
Kudos!
Thank you for such an interesting video. A lot of these I was hearing about for the first time and I found great joy in hearing you pronounce the name, getting surprised that this one is longer than the last one, and then laughing as I struggled to pronounce the name myself.
My favorite was either the “Snub Dodecahedron” or the “Pentagonal Hexacontahedron”. The Snub Dodecahedron looks so satisfying having a thick border of triangles around the pentagon, but there was something about that Pentagonal Hexacontahedron that I found really pretty. I think it’s because of the rotational symmetry.
Again, thank you for taking the time to make such interesting and engaging videos. I look forward to watching another one.
mine too!
I LOVED this video!! I am a huge geometry nerd and learning about polyhedral families and the construction methods to generate new ones makes them all feel so intertwined and uniform. If I may request, please do a video on higher dimensional projections into the third dimension like fun cross sections of polytopes through various polyhedra. TYSM
11:50 i like the pacman reference
There is another category of almost platonic solids where you only use property 1 and 2 and don't care about the verticies being identical. These are the triangular bipyramid, pentagonal bipyramid, snub disphenoid, triaugmented triangular prism and gyroelongated square bipyramid, otherwise known as the irregular deltahedra.
Thank you for making a version of jan Misali's 48 Regular Polyhedra that respects its audience. I needed that.
This is the first time I've ever heard of a disdyakis triacontahedron, but upon discovering what it is, I now want one.
i'm honestly surprised that you've explained it this well, i was able to keep up pretty much the whole time,, i was so shocked that i could understand what was happening
i want to commend you for the use of color coding for things like rotundas and cupolas, you've done an amazing job at making this more digestible and it was very helpful
excellent job on the video, kuvina
Let's face it most underrated youtuber I have ever come across (is you)! Well done and Thank You, you are a wonderful edgeucator c: who always gets even very complicated points across, not to mention the volume of information in each video is enormous!
I'm trying to get a pun in here but your comment fills so much of the available space that I'm pretty sure it's a tileable solid!
Just discovered your channel and am loving it. You are covering all my favourite topics. I personally find the Catalan solids more beautiful than the Archimedean ones.
i like the cupolas
also i admire how you were able to say so many syllables so confidently lol- it probably took a few takes
This channel is going onto the list.
Hopefully once this nightmare of a degree (math) is done I'll have time to get through these interesting videos/topics.
This video fulfilled a craving I’ve had for years. Thank you.
My favorite Catalan solid is the 30-sided rhombic polyhedron based on the Golden Ratio because I figured out how to make it in Sketchup. It is closely related to the icosahedron and dodecahedron.
same with the icosidodecahedron (which is pretty much if the two fused together dragon ball z style)
If you're into Sketchup and geometry then you might find a few videos I've done on my channel to be interesting.
Also, you guys know the Sketchup team does a livestream every Friday? Fun times..
I loved this, especially the explanation on why there are only 13 Archimedian solids, great work!
Even as someone who knew where most of this was going in the first half, I didn't realize why you were delaying explaining the relationship between the cube, octahedron, and cuboctahedron until you started talking about duals.
And the real fun (and actual research) starts when you go to higher dimensions. The higher dimensional Archimedean solids are called uniform polytopes, and noone so far has been able to classify them. Same for edge-transitive polytopes. There are lists that are conjectured to be complete, but no one knows. Conway found a new uniform polytope in dimension 4 (the grand antiprism) which had to be added to the list, so no one knows whether there is not something else we have missed so far.
I’ve always LOVED the Catalan solids, definitely more than the Archimedean solids, …maybe more than the Platonic solids.
These are incredibly interesting, like platonic solids but stranger and there are way more. Love it!
4:37 You can also make a rhombicuboctahedron by expanding a cube, which is done by moving the faces away from the centre and then connecting them with rectangles on the edges and whichever polygon is needed on the corners. The same can be done but by rotating each face and connecting them with triangles instead of rectangles to make a snub cube
First time seeing any video of yours, already my favorite enby math teacher
This UA-cam video has earned a spot in my all-time top 100, and definitely on the upper end of that 100. I’ve been watching YT since 2007. You’re seriously underrated, so if it helps, you’ve earned a new subscriber.
I'm thankful another person has commented on the incredible quality of this video. I agree!
The shapes are all so beautifully presented; could you please share the software you used? Or is it a code library, perhaps?
I used blender! You can download all the STLs from wikimedia commons, and they're automatically public domain since they're simple geometry!
@@Kuvina awesome; many thanks!
@@KuvinaI didn't know Wikimedia hosts 3D files. Thanks!
The blender is incredible! I love the little introductory twirl tytytytyty
I'd love to see a video about tessellation of 3D space with golden rhombohedrons and what they build (such as the rhombic triacontehedron) and then combine that in the same video with looking at the dual polyhedra of the various related solids using the icosadodecahedron as the glue that fits the whole picture together.
Quasicrystals are something a lot of people are interested in and these relationships are critical to quasicrystals because of the 5-fold symmetry (ie the golden ratio) and space-filling aspects of them.
There's a sort of progression of the solids (via dual polyhedra?) that inspired Kepler to write mysterium cosmigraphicum and write the three laws of planetary motion based upon orbital resonance and its relationship to these geometries.
I really feel like you could give these subjects a good treatment!
great video!
once, twice opposite, twice not opposite, or three times
You deserve way more than 4k subs, this a brilliant video
This is an incredible video. Fantastic job, and thank you!
I hate to be that guy but 15 seconds in, the icosahedron is labeled as a dodecahedron. That's the only thing I could think of that was wrong with this video. Amazing work!
Lol there is 2 Dodecs
My favorite is the pseudo rhombicuboctahedron. I have one sitting on my desk along with an icosahedron that’s missing eight faces.
this channel is so underrated love your videos!!!!
Came for the 3d shapes
Stayed for the enby explaining the 3d shapes