Wow this is super interesting!

Pascal's triangle was one of the first programs I wrote in 1982 learning Pascal. It was just simple enough for a 13 years old child. And here we are, a PhD talks 25 minutes about it. In Math there is always so much more in every problem. I love it, thank you.

This is so insane how is this the first time I've ever seen this idea?

I was thinking 1/2 above 1 and alternating -1/2 and 1/2 on either side, since the triangle seemed symmetric.

Mind blown when he showed the original triangle rotated at the top

It's also fascinating that the symmetry of the bottom (classic) part of the triangle is broken -- arbitrarily, really -- by a decision about whether we read the coefficients right-to-left or conversely.

my smooth brain wanted a and b to both be equal to 1/2 or 0.5

Everywhere you look up new thing in Math it seems like beauty always emerge.

"What lies above Pascal's Triangle? Pascal's Triangle."

I once did the expansion while bored in class. It's nice now learning of proofs and further expansions, thanks!

This is honestly the first place I've seen the series expansion of (1+x)^-n for |x|>1 by leveraging the fact that (1+x)^-n = x^-n*(1+1/x)^-n, and it's one of those things that feels so obvious in hindsight, that it's hard to believe it never occurred to me before seeing this video

Never knew this pattern existed, great explanation cheers

Hi, great video! What's happening at the end there in terms of the doubly infinite series can actually be made sense of rigorously, if you're willing to ignore convergence. Just like you can write down formal power series with arbitrary coefficients while ignoring convergence, you can write down "doubly infinite formal Laurent series" with arbitrary coefficients in both directions while ignoring convergence. These things are no longer closed under multiplication so they don't form a ring, but you can still multiply such a series by a polynomial (even a Laurent polynomial), so they are still a *module* over polynomials (or even Laurent polynomials), and what your calculation is doing is repeatedly attempting to invert the operation of multiplication by (1 + x). The reason you get this 1-parameter family of choices when you try to extend upward is that multiplication by (1 + x) is not invertible (unlike in formal power series where it is invertible) - there's a series p(x) such that (1 + x) p(x) = 0, namely the series p(x) = sum_{n in Z} (-1)^n x^n, which has the property that if you multiply it by x you get -p(x)! This series can be interpreted as the "Dirac delta at x = -1," since it has the more general property that if f(x) is any polynomial then f(x) q(x) = f(-1) q(x). The fact that it has coefficients going off infinitely in both directions is related to what happens when you take the Fourier transform of the Dirac delta, and the fact that doubly infinite formal Laurent series aren't closed under multiplication is related to the fact that you can't multiply Dirac deltas together. So, every time you try to invert (1 + x) you end up with another 1-parameter family of choices you can make, because every time you have the freedom to add another multiple of p(x). (And it's exactly 1 parameter, not more; it's not hard to show the kernel of multiplication by (1 + x) is 1-dimensional with basis p(x).) Cheers, Qiaochu

Next time (1+x)^sqrt(2) ☺ Great video

I've always extended Pascal's Triangle in my mind as if there was an extremely tiny, infinitesimal chance that there was a glitch in the summation. So you start with an infinite hexagonal grid of 0s, each 0 the sum of two other zeros. Except randomly, at some point in the infinite expanse...there's a "glitch" and 0+0=1. And from that, the entire Pascal's Triangle is generated. Similarly: the Fibonacci series.

The final diagram with 3 separate scalar multiples of Pascal’s Triangles with 0s in between was truly beautiful. The proof (for the binomial coefficients doing that) was also extremely satisfying and cleanly done! I’ve also never seen expansions of real binomials for abs(x) > 1. Just wow!

When I did this in undergrad, i found that a = b = 1. Instead of extending with the addition rule, I used the n choose k formula for the coefficients and made the assumption that -1! would be some kind of undefined infinite value, but 1/-1! would be 0, and the factorial relation would be preserved. The pattern fills out like you would expect with a=b=1, but the reason why the addition rule breaks down at that spot is because the proof of the addition rule for n choose k would do a division by 0 at that spot. After that, I played around with higher dimensional pascal's triangles, which helps when you have the assumption that the outsides of the triangles/tetrahedrons are 0.

It is pascals triangle rotated 60 degrees with alternating forms of negative and positive numbers. So fascinating!

I am so happy that you've made this video, I looked this up a few years back and I'm happy that others can enjoy this concept!

This is remarkably well explained. Thank you from just a guy online who is interested in some math

This is utterly remarkable. How do such things work so well? It reminds me of extrapolating the notion of exponent from integer "counts" of multiplication out to negative and fractional exponents: just extend the additive arithmetic for whole exponents to any number, "pretending" that it still holds, and voila...

