If you missed the first video in the series, you can watch me and grant take part in 'Maths Speed Dating' here: ruclips.net/video/Xh2LVy7B5q0/видео.html
I love the way you guys presented this, showing that math is a human endeavor, that even the brightest among us can be momentary “fooled” and be humble and enthusiastic about it.
I just don't know. Whenever I see grant I am filled with this calm feeling. I really like his personality and vibe. I wish I was that gentle and soothing. I really do.
Mr. Grant also covered this topic in one of his lock-down series, good to see Mr. Tom collabed on same topic, it refreshes a lot things. Surely one of the rare topic we can get over internet so precisely :)
I love how this puzzle links to iterated maps and dynamical systems! At first the connection isn't obvious but then Grant brings in the idea of seeing it as a function being repeated. This allows one to bring in the machinery of iterated maps and dynamical systems. As a novice of the said topics, it was nice to realise that one of the solutions is stable and the other is unstable and they coalesce in the form of a saddle node bifurcation at the value found in the video.
Grant's a Conservative. That's the proper way of constituting a family. (the freaks that like to behave out of Judeo-Christian ethics could all gather in their own country and disintegrate there by themselves)
hi tom. the lower bound of the base is exp(-e), a proof can be found in a mock exam that i co-authored. BoS Trials, 2019 Mathematics Extension 1, Q13 (a)
"To solve an equation, you have to know that the equation has a solution" would be fitting for both videos seeing as it is precisely one of open problems of Navier-Stokes equations!
9:46 That would appear to intersect at x=4, actually. But if you tried to approach it, you can’t because it’s like an unstable equilibrium. The fact remains that sqrt(2)^4 = 4.
It's true that it is an intersection point, but the iterative procedure that Grant defines will never end up there (unless you start at exactly that point).
Blackpen. Redpen made it in a different way with the limits of convergence for both x n y values . More over still there is more to tell in this videos at least showing the case where a to the power of x crosses the y=x twice when we would be facing that bounded area between the curve n the y=x . Can we even think of integration !!!
Great vid! Another way to quickly find the range of convergence is to plot the y=x^y graph. That's using the fact that x^x^... = y. You will find that the only x's that satisfy that equation are in (0 ; e^(1/e)]
@@aprendiendoC By graphing y=x^y you get a curve that is equivalent to x=y^x (which defines a real function f). We are looking for a subdomain in which this function is inyective beacuse x^x^...= y defined as a limit must be unique (a limit can`t have multiple values). It turns out that that subdomain is (0; argmax(f)] where argmax(f) turns out to be e^(1/e) by just using standard calculus tools.
@@TomRocksMaths could I by any chance talk to you about the Navier-Stokes equations, I have some ideas about them and would like to bring them to an expert. My email is ejhoman92@gmail.com
As Grant mentions at the end of the video, it is an intersection point yes, BUT it is what we call 'unstable' which means that the 'power tower' process will never converge to it unless you start on exactly that point. Initiating the sequence from any other value will see you either go to 2 (as it is a stable point) or to infinity. If you look up 'cobweb maps' you should get more of an idea about what's happening.
Currently in calculus so it was cool to use it to solve this puzzle! I did f(x) = a^x *f(c)* = a^c = *c* a = c^(1/c) *f'(c)* = a^c • ln(a) = *1* c • ln(c^(1/c)) = 1 ln(c) = 1 c = e a = e^(1/e)
the domain max of x^y=y is the range max of y^x=x, which is point e,e^(1/e) by the first and second derivative tests (they get messy). So the domain max of the original x^y=y is e^(1/e)~1.44466, which maps to e.
So if you look at the graph at 9:37, you can see why the answer of sqrt(2) popped out for the second equation. If you start with c_0=4, you'll be at a stable state and will continue getting 4.
I remember doing this question in high school, and the way I tackled it was. x^x^x… = 2 => log2(x^x…) = log2(2) => x^x^x… * log2(x) = 1 => 2 * log2(x) = 1 => log2(x) = 1/2 => x = 2^(1/2) That’s how I got sqrt(2) haha
i think i watched a video some time ago saying that if x^x^x^x.... converges, it converges to -W(-ln(x))/ln(x) (or something like that) where W is lambert's w function.
