Some notes and responses to common questions: - The video was made using Adobe Illustrator and After Effects. I would not recommend doing a similar video this way, as it requires laying out every shot perfectly beforehand and animating every line more or less individually, rather than relying on a coding background (I have basically none) and a program that could simply generate the animations instead. A drawback of the way I did it is stuff like the missing line in the decagon that people have pointed out at 0:50. - Despite looking similar, I assure you there's no connection between the 10 graph and the Brilliant logo :D. (Also, what do we call these images? Designs? Graphs? Patterns? Symbols? Let me know what you think) - Could this be done in 3D? I'm not exactly sure. You could pick a point on the sphere to start, but how do you go about distributing the rest of the points on the sphere, in a regular pattern? It's easy to do it with a circle because you just go around the circle. But with a sphere, you have to choose between two axes of movement. - Thanks to everyone who reassured me that the mod operation can apply to fractions as well as integers!

This is a hidden gem.

I don’t know why I’m getting this as a suggested a year later but I ain’t complaining

I’m an artist and have been focused on rotating objects and the visualization of mathematical patterns for my entire life. The information in this video absolutely provides the most inspiring information I’ve ever come across, thank you!

Hi. I discovered these exact patterns a few years back and it feels strangely validating to have someone else discover them too. I would like to be the first to have discovered these things but that's highly unlikely since there's nothing new under the sun. Let me recommend that you stop limiting the periods to bouncing within a circle and give them the angles of a triangle or a pentagon or a hexagon. Whatever polygon you like. You will see some very beautiful and awesome line designs, there's one that even looks like a profile of a brain. It's fascinating. Also, I used a different kind of modulo that does not allow zeroes to be produced, I guess you could say it is an 'inclusive modulo' since it produces the dividend if the divisor fits exactly. Be careful though, you may lose many many hours watching the designs produced:D

Any way add a third dimension? It would be interesting to see some of the irregular designs in a sphere.

I bet this video will inspire a lot of tattoos in some math enthusiasts around the globe

6:18 This mod 10 design was brought to you by, brilliant

The pedagogical outlook expressed in the introduction actually hooked me. Multiple/alternative modalities, recognition of many possible representations, lovely! Math content that treats students as curious humans rather than the "show your work" automata i recall from my school days.

9:42 It contains 1, 3, 7, and 9 *because* the chosen mod is 10. Except for two and five, all of these numbers are coprime with ten-because primes are necessarily coprime with every number that isn't a multiple of themselves. Two and five are the *only* exceptions because they are the factors of ten.

This is one of the most interesting, math related videos I've seen in a while. I love these types of math visualizing videos, so I hope you continue making them!

Hi Jacob. I found some interesting ones. Just woow: For mod = 675 and every [fib+fib] * 947 with a fib start position of 6,7 Butt/Mushroom: For mod = 2529 and every [fib+fib] * 2 with a fib start position of 0,1 eye: For mod = 2529 and every [fib+fib] * 2 with a fib start position of 2:2 Infinity mandala: For mod = 376 and every [fib+fib] * 2 with a fib start position of 2:2 Regular mandana: For mod = 688 and every [fib+fib] * 662 with a fib start position of 2:8 I also made an online demo where everyone can experiment with values I tried linking it before but it didn't work, will now try in the reactions of this comment.

5:30 When you just want to do mathematics but accidentally start summoning a demon.

First of all, since you were wondering: this was in my youtube recommendations Second of all, wow. This video was amazing. I can see just how much effort you put into animating everything and I’m honestly shocked it has this little views. Keep it up!

First thing in my recommended after waking up in the morning. I absolutely loved the style and message of it. Looking forward to seeing more beautiful productions like this.

Yes! This is exactly the type of math visuals I have been sketching for some time now, mostly experimenting with star polygons. I'm so happy this was recommended to me. Great work, you have opened me up to new knowledge!

10:14 I actually used this framework a couple years ago to solve an interesting puzzle I came across at a conference: “arrange the digits 1 through 16 so that every pair of digits sums to a perfect square.” I used this visitation method to find other sequences of digits, 1 to n, for which this is possible, and their respective solutions. Turns out they’re connected to Pythagorean triples, and the visitation of all possible sequence of digits makes nice parallel lines.

I slightly chuckled when I saw the words "Pisano period" was written in red text over a yellow background. I will never grow up.

This is excellent both in concept and execution, thank you. I’ve been drawing patterns like these for years but without any sophisticated math(s) underpinning. I will be experimenting with the generative sequences you have described so clearly.