Amazing video! At everyone in the comments who is asking why he didn't talk about using 1/2 + 1/2 = 1... he did!! In the end of the video the purpose of generalizing to a and b is to allow you to choose ANY values of a and b that sum to 1, which includes 1/2! So just pause the video at the end and replace a and b both with 1/2 and you have the triangle you're asking for. It's certainly the most aesthetically pleasing and temtping choice, but to everyone insisting that symmetry is the most important property of pascal's triangle that needs to be preserved, I urge you to learn more about Pascal's triangle@ The really neat thing is he showed in the end basically that while there are many other exciting patterns to explore, the only choices for (a,b) that lead to convergent series expansions are (1,0) and (0,1). It's pretty freaking cool. Of course I wanted the "canonical" answer to involve 1/2 as well, that's human instinct, but it's delightfully charming when math gives us an ego check and reminds us there are much more unexpected ways for things to be beautiful. Ultimately I find the general form with a and b to be the most beautiful. It shows the perfect symmetry in its own way and represents an infinite spectrum of pascals triangles, precisely two of which have rows that represent valid convergent series expansions, and one of which is perfectly symmetrical. HOW COULD YOU NOT LOVE IT!!! 😍

Caught your video in recommended, didn't watch it in full but skipped ahead to 20:37 to get a sneak preview, I never thought about this, very interesting.

This is one of the two options, yes If you follow the / diagonal, a is 0 and b is 1 If you follow the \ diagonal, a is 1 and b is zero They're both the same, just flipped over the y axis

I read the title and think to myself,this is going to be boring. Then I watch the video. Wow man! Amazing !

You are sofa-king good at this I really hope you do this for the rest of your life. Recorded videos like this are forever. You're so good at this and there's no overhead but the upside to society in perpetuity is exponentially great ROI on this investment. Keep at it, please. This kind of content is what makes KZbin so amazing.

I was led to what lied above the Pascal Triangle by extending the Fibonacci number backwards from zero. (Be aware that the Fibonacci numbers are also obtained from Pascal Triangle) and then filled the missing upper layers. It turned out that if the bottom triangle is the expansion of (x+1) to the powers of n then the upper parts are the expansion of (x-1) to the powers of n. And also whereas the sum of the coefficients of every row is 2 to the power of n, those of the above sum to zero.

Many many thanks for this very nice and exhaustive video! The "expansion to the left" shown by you has also another possible interpretation, sliding the rows to make it look like an infinite square matrix. Then Pascal's original triangle is equal to the exponential of a particular "subdiagonal" matrix, i.e. a matrix having all zeroes on the main diagonal and {0, 1, 2, 3, ...} on the parallel diagonal situated one place lower. If we expand this diagonal also above with negative values, and exponentiate, we get Pascal's triangle expanded to the upper left.

Nice video and explanation :) How about doing a sequel on "What Lies Between Numbers in Pascal's Triangle"? Is there a continuous function that smoothly interpolates all the discrete values of Pascal's triangle, like how the gamma function interpolates discrete values of the factorial function?

Yes! Perfect way to spend this beautiful Friday morning, accompanying my cup of tea, toast, and bowl of porridge 😊

Great video, I learned a lot through this! Another very interesting thing I see in this expansion is the fact that it simultaneously also displays the binomial expansion for the term (1 - x)^n, so for example n=2: 1 - 2x + x² n=3: 1 - 3x + 3x² + x³ n=4: 1 - 4x + 6x² - 4x³ + x⁴ and so on.

The rotated triangle thing was quite the plot twist!

Truly interesting! Also you speak so naturally, clearly and fluently. I'm just terrified of people who write x as an inverted c and c put together.

22:53 I think that’s a brilliant maths quote: ‘bearing in mind that this isn’t actually going to be valid for any values’ but we’ll just keep going anyway cus it’s interesting!

Whats interesting is that if you add up all the numbers in the nth row in Pascal's Triangle, you get 2^n For example, 1 3 3 1 is the third row and 1+3+3+1 = 2^3 = 8. But at the -1st row at 4:18, you get zeros on the left and 1-1+1-1+... on the right, which is Grandi's series which "evaluates" to 1/2, which is 2^-1, and I can assume that the other negative rows "evaluate" to 2^n as well.

Legend says that way off in the distance to the right, there is another triangle. The whole thing is a triforce, if you will. The bottom left, the original, is the triforce of power. The top, above the first, is wisdom. The third is only legendary, yet hypothetically possible with the oddity that is named infinity. Its name? Courage.

