Terrific Toothpick Patterns - Numberphile

I like how mathematicians solve things because they look fun and then later everyone is astounded that the solved problem has some amazing, unexpected, and useful real-life application, and the mathematicians are like, "yeah, neat..." but they are already working on their next puzzle just for fun.

"...and we don't understand this at all." When he says this, there is a childlike excitement in his voice. I guess that this goes to show that though it's exciting to understand things, it's can also be exciting not to.

Waiting for Matt Parker to buy a space somewhere to start laying down as many toothpicks as possible in this configuration

I like this professor. He is Numberphile's ASMR.

The way he is talking lmao its seductive to be honest.
Anyways, almost everyone on Numberphile is so passionate about their stuff, it's so amazing to see.

Sloane was 79 at the time of this video's publication. Besides being an incredible mathematician he's an avid rockclimber. Seriously, Neil Sloane has managed to mathematically manipulate his age to stay so young.

That was a wonderful video.
His voice is mesmerising.

Omar. Omar Poll .... yes 'yes' (whisper)

Complexity emerging from simple rules and simple starting conditions is always fascinating!

Every pattern is very beautiful. I also want to see 3D version.

Me in 2019: oh that's pretty neat
Me in 2020: "how fast diseases spread" HA

This is turning out to be a wonderful series. Neil Sloane himself giving us an inside peek of his marvelous encyclopedia entries. Keep em comin :)

Oh my god. I can't even.
I swear, i encountered the first pattern for myself via bored doodling back in school like 10 years ago
and drew this pattern everywhere in notebooks cause it looked so pleasing.
Thank you for showing it in an actual video.

"We're at a table. We have tooth picks. We notice that each tooth pick has two ends." Reminds me of when we rolled low on a perception check. Except not even then did we notice that the door has two sides.

"And then when you look at 32 generations", it's suddenly a QR code.

Most Numberphile videos are ver good. This one is better, I dare say an excellent
...pick.

I love how he was incredulously like "who would ever design a gull toothpi..." and he just answered "Mark Pol" without skipping a beat.

“Good news everyone!”

Love everything about this guy. His knowledge, his wallpaper, his t-shirt.

Always thought Sloane's voice is oddly soothing and satisfying.

Me during the day: Omg I’m so tired, I’m going to bed early today.
Ma at 3am: *Terrific toothpick patterns*

One of the best videos on the channel, imo! Very interesting, very mathematic AND aesthetic, simple yet complicated, and not arbitrary... I want moar of this! :D

I smiled when I saw his large piece of paper. I have books and books of this kind of stuff from a phase I went through in the 90's. Complexity from simple rules is absolutely fascinating.

how the heck does the replicator work? it seems like magic. I drew a smiley face and an arbitrary picture, and both got replicated perfectly. In the simulator I was using, the field was limited, and interestingly, when it hit the corners it actually produced a mirrored version of the original.
Even more interestingly is that the simulator didn't consider the diagonals, only the direct neighbours.

It's like Attenborough but with numbers.

This was one of my favorite Numberphile videos. It was absolutely flabbergasting to see the patterns unfold like that. When he brought out the hexagonal cellular automaton analysis paper, it really showed his passion.

Looks like Piet Mondrian's work! Very cool.

for somebody totaly sucking at math my whole life , yet not able to resist not subscribing to this channel , i just think i wish i had this man as my math teacher... i just got high watching this its amazing

Awesome... just recently I looked up a sequence on OEIS. Then I wanted to know who made that database. And I found out, it was him.
And now we have him explaining cool stuff here. Almost as amazing as replicating pixels.

everytime he says "we do this forever" its gives me chills

I love the hex, because the pattern is so much more complex. You get repeating bits, but slowly those bits grow into larger patterns as you get more growing hexes! So beautiful! And lots of triangles in its shape as well.

I have never loved even a person as much as he loves mathematics, I feel jealous :(

Brings back memories. Back in the Eighties, I read an article in Scientific American on cellular automata which led to a fruitful period of learning to program my new Commodore 64, first in Basic and then when that was too slow, with opcodes, reading, processing and then writing directly to the screen memory, one pixel at a time. You can now find websites with such wee programs you can play with.

I'm so happy that people can work on things like this, humanity is doing some things right...