So cool! I’ve been working with Fibonacci in rings for years, not having any idea about Pisano! I came up with another visualization technique - rather than treat each pair of numbers as a line, treat them as Cartesian coordinates. So mod 13 gives you a 13x13 grid, color in the coordinates as they come up in the series. Then, if you start with a different pair (say Fibonacci x2, or Lucas), it will fill in either exactly the same squares, or a completely different, non overlapping, set of squares. Keep going, and you can tile the square with a small set of nonoverlapping patterns. Striking symmetries appear with prime modulo bases!

Hey man you are setting a great example. I appreciate that you are inspiring people to explore in new ways and not just giving answers - I don’t want to find the answers to life’s mysteries in a KZbin video. I say, let people discover things on their own - that path is sacred. 🙌 On a side note, towards the end of this video you mention the Fibonacci series X2, etc.... I use this idea extensively in setting up modular compositions. There is a particularly elegant group of these multiples which can be used simultaneously - a fruitful rabbit hole to explore and interesting lessons to learn there . I call these the “Fibonacci Canons”. And again, thank you for doing it right. I shall subscribe! - tommy

9:44 The only possible remainders are actually 1, 3, 7 and 9, because since we’re dealing with prime numbers, suppose p = any prime number, p/10 will always give an uneven remainder inferior to ten, and the reason we don’t get 5 (the only missing uneven number) is because all numbers ending with 5 are multiple of 5. Therefore, we can only get the remainders 2 and 5 at the beginning (2/10 = remainder 2, 5/10 = remainder 5)

0:50 the mandalas - I love how the even numbers have a centerpoint, while the odd numbers have a center area/polygon. I never realized that until now, thank you.

LOVING that you added TOOL!

13:00 I would say 0 is an even number, you can decide it by 2 and get a whole number (0/2=0) and it is surrounded by odds (1&-1) that makes it even. So how would the shapes differ if you counted 0 as an even number instead of ignoring it? Maybe it gets even more beautiful results

Love that you had the Lateralus reference in there at 10:23. Great job. Thank you.

While exploring my interest in number theory, I was trying to think about what Fibonacci numbers would like like under mods. I saw the odd repeating patterns and decided to do some research, finding pisano sequences and then later stumbling upon this video. This was very insightful and I have learned a lot from this, one of the best math videos I've ever seen. Nerding out so hard to this one

Thanks for sharing! One of the most interesting patterns I have found related to phi is Penrose tiling.

This needs way more views. Blew my mind

This is the video I need! Thank you foe the in-dept explanation of fibonacci sequence, an oddly favorite sequence!

My new favorite channel 🤩 thank you so much 🙏. Amazing work here!

This video was amazing. I loved it so much. Best video I have watched on KZbin in a while. Please let me know if you have more video like this!

This reminds me of "Spirogragh" that came out in the 60's. I never got bored with it, yet I always felt a sadness come over me. You see, I have always loved math and geometry with a passion, but as it was, the two never loved me in the same way. My brain was never wired for it. As with some people who say that they are a woman trapped in a man's body, similarly, felt I was a mathematician genius trapped in a D- average mind. Nonetheless, this doesn't stop me from enjoying videos such as this one. And if I may say without qualification, this video was wonderful and fascinating to watch. Thank-you for the time you put into it. By the way, KZbin recommended this video to me.

at 9:42, the reason that (ignoring the first 3 numbers) it’s always 1,3,7,9 is because mod 10 is the same as only looking at the last number, and all prime numbers after 5 only end in 1,3,7,9 due to the fact that ending in an even number makes it automatically divisible by 2, and ending in a 5 makes it divisible by 5

This is the same hobby I do! (Exploring math especially visually) I plan on making some math videos but Ill probably make a dedicated channel for them. Applying a modulus to an infinite sequence is such a brilliant idea, glad I saw it! Love this video a lot!!

I'm interested in learning what type of a program was used in making and displaying the graphics in this video(the animation in the end made me realize this!)?

Thank you for explaining the Pisano Period. This is yet another concept that I discovered independently while thinking about math, along with continued fractions, integer partitions, Hasse diagrams, and rep-n-tiles.

Damn I at the end I looked at the subscribers expecting 300000+ , keep up the good work!

Almost sixteen minutes of bliss. Superb fun, highly creative. Thanks uploader!

thanks for doing this! i appreciate your efforts very much. in community college, i submitted a spirograph drawing for display. they’re beautiful and remarkable. it was accepted. so, it’s art. love, david

I'd say that this is very much art. The procedural nature of these designs reminds me of the the Library of Babel. The creativity doesn't lie in the procedure itself, but rather finding it among the infinite sea of other ones.