Been a long time since my math undergrad, and this just reminded me why I fell in love with it. What a cool generalization

I don't know why I'm here and why I watched it all, but thanks, i loved it

I would like to note that this generalization preserves in a certain way the property that the sum of the terms of the n'th row is 2^n (starting to count from the 0'th row). If you consider Ramanujan sumation, then this property actually holds for negative n.

This is insane! I was bored through a couple math classes, so my paper was filled with this exact idea a couple months ago!

Very cool. Pascal’s simplices are some of my favorite patterns in mathematics, so this is very cool. It also gives an argument for why the sum 1-1+1-1+… “converges” to 1/2 in some contexts.

Incredibly clean presentation! I love your style.

Math is so beautiful. Somethimes I wish I had studied Math in university. But then again, I can just enjoy the beauty of Math at home through videos like this.

I am interested but not well educated in math and this sort of succinct explanation of an interesting (to me emergent) phenomenon always blows my mind. I don't know whether I'd use any takeaways in life but am pleasantly surprised by youtube suggesting this :)

Veritasium also made a video about this and it was about Newton and π. He figured out that you could squeeze fractional values between the integers. He had invented integrals and he could combine these ideas to calculate π as an infinite sum

Excellent video! This is the first time I’ve seen the rest of Pascal’s Triangle explored. I got out the popcorn when I saw the 1, -2, 3, -4, …. appear. This gon b gud. 🤓

What a coincidence! I thought of this like a week ago haha. Very nice explanation!!

What if we start with a = b = 0.5? I started to explore this myself. All of the numbers in the row have a fixed power of two as the denominator, e.g., 1/2 for row -1, 1/4 for row -2, etc.. But each numerator row is a series of numbers I have not seen before: Each series is symmetrical, extending to infinity in both directions. Looking only at the right side, I see: Row 0: 1 0 0 0 0 ... Row -1: 1 -1 1 -1 ... Row -2: 1 -3 5 -6 ... Row -3: 1 -7 17 -29 ... Row -4: 1 -15 49 -107 ... What are these numbers? They are derived from b = 2*c-a, where c is the number below and to the right of a we can simplify things by turning the isosceles triangle into a right triangle: 1 1 1 1 2 1 1 3 3 1 ...

Never thought about what's above the Pascal's triangle! Cool!

This is eye opening, I thought that Pascal's Triangle *MUST* be symmetrical

This is absolutely beautiful. Thanks for showing this! ❤

I'm simply mindblown. Great video man!

This was very fascinating! Great video!

I wish my math classes had been this fascinating!

Apparently, the Almighty Algorithm© has decided to finally show your videos to me! The first one was your recent _Why Is This Almost An Integer_ which I found fascinating as it was talking about this mathematical quirk I'd never heard about. This one, too, was fascinating. I think I have casually thought about these areas outside of the classical triangle but never followed up on it. It's astounding what turns up exploring Pascal's Triangle which, in the way we know it, is a rather simple, almost trivial, concept. Now, I'm curious about your other videos!

Never had this question. But very interesting to see. Thanks a lot!

I didn't expect this video to be this interesting

うわっすっごいな。目から鱗でした。

I can't believe this, it's amazing how math can always shock you with new things with just simple things

Wow, that is extremely cool and absolutely not what I expected.

this shit crazy, you rotate it 120 degrees either side, resulting in 6 hexants (6 triangles in a hexagon) 1. the OG Pascal triangle 2, 4, 6. the Zeroes triangles 3&5. the As and Bs Pascal triangles, similar to the og triangle except for the alternative change between positive and negative values, depending on if it's seperated by even or odd number of zeroes

The upper extension of Pascal's can be rewritten very much like the usual triangle, except that the numbers down the left hand side oscillate between 1 and -1, the numbers down the right hand side are all 1 as usual, and all the other numbers within the triangle are found by subtracting the number above to the right from the number above on the left.

superb! Have to reurn to absorb the points made during the last section (regarding a and b). Many thanks,

That's a very beautiful result.

fantastically fascinating! a mathematical masterpiece!

I remember extending the Pascal triangle upwards on a whim in high school math, but I did not at all understand that the numbers (after arbitrarily going with 0 1 though I don't remember which direction I went in) correspond to these coefficients. It's really very beautiful.

Question: can we fill in-between the lines too? As in, can we think of a natural way to fill, say, the 1/2-th line?

Very cool, thanks for sharing this!