Yes, that’s correct x^x^x^x^x... = LambertW(-ln(x))/-ln(x) Ther answer will only be finite for x=(0, e^(1/e)] or (0, ~1.44466786] A power tower of e^(1/e) will converge to e. Anything greater than that will diverge to infinity.
this is so far above my level and yet i thoroughly enjoyed the whole thing, hopefull one day i will be able to see this and understand what all your maths means lmao
It wasn't explicitly stated, but the way in which function f was defined means x^x^x^x ^... means x^(x^(x^(x^(...)))) Does that mean the ^ operator is taken to be right associative? I think it does. By contrast, had they defined f(x) as return x**sqrt(2), then that would mean they're treating exponentiation as left associative.
I don't think the expression x^x^x^x^... really has a standard interpretation, but when you write it as a tower as in the video it's unambiguously right associative. Regardless, the left associative version is pretty boring. The n-th iterate just becomes x_0^(a^n), which has very easily analyzed behavior (you can end up with either 0, 1, x_0, infinity, or a simple period 2 oscillation).
x=4 seems to be the other intersection point of the graph, if you start your iteration at e.g. 2.5 instead of starting at 1, i think it would instead converge to 4 maybe? and then if you start iterating above 4 then it blows up. does it have to be just the first intersection? sqrt(2)^x = x has 2 solutions at x=2 and x=4
Okay, but at 9:37 you show that graph with a = √2, and it intersects at 2 **and at 4**. Why do we say that x^x^x^x^x^… is equal to 2 in that case instead of the other possible solution; why do we have to start at 1 instead of some other place where it converges to 4? (I assume this has something to do with 1 being the multiplicative identity and everything, but it still seems like there should be *some* way to express that the less-preferred solution is 4 or something)
The Taylor expansion of sqrt(2)^(4+x) begins 4 + xlog(4) + ... . Since log(4) is greater than 1 this means that if you start with a point near 4 it will move *away* from 4 when you apply the function. Whereas if you start with a point near 2 it will move towards 2. So 2 is a stable equilibrium and 4 is unstable.
We really just need to start at sqrt(2). To see what happens to x^x^x... when x=sqrt(2), we set f(x)=sqrt(2)^x. Then f(sqrt(2)) = sqrt(2)^sqrt(2). And f(answer) = sqrt(2)^sqrt(2)^sqr(2) {somewhat ambiguous, but this problem means sqrt(2)^(sqrt(2)^sqrt(2))}. Keep taking f(answer) to check convergence. But note that starting at x=1 gives the same tower, but just one iteration behind. (And it's easier to change bases but start at x=1 for a general principle.) So there is nowhere else to start if you want to check convergence of x^x^x... at sqrt(2) using iterations of the function f(x)=sqrt(2)^x.
Isn't there a mistake? (1) ln(a)*a^x = 1 (2) a^x = 1/(ln(a)) (3) x = ln(1/(ln(a))) If you apply ln to both sides on line (2), and since ln(a^x) = x*ln(a), shouldn't line (3) be: x = ln(1/(ln(a)))/ln(a) ???
There could well be, but fortunately we didn't actually use that part in the final calculation! As we show in the video the limiting value for convergence is e^(1/e)
@Tom @3B1B I found a brilliant idea to show the lower and upper bound for a for the function a^(x) there will be two bounds naturally, the lower bound is when the curve y=x is normal to the curve a^x and the upper bound is when the curve y=x is tangent to the curve a^x. Find out the rest :3
when he said I didnt think about this earlier and we would have to figure it on the way I thought it would some scripted moment but am genuinely happy that it took longer this has happened to me on many occasions but thats the interesting part, the brainstorming
You can also ask yourself “To what power do you have to take sqrt2 to exceed 2 and how would you reach that value?” which would give you a contradiction, given you start at something smaller than 2.
Interesting idea, but I'm not sure it works quite like that... you have to be very careful when dealing with the concept of infinity, which is what Grant is hinting at when explaining the idea of defining a function that converges to 2.
i was wondering about this too, but the problem is that exponentiation isn’t associative, which means that you can’t move parentheses around without changing the result. in the video, they are talking about: x^(x^(x^(x^(x… which, for example, is not equal to: (x^x)^(x^x)^(x^x)… nor is it equal to: (x^x^x^x…)^(x^x^x^x…) which would be equal to 4 for x = √2. i thought i could be clever, so i tried rewriting the python code in the video starting with the function: >>> def f(x): return x**x but iterating this with √2 just puts larger and larger inputs into x**x. if you draw out the cobweb diagram for this, you see that it only converges for (real, non-negative) x < 1, with x = 1 being the only value for which x^x = x. all other negative/complex inputs seem to converge to 1??? (assuming you force the complex arguments to lie between -pi < Arg(z) < +pi)
Are we just not going to talk about the fact that the graph of y= sqrt(2)^x and y= x also intersect at the value of 4? Because I really wanted you to bring that home.