Absolutely fascinating! I had just been wondering about creating digital art and this hits quite the spot

I deliberately searched for fibonacci sequence looking for which items I could apply this sequence to, mostly which plants. Most of the videos appeared lecture-oriented or copy and pastas of other content in a v ambiguous higher-power way. The title and visual both are why I clicked on this one. I'm in a math class that touches on this and I want to expand my breadth of understanding how this connects and to what. Thanks for transparency on how this was made, too.

THAT is a great explanation of modulo

This is actually related to and helps understand polyrhythms and cycles of rhythms in general in music a lot more efficiently.

Looking at the graph of modulus to Pisano period length reminded me of the output of my master's thesis/research on strongly non-repetitive sequences. They look surprisingly similar!

Well this really got my old brain cells buzzing thank you Jacob! The first thing I want to say is that for some years I've been learning and using (privately) a schematic programming system called FLOWSTONE, by Dsprobotics. I'm sure it will be possible to make a program that will generate these visualisations exactly as shown without all the tedious video editing, and I'm going to make that a new project along the lines of specifying a sequence, or even entering the formula for a sequence, and how to modify it. I would like to send you the results once done. The main project I've been using Flowstone for over the last 12 years or so has been developing a music generation system. I basically use more or less randomly selected logic gates to generate three different repeating sequences of numbers between 0 and 7. The first pattern determines the order in which 8 oscillators tuned to a common chord sounds. The other two patterns determine how the pitch of each note is changed by a specified amount. Once I find a pattern that is musically interesting, I use the oscillators to generate further parts to make a complete performance. This video has inspired me to adapt what I've done, to use these sequences you've so beautifully described, instead of my semi-random ones - music generated by mathematics can be surprisingly interesting, dramatic and moving. Again, I would like to send you the results, but I suspect the music version will take somewhat longer than the visualization. Thanks again, Jacob, for sparking off so many interesting ideas.

This is fantastic, just beautiful. Thank you!

4:32 To be honest, I'm more interested in those outliers around 250, 620, and 740.

This is pretty cool, I wish stuff like this was shown in schools. It wouldn't replace in-depth learning, but it gets students excited about math and makes grasping the concepts way easier

What a time to be alive and curious. Thank you for sharing your work

0:49 I can't see normal nonagon diagonals after kglw's nonagon infinity

Glad I found this channel by accident...keep up the good work!

Excellent! I deeply appreciate your hard work and so very interesting and rare information! Keep up the good work!

0:51 are the bottom right and the bottom left missing 1 line each?

Interesting video. I have been discovering the beauty of math and how it truly weaves its way thought all of creation. I can already see application in the arts and will be applying this to some musical ideas that I have been exploring. Contrary to what I believed my whole youth, I am finding math to be quite beautiful, useful and not as scary as I thought.

9:42 The sequence only contains 1,3,7,9 because 2 is the only even prime (i.e numbers ending in 0,2,4,6,8) and numbers ending in 5 are always divisible by 5.

i would like to see the path designs but this time the angle is according to the angular fraction of the remainder and the modulus. so if we did mod 3 and the remainder was 1 then we go in a 120degree angle (anti clockwise) from the previous line. if it's remainder 2 then we go in a 240degree angle (anti clockwise) from the previous line. if the remainder is 0 then we go backwards (360degree angle anti clockwise) from the previous line.

Hi and Thanks for sharing. Is there a open source plotting tool available to plot these scenarios? or is there a tool you can share to plaly around with this discovery? I am particularly interested in the values in Pi as a area to focus on.

I just love stuff like this! Great work!

Wow, great video! You've provided me with lots of food for thought. I'll have to explore some of these designs myself and see if I can come up with some new results. Thanks for sharing this information!

Great video, made me understand pisano period

You can totally take mod fractions! You just can't factor them, and they don't behave as nicely under stuff like exponentiation. It all depends on what field of math you're working in - number theory, where moduli live, is usually only concerned with integers (and integer-like objects) anyway.

Having all the circels on a big poster would look sick!

Just wanted to point out, for those who have not seen it, the result at around 9:40 is a result of Dirichlet's theorem.

You can extend the modulus operation as a mod b = {a/b} * b, so that {x} is the fractional part of x. If you aren't familiar with the fractional number of another number, it is defined as x-floor(x), where floor(x) is the only integer n so that x-1

The fact that the Fibonacci one makes a plus sign is so incredible to me.

A little late to the game, but PLEASE MAKE MORE VIDEOS!! THIS WAS SO LOVELY AND ACCESSIBLE!!! as someone way up in higher maths, it's rare that i find a video I find both accessible to students AND interesting to me personally, this one 110% hit it!! liked subscribed etc but PLEASE KEEP IT UP!!