Together with the relationship between Pascals and Sirpinskis triangle, that gives every odd number in the Pascal Triangle a certain color and every even number another certain color, resulting in a Sirpinski-Triangle-Looking-Pattern, this expansion to "what lies above" gives the Sirpinski a somewhat zero-th iteration or just an miror image pattern. But in general, its cool, Pascals Triangle is 1 of my favorite math topics and now thanks for making it into an Hourglass. So if above Pascal triangle is just a fliped version of the triangle, its more like Pascals Hourglass. Or a rather distorted Hourglass as there are now infinite nonzero values to the right. Proof is 15:04 for the Hourglass. And as 18:49 says, the uper part of the Hourglass is bent to the side coresponding to if |x|>1 or |x|1 or |x|1 or |x|

Beautiful idea! Thanks for sharing!!

Amazing! Thanks for the wonderful explanation.

Well he used for the rotated Pascal triangle the binomial expansion of (1+x)^(-n) = sum from k = 0 to infinity of (-1)^k *((n+k-1) choose k)*x^(k) for |x|

literally gasped at the rotated triangle reveal

i remember when i was like 10 and super bored i extended it this exact way (without the binomial expansion obviously, i just did it by accident) i thought of it like a rotated, half negated version of it. i also thought it was kinda like being zoomed infinitely into the Sierpinski triangle (i liked fractals back then)

Handsome guy with interesting smart content! Subbed! 😂

Blaise in Maths Heaven is smiling seeing this presentation!

Have you just explained at 16:35 why this binomial series are usable in counting partitions using generating functions?

That is wonderful! Is that original with you? Whether it is or not, you've made a video that tickles my math brain in a lovely way, Thank you very very. This is also a cellular automaton. Have you tried complex numbers for a and b?

Really interesting and amenelly told, thanks!

This is way above my level of understand of maths but I enjoyed it, still.

Wow, I had no idea. Truly a new perspective.

The coefficients a and b can be chosen to make the two series converge around an arbitrary point, making this a recipe for a laurent series expansion of the expression

Excellent! Who originally discovered this?

is that pascal's triangle but for (a-b)² ?

There are a few ways you could expand it based on a rule. Maybe you are interested in the fibonacci sequence expansion going backwards too. Also valid, since that sequence extends in both directions.

The similarity of the two triangles indicates that you could extend the nCr operation to negative values of n, by mapping them to the positive domain. Formally, (-n C k) = (-1)^k * ((n - k) C k) I vaguely recognize that, might have learned it in combinatorics class! It could be useful for some applications of generating functions

Very amazing thank you very much Dr Barker 😊🎉

The case of |x| < 1 and |x| > 1 are both handled here, but what about |x| = 1?

Awesome! Kp it up with these cool math videos!❤❤❤

Very cool stuff on friday 🙂

To be honest i think the topic could be explored with much more fun. With excel (or google sheets) you can just experiment directly with the number. It's obvious that you can select one number in each row arbitrary (useful to set them at the center or directly around it). I was trying to preserve another property of triangle - symmetry (selected 0.5+0.5 to construct top most 1). Experimenting around it's quickly become obvious that if you set all other rows to zero at the center you'll get a nice pattern of inverted triangle of zeros. And all non-zero values forms two Pascal's triangles with all values divided by 2 and oscillating signs. Diagonals of "1" continues as diagonals of "0.5". And if you change one 0.5 to 1 (or to 0) then you'll lose symmetry but you'll get copy of original triangle on one side an just zeros on the other, which is kinda neat... Why bother with binominals at all?

I always wondered this and it's a super interesting result

Just noticed also that the sum of elements in a row of Pascal's triangle is the corresponding power of 2. The row at n = -1, you've established should be defined as alternating 1 and -1, and the power of 2 would be 1/2. The agrees with the value of an L-function under analytic continuation that would correspond to 1-1+1-1+... "=" 1/2

@12:58 - What does W.T.S. stand for?

Very cool! I wonder about deferent triangles one might make. I discovered in 5th grade that the difference of the power series for the N-th power eventually yields N! after N iterations.

A fun thing to do is to replace the outer rows of 1s with different patterns. Similarly, you can use the rules of pascal's triangle to reconstruct the upper layers given a "seed" cluster of numbers from some arbitrary layer.

20:32 The triangle is very regular, I can definitely see lines. Very nice, mine are always a little off

Well I'm amazed. What an incredible finish! A and B as coefficients that satisfy (a+b = 1), but for which X is undefined. Could there be complex values of X where there's a valid solution?

i always thought the "typical" way of writing things was x^n+....+1, so id have said the last 1 (the one on the far right) represented the constant, not the first (far left). obviously its symmetric so it doesnt matter and you can just do this "backwards" really cool lil proof i never thought about!!

The extension above the "standard: Pascals triangle where the sum of the a and b values do not converge as you show, reminds me of the analytic extension "trick" that is used in, say the Reimann Zeta function. I'm sure that is not accurate, but it does seem as if there is an analogous process going on here.