We know ln(a)*a^x_0 = 1, but a^x_0 = x_0 since the graphs y = x and y = a^x intersect at that point i.e they have the same outputs. And since the output of y = x when we input x_0 is x_0, so is the one from a^x (a^x_0 = x_0). In other words, at that exact point a^x outputs its input(x_0) because it intersects y = x.
In terms of integer tetrations greater than 2, e.g. x^x^x, there is no general inverse like we have for the cases at 1,2, and infinity. It's transcendental. However, I've seen that it's possible to extend the inverse of the function (specifically the "super-root" inverse, instead of the logarithmic one) to these by using an extended form of the W-Lambert function. There's also no elementary integral, but I found the derivative of the integer case expressed in terms of the previous derivative. As far as I could tell and with my methods I couldn't find a neat universal form to express it, but the form I could express it in was quite simple and elegant. I'll paste it here if you're interested. As far as the integral is concerned, I currently have no idea. Do you have any knowledge on how to analyse these functions? Is there anything we can do with non-elementary/transcendental functions to generally work with them (maybe through series expressions?)? Thanks.
Aren't the first 2 proofs also correct? Because the statements you proved were "If [x^(x^(x^(... ] = 4, then x = sqrt(2)" and "If [x^(x^(x^(... ] = 2, then x = sqrt(2)". Both are true statements, it's just that only one of the 2 hypotheses is true.
The idea is that only one of them is possible within the setup of the problem... this is what we are alluding to when talking about cobweb diagrams and stable/unstable points.
4 is a solution, but it is unstable which means the iterative process that grant talks about will never end up there unless you start at exactly that point. If you start at 4 + epsilon then you never get back to 4.
Thank you for taking the time to reply! Yeah i found the same question in other comments, and saw that you had replyed there :) im still not sure i understand it though 😅
I don't think you ever answered why it works for 2 and not 4! The answer is, you assumed the seed was 1. Since the value wasn't e^(1/e) where it crossed at exactly one point, there's two solutions. When you come from below 2 (like 1 is) you converge upto 2. When you come from above 4, you converge down to 4.
Actually you will diverge to infinity if you come from above 4 For example, starting with 5: Step 1: (2^(1/2))^5 ≈ 5,65 Step 2: (2^(1/2))^5,65 ≈ 7,10 Step 3: (2^(1/2))^7,10 ≈ 11,72 Step 4: (2^(1/2))^11,72 ≈ 58,17 Step 5: (2^(1/2))^58,17 ≈ 82,27
Actually it’s not a paradox. Cause you just prove that IF x^x......^x = 4 THEN x should be equal to sqrt(2). But you still have to verify that sqrt(2) is indeed a solution. It appears that is not so this equation has no solution.
This video changed my mind. It makes me think about the nature of infinity and the quantum nature of reality. I hope to write a paper and have you both as co-authors
Awww mr . Puppy dog ‘ s never going to understand any of the algebraic structures responsible for this iteratively natural construction …. Inverse function theorem . The question is whether it exists : this is an excellent logical demonstration of degeneracy Woof woof
@2:50 Over an algebraically closed field , one would most sensibly see that the composition of the exp and its inverse in an algebraically natural way is responsible for the composition : which is not natural … All of fourier analysis surrounds themes that will always ‘ sit beaneath ‘ this peak of iteration : If it ‘ s some random point on a wave , the problem sheet is what are the wave structures derived from the source - of - mind .
If you missed the first video in the series, you can watch me and grant take part in 'Maths Speed Dating' here: ruclips.net/video/Xh2LVy7B5q0/видео.html
I love the way you guys presented this, showing that math is a human endeavor, that even the brightest among us can be momentary “fooled” and be humble and enthusiastic about it.
I just don't know. Whenever I see grant I am filled with this calm feeling. I really like his personality and vibe. I wish I was that gentle and soothing. I really do.
This is beautiful - the humility and collegiality on display here is inspiring.
13:45 "What would it mean actually?" 😅 The way he said it made me smile.