I came up with an interesting symmetrical Fibonacci-generated pattern along a similar route once. I started with a 10x10 grid of squares numbered 0 to 9. I then colored in every square whose coordinates corresponded to a Fibonacci pair of numbers, mod 10. So the first few squares I colored in were (1,1), (1, 2), (2, 3), (3, 5), (5, 8), (8, 3), (3, 1), etc. What I ended up with was a pinwheel-ish pattern that was beautifully unexpected. I tried to pursue this further to a 100x100 grid, but I was doing it by hand and didn't get very far, to be honest. I've always wondered if other mods made the same cool pattern that the mod-10 one did.

Something neat about the pattern revealed by the Fibonacci sequence, is that you will get the pattern regardless of the starting numbers. 246 and 10500, 2,134,431 and 12, pick any pair.

I did this randomly last year and found there is a period, I didn't know it had a name and i did it for integers upto 10 and it was somehow very cool and felt the right thing to do without any goal. I'm surprised how this is really a thing

Thank you for creating and sharing this excellent video.

I have only one word: beautiful.

this is brilliant! you need more subs.

You arranged numbers on a circle, but what's your thoughts on adding one more level of complexity by also changing the radius at which the line stops? For example, iterating Fibonacci mod 10 for the degree, and mod 3 for the radius? I think this could lead to quite a trippy periodic loop.

Thank you for a fascinating video -- indeed, it was exactly as promised: "A New Way to Look at Fibonacci Numbers" and i found it quite thrilling.

Now i know where the brilliant app logo came from, ty

Incredibly helpful for my current relationship with Fibonacci.

all mod 12 can be associated with the chromatic scale in music and generate melodic or harmonic structures. Thanks.

just a small note, you can absolutely use modular arithmetic with all real numbers, but that tends to be more of a computer science approach. Look into the sawtooth wave; it is a perfect extension into real numbers, albeit not quite as easy to use now that I think of it, the Desmos graphing calculator allows the mod function with real numbers, so that’s a pretty good way to visualize it and hopefully understand it

Just like music is the audio expression of math, what you are doing here is the visual expression of math. A pleasure to watch a fellow thinker in this field!

I wonder if this method can used to make sense of data sets ?

Can you tell me what this proof is called? (n + 1)² = n² + 2n + 1 Essentially, it's a proof for infinite squares using addition, which subsequently fills out the central line of the multiplication table. I wanted to reach my niece the multiplication tables, and stumbled upon it, but had no idea what it would be called.

Great insights! I liked this better than Numberphile. By the way, do you post your art anywhere? It’s solid generative design.

KZbin recommended this to me randomly. Fascinating stuff!

I didn't know I needed to know this. Really cool.

"Tell him that this video is lit, Johnny."

love that Tool reference, lol, great video

this is the best video i've watched in a long time. thank you

This is so good, been trynna find a way to get back to math. Amazing stuff! Hope you grow fast!

9:47 "...for whatever reason"? A number modulo 10 is congruent to its last digit (in base 10), and primes in base 10 in 1, 3, 7 or 9.

That egg art piece you made is sci fi af and incredible!!

Man this must've taken FOREVER to make with adobe software. Bloody amazing work, it looks beautiful! And very clearly explained

Excellent video! I'd be curious to see what would result from looking at the designs' inverses, that is to say, the connections that /aren't/ made might give some insight on those that are.

One of the best videos on fibonnacci, earned a new follower 🙏

These number sequences were known to Indian vedic scholors like Pingala and Varahamihira in 4th century BC, that is 2400 years ago. These sequences are the basis for Indian classical music Ragas. Acharya Hemachandra has compiled a tritise on these numbers and their use in the year 1150. Fibinnachi presented his work on these numbers in 1202

Slight amendment to 11:45 - moduli *can* be any real number. For x mod y, as you've explained, you subtract y from x as many times as possible and return the last positive number. Example: 5 mod 3/2 5 - 3/2 = 7/2 7/2 - 3/2 = 4/2 = 2 2 - 3/2 = 1/2 Therefore, 5 mod 3/2 = 1/2 Note that this is related to 5*2 mod 3, which is 1. If you take the Fibonacci sequence mod 7/3, it's the same as taking the fibonacci sequence*3 mod 7, except your resulting Pisano sequence will be divided by 3.

great video! how did you make these animations?

Great video! Does someone why there can be only 1,2 or 4 zeroes in the sequence at 7:12?

V interesting, lot of cool open problems too! I may come back to this...