I believe everything you say, Professor Farnsworth

Things I've found while trying to resolve the hexagonal one: if n=2^k | kEN, u(n)=6(n-1), and the following term will always be 6. The sum that describes the total of the square set holds for the hexagonal set out to about n=15 if you replace the 4/3 with 2 and the -1/3 with -1. There is a pattern in u(n), but every iteration of it I come up with collapses after a certain point. Adjusting it slightly makes it work again even further out, but even if it holds to 2^2^2^2^2^2^2^2, it holds for only the tiniest fraction of the amount of the time it would need to to prove it, and I don't have the math chops to analyze it that far out.
This is super fun though, I can see why Neil has been cataloging these for as long as he has.

This video is the perfect response to all the haters saying this new guest has "ruined" Numberphile. Brilliant, beautiful video. More Sloane!

Some people have voices just perfect for explaining abstract and incredible mathematical concepts.

Brady, you said that I was going to enjoy this video, and you were right! Lovely video, thank you!

I sense a Coding Train video coming out of this...

Neil Sloane is the David Attenborough of mathematics

Dr Sloane is one of my heroes, thanks for interviewing him :-) !!!

I love Neil Sloane's passion! Thank you!

I happy guys like this exist to ask and answer questions i would have never even conceived of

THIS IS CRAZY! I can assure yall I have never heard of this problem but this was my tactic to dealing with anxiety in a class by doodling this exact problem. I thought I was a genius to come up with this but thanks for shattering my ego. Still cool to see!

Cliff and Neil are two sides of the same math-loving coin. One with a chaotic and excitable approach and the other with an equally powerful ordered and serious approach. Both seem to have the exact same passion for the field and I think it's beautiful.

It looks like a really cool city design. Big boulevards down the center and then smaller boulevards crossing the quadrants and then breaking down into neighborhoods on side roads that are not through streets

This video is absolutely outstanding. I love cellular atomata and (without knowing mathmaticians think about it) i always draw those toothpicker patterns in class.

I love when you see a magnification of a fractal pattern that diffraction type patterns come and go. I swear after so many decades of studying it....it seems like it communicates something sometimes that way...a higher order of the pattern revealing itself. Trippy.

On the hexagonal pattern, the inner pattern spawns four replicas of itself after reaching a power of two. In the replicas that grow in a more outwardly direction from the center it's easy to see the replicated pattern, but the replicas that fill the empty space between the points of the hexagon start interfering with each other to create a slightly new pattern in the middle of the new triangle.

15 years ago I've been playing with Conway's Game of Life, in fact playing with the rules of the game, and found (after many trials and errors) that very beautiful and intricate patterns could appear with this set of rules:
1. Cell turns ON if it has 1, 3, 5 or 7 neighbours.
2. Cell stays turned ON only if it has no neighbours; otherwise it turns OFF.
It behaves very much like that Fredkin replicator, because... now I see that it has pretty much the same rules.
The variety of patterns of course depends on the starting position.
Curious patterns and trends appear when we change the concept of the neighbouring cell - for example: besides the "classical" neighbours (which have common side or vertex with our cell) we will include the neighbours of the neighbours.
There is plenty of this to observe and explore.
Very nice and informative video, by the way.

This mans voice is delightful. I would love to hear more of it!

I would listen to anything he said for hours. His voice is wonderful.

I used to replicate the first toothpick pattern with cards to build a squared base for many houses of cards. It's a pretty strong structure, and now I can know exactly how many cards is needed depending on the size of the base. Thanks.

I don't understand maths but I am touched by the compassion and dedication of this wonderful man to his subject. Just beautiful!

My favourite part of these videos is looking at these kinds of activities, and seeing how they can be applied to other areas of life and science. For example, immediately this makes me think of crystal growth, with each of the "toothpicks" being a different tiny crystal domain, a set of regular crystal lattices, forming into small crystals that then themselves form on specific sites of other crystals, and then continue to grow into a massive, chaotic, and yet still periodic, superstructure.

The most beautiful thing I've ever seen people do with toothpicks

First one looks like a frank-lloyd-wright window-screen. Reminded me of the guy who did the “dragon’s curve” as a tiled wall decoration...

I would LOVE to see more working notes from mathematicians! Exciting to see what's on the horizon like that, and to glimpse at how they approach problems.

I would have loved having this fellow as a professor. Passionate people make learning easy.