Mr. Grant also covered this topic in one of his lock-down series, good to see Mr. Tom collabed on same topic, it refreshes a lot things. Surely one of the rare topic we can get over internet so precisely :)
Glad you enjoyed it :)
I love how this puzzle links to iterated maps and dynamical systems! At first the connection isn't obvious but then Grant brings in the idea of seeing it as a function being repeated. This allows one to bring in the machinery of iterated maps and dynamical systems. As a novice of the said topics, it was nice to realise that one of the solutions is stable and the other is unstable and they coalesce in the form of a saddle node bifurcation at the value found in the video.
Grant picked a great puzzle :)
This is so good! Love the collab!
Thanks Varun - glad you enjoyed it!
Two of the most attractive men in math
Bars down here bruv
Tom and the camera man? jkjk
love this joke
Tom is a freak
@@arlenestanton9955 you mean his piercings and tattoos?
Damn, Grant's wearing a wedding ring, I'm too late.
Polygamy is a thing. Now go for it!
Grant's a Conservative. That's the proper way of constituting a family. (the freaks that like to behave out of Judeo-Christian ethics could all gather in their own country and disintegrate there by themselves)
This is so above my level of knowledge and I thoroughly enjoyed watching you both talk through it.
as long as you had fun!
Two such great persons in maths and charismatic, hope to see more vids of these guys together.
hi tom. the lower bound of the base is exp(-e), a proof can be found in a mock exam that i co-authored. BoS Trials, 2019 Mathematics Extension 1, Q13 (a)
Awesome thanks Jack!
"To solve an equation, you have to know that the equation has a solution" would be fitting for both videos seeing as it is precisely one of open problems of Navier-Stokes equations!
9:46 That would appear to intersect at x=4, actually. But if you tried to approach it, you can’t because it’s like an unstable equilibrium. The fact remains that sqrt(2)^4 = 4.
It's true that it is an intersection point, but the iterative procedure that Grant defines will never end up there (unless you start at exactly that point).
Tom Rocks Maths Yeah, that’s what I meant by unstable equilibrium.
I like Dr Tom's glittering laughter.... Always...showing humility in mathematics! Ganbate kudasai !
Love these collabs with Grant :D
Towers in two math channels at the same time? This is a conspiracy. (⌐■_■)
This I did not know, which other channel??
@@TomRocksMaths numberphile :)
Clearly we are both right on topic without even realising it...
@@TomRocksMaths Also I think blackpenredpen
Blackpen. Redpen made it in a different way with the limits of convergence for both x n y values . More over still there is more to tell in this videos at least showing the case where a to the power of x crosses the y=x twice when we would be facing that bounded area between the curve n the y=x . Can we even think of integration !!!
Great vid! Another way to quickly find the range of convergence is to plot the y=x^y graph. That's using the fact that x^x^... = y. You will find that the only x's that satisfy that equation are in (0 ; e^(1/e)]
Nice!
I tried plotting y=x^y in Wolfram Alpha but I don't know where you get the result that the only x's that satisfy that equation are in (0 ; e^(1/e)]
@@aprendiendoC By graphing y=x^y you get a curve that is equivalent to x=y^x (which defines a real function f). We are looking for a subdomain in which this function is inyective beacuse x^x^...= y defined as a limit must be unique (a limit can`t have multiple values). It turns out that that subdomain is (0; argmax(f)] where argmax(f) turns out to be e^(1/e) by just using standard calculus tools.
You are making maths cool
Thanks Eric!!
@@TomRocksMaths could I by any chance talk to you about the Navier-Stokes equations, I have some ideas about them and would like to bring them to an expert. My email is ejhoman92@gmail.com
I dont know how i got here but I'm not disappointed
the YT algorithm works in mysterious ways
9:41 and 15:47 - 4 shows up as the other point where the graphs cross. Can you elaborate on whether it is, in some way, a valid solution?
As Grant mentions at the end of the video, it is an intersection point yes, BUT it is what we call 'unstable' which means that the 'power tower' process will never converge to it unless you start on exactly that point. Initiating the sequence from any other value will see you either go to 2 (as it is a stable point) or to infinity. If you look up 'cobweb maps' you should get more of an idea about what's happening.
@@TomRocksMaths Ah yep, thanks. So it's like why phi is 1.618 and not -0.618, cf ruclips.net/video/CfW845LNObM/видео.html
Thanks for this question and explanation. I can see now how the region of a(x) between 2 and 4 will cobweb back to 2.
Currently in calculus so it was cool to use it to solve this puzzle! I did
f(x) = a^x
*f(c)* = a^c = *c*
a = c^(1/c)
*f'(c)* = a^c • ln(a) = *1*
c • ln(c^(1/c)) = 1
ln(c) = 1
c = e
a = e^(1/e)
Math men math men
Math math math men men
With Tom Crawford and/or Grant Sanderson
LOVE this. What's the tune?
Check out Jay Foreman's series 'Map Men'
men
@@asheep7797 of course how could I have missed that
absolutly dope collabo
the domain max of x^y=y is the range max of y^x=x, which is point e,e^(1/e) by the first and second derivative tests (they get messy). So the domain max of the original x^y=y is e^(1/e)~1.44466, which maps to e.
So if you look at the graph at 9:37, you can see why the answer of sqrt(2) popped out for the second equation.
If you start with c_0=4, you'll be at a stable state and will continue getting 4.
Isn't that just a coincidence?
I love the fact that 2 and 4 is possible if you look at the graoh depending where u start u can get 2 or 4
I remember doing this question in high school, and the way I tackled it was.
x^x^x… = 2
=> log2(x^x…) = log2(2)
=> x^x^x… * log2(x) = 1
=> 2 * log2(x) = 1
=> log2(x) = 1/2
=> x = 2^(1/2)
That’s how I got sqrt(2) haha
so in general,
k^(1/k), k > 0
This is beautiful, what a great video!
Glad you enjoyed it!
i think i watched a video some time ago saying that if x^x^x^x.... converges, it converges to -W(-ln(x))/ln(x) (or something like that) where W is lambert's w function.
Yes, that’s correct
x^x^x^x^x... = LambertW(-ln(x))/-ln(x)
Ther answer will only be finite for x=(0, e^(1/e)] or (0, ~1.44466786]
A power tower of e^(1/e) will converge to e. Anything greater than that will diverge to infinity.
@@Eric4372 so cool. I love this obscure part of mathematics
Agreed!
This should be an Oxford Interview Question for students trying to apply for maths
if maths split into two personalities
Name that website you guys used for graphs pls
this is so far above my level and yet i thoroughly enjoyed the whole thing, hopefull one day i will be able to see this and understand what all your maths means lmao
It wasn't explicitly stated, but the way in which function f was defined means x^x^x^x ^... means x^(x^(x^(x^(...))))
Does that mean the ^ operator is taken to be right associative? I think it does.
By contrast, had they defined f(x) as return x**sqrt(2), then that would mean they're treating exponentiation as left associative.
I don't think the expression x^x^x^x^... really has a standard interpretation, but when you write it as a tower as in the video it's unambiguously right associative.
Regardless, the left associative version is pretty boring. The n-th iterate just becomes x_0^(a^n), which has very easily analyzed behavior (you can end up with either 0, 1, x_0, infinity, or a simple period 2 oscillation).
"The whole property of infinity is that, you add 1 and you don't change size" Wow, so simple
*add
I learned that an infinite set is defined as "any set for which there exists a one to one correspondence with a proper subset of that set."
@@letspass3465 thanks!
@@TIO540S1 cool!
x=4 seems to be the other intersection point of the graph, if you start your iteration at e.g. 2.5 instead of starting at 1, i think it would instead converge to 4 maybe? and then if you start iterating above 4 then it blows up. does it have to be just the first intersection?
sqrt(2)^x = x has 2 solutions at x=2 and x=4
The intersection point at x=4 is unstable when analysing it using cobweb maps, which is why that 'solution' isn't valid.
Okay, but at 9:37 you show that graph with a = √2, and it intersects at 2 **and at 4**. Why do we say that x^x^x^x^x^… is equal to 2 in that case instead of the other possible solution; why do we have to start at 1 instead of some other place where it converges to 4?
(I assume this has something to do with 1 being the multiplicative identity and everything, but it still seems like there should be *some* way to express that the less-preferred solution is 4 or something)
The Taylor expansion of sqrt(2)^(4+x) begins 4 + xlog(4) + ... . Since log(4) is greater than 1 this means that if you start with a point near 4 it will move *away* from 4 when you apply the function. Whereas if you start with a point near 2 it will move towards 2. So 2 is a stable equilibrium and 4 is unstable.
@@OscarCunningham Ah, that makes sesnse.
What he said ^^^^^ Thank you Oscar!