1. Excellent video. This kind of video shows the innate beauty of mathematics in a way that makes me want to pick up a pencil and start drawing iterations. One can only imagine how these sequences are related to others found in nature. 2. This would be an awesome screensaver.

I love this old mans passion!

God I love this niel Sloane guy he's so relaxing and happy and always has interesting topics to me

Love the Hendrix t-shirt feels very appropriate for this kind of fractal maths

My favourite numberphile mathematician by far!

Thank you for the video! All of you are super awesome!

I love how much that guy loves math

Watching this actually caused me to stop what I was doing and play around with the simulations. Amazing content!

I love this channel and I love how enthusiastic mathematician are on here

One of my favorites

his excitement about toothpicks is infectious

This is like the 10 time that I listen this video, I really like the content and in general the content of numberphile, but the voice of this gentleman is really warming and calming, it relaxes me -_-

His voice seeks into my brain and and whispers int oits very depths. . .

Thank you Mr. Sloane, very cool!

I've seen quite a few videos with this gentleman speaking and he is easy to listen to and interesting to relate to.

I love math for reasons like this. Makes me so happy, something so small(yet large) is so entertaining to me. I'm thinking about going back to college to get into physics or some type of science/maths heavy field. UA-camrs like you and 3 blue 1 brown, Matt Parker, etc. You guys really make maths fun

close your eyes and enjoy 3:54

as a chemical engineer i can se how some of this sequences can be used in different models to predict a catalytic reaction, a really impressive work, great video ¡¡¡¡

I had this in the background while doing homework and I jumped when he started mentioning how things spread and how this might be useful for people studying epidemics. Kinda makes sense why UA-cam decided to recommend this one

Idk if this is very significant, but you can simulate the original toothpick machine using a grid and cells.
You just need cells to survive with 1-5 neighbors (if you change the survival states, you can get variations of the same image, and I find them all rather delightfully pretty) and to be born with 1 neighbor (diagonals included for both)
I noticed the toothpicks greatly resembled a simulation I created in an app meant to replicate conway's game of life, but where you can alter the rules if you please. Cells born from single neighbors naturally reflect this corner-centric style of growth.

ok, I didn't particularly enjoy the previous two videos with prof Sloane, but this one is amazing. I wan't toothpick design on my walls

Thank you for the work you put into the description! It is nice to know that relevant links will always be there :) checking out the toothpick simulator now

so it becomes a square at every power of two, better call computerphile!

Absolutely loved this one

His tone and way of speech...Neil Sloane is like the Jeff Goldblum of maths

Played around with this stuff in golly, it's super cool to see some of the math behind it.

If Neil ever narrates a book, I will buy that audiobook.

I did this on my notebooks in school. When u get big full page patterns it’s just a big square with the same 4 ends as the start, and that’s square gets bigger by powers of 2.

His enthusiasm is so contagious!

i love this video because the second the concept was introduced my first thought was different shapes so i was filled with glee when the other options were shown in the video!

I stumbled upon the toothpick pattern myself as a kid, in my case it was with playing cards, building a sort of one-story "house of cards" by propping up a playing card standing on its side by crossing it with two other cards, one on each end, then crossing the two ends of those two cards with other cards etc. The pattern very quickly grew unwieldy yet interesting enough to switch to graph paper, and I soon filled much of a graph paper notebook with lined patterns, and on the other side of each page lists of numbers keeping track of how many "cards" were added to each generation, fruitlessly trying to find a pattern in the numbers. Being a ten year old or so kid who would not ultimately be drawn to a career in mathematics that's as far as it went, but it's cool to see some actual competent mathematicians picking up where I left off

That's so beautiful. Amazing.

Division is the one rule of partitioning. Numbers are junctions of partitions. Patterns vary every time you hit prime.

The passion this guy has is formidable

Gosh, what a delightful, gentle soul Neil is.

I love how excited he is!!!

Fibonacci is in there. Count the steps for every new square that arises ,till they add up to the next complete bigger square.

this is the best video on the channel i have come across, great work on the logo and graphic effects. this guy really loves what he does, and i relate to that, he hasn't given up!

After step 3, the toothpicks edges can be coloured with just 4 colours (no less). Alternate colours going north and south and alternate colours going east and west. This makes the toothpick graph type 1 instead of type 2 for any n>3.

Sometimes he sounds like Mr freeze turning on buttons in Batman and robin....lol....Great work guys