We really just need to start at sqrt(2). To see what happens to x^x^x... when x=sqrt(2), we set f(x)=sqrt(2)^x. Then f(sqrt(2)) = sqrt(2)^sqrt(2). And f(answer) = sqrt(2)^sqrt(2)^sqr(2) {somewhat ambiguous, but this problem means sqrt(2)^(sqrt(2)^sqrt(2))}. Keep taking f(answer) to check convergence. But note that starting at x=1 gives the same tower, but just one iteration behind.
(And it's easier to change bases but start at x=1 for a general principle.)
So there is nowhere else to start if you want to check convergence of x^x^x... at sqrt(2) using iterations of the function f(x)=sqrt(2)^x.
Isn't there a mistake?
(1) ln(a)*a^x = 1
(2) a^x = 1/(ln(a))
(3) x = ln(1/(ln(a)))
If you apply ln to both sides on line (2), and since ln(a^x) = x*ln(a), shouldn't line (3) be:
x = ln(1/(ln(a)))/ln(a)
???
There could well be, but fortunately we didn't actually use that part in the final calculation! As we show in the video the limiting value for convergence is e^(1/e)
@Tom @3B1B I found a brilliant idea to show the lower and upper bound for a for the function a^(x) there will be two bounds naturally, the lower bound is when the curve y=x is normal to the curve a^x and the upper bound is when the curve y=x is tangent to the curve a^x. Find out the rest :3
when he said I didnt think about this earlier and we would have to figure it on the way
I thought it would some scripted moment but am genuinely happy that it took longer
this has happened to me on many occasions but thats the interesting part, the brainstorming
this is awesome
Does this hold true for all n-dimension numbers, that there is a number where the power tower does not explode to infinity or go to zero?
Grant seems a lot less uncomfortable around Tom this time.
ARE YOU SURE ABOUT THAT
RIP bug.
I think he missed.
What bug
You can also ask yourself “To what power do you have to take sqrt2 to exceed 2 and how would you reach that value?” which would give you a contradiction, given you start at something smaller than 2.
Be careful - it doesn't quite work like that... for example, sqrt2 to the power 8 gives you 2^4.
@@TomRocksMaths Yeah, but to get to 8 in the first place you would need a value bigger than 2 to start with.
If we divide one tower into two we should still get 2 for both towers so 2^2 equals 4 right
Interesting idea, but I'm not sure it works quite like that... you have to be very careful when dealing with the concept of infinity, which is what Grant is hinting at when explaining the idea of defining a function that converges to 2.
@@TomRocksMaths thanks for the reply
i was wondering about this too, but the problem is that exponentiation isn’t associative, which means that you can’t move parentheses around without changing the result. in the video, they are talking about:
x^(x^(x^(x^(x…
which, for example, is not equal to:
(x^x)^(x^x)^(x^x)…
nor is it equal to:
(x^x^x^x…)^(x^x^x^x…)
which would be equal to 4 for x = √2. i thought i could be clever, so i tried rewriting the python code in the video starting with the function:
>>> def f(x): return x**x
but iterating this with √2 just puts larger and larger inputs into x**x. if you draw out the cobweb diagram for this, you see that it only converges for (real, non-negative) x < 1, with x = 1 being the only value for which x^x = x. all other negative/complex inputs seem to converge to 1??? (assuming you force the complex arguments to lie between -pi < Arg(z) < +pi)
@@channelnamechannel cool
@@channelnamechannel yes exactly!!!
Are we just not going to talk about the fact that the graph of y= sqrt(2)^x and y= x also intersect at the value of 4? Because I really wanted you to bring that home.
It is a fixed point yes, BUT it is unstable so the iterative procedure will never end up there unless you start at exactly that point.
Tetration (towers) remainds me about how to imagine Graham's Number. Cheers from Poland. 🇵🇱🍻
Hello Poland :)
12:51 where does ln(a)x_0 = 1 come from??? Why gloss over the derivation?
We know ln(a)*a^x_0 = 1, but a^x_0 = x_0 since the graphs y = x and y = a^x intersect at that point i.e they have the same outputs. And since the output of y = x when we input x_0 is x_0, so is the one from a^x (a^x_0 = x_0).
In other words, at that exact point a^x outputs its input(x_0) because it intersects y = x.
Great video (as always from both of you). Would you know which program was used to plot the curves?
Desmos - free on their website
6:39 here i understood that this had to do with the mandelbrot set and the population equation
Yes, that's another famous use of cobweb maps.
4 is a fixed point, of the iteration, just an unstable one.
Exactly.
In terms of integer tetrations greater than 2, e.g. x^x^x, there is no general inverse like we have for the cases at 1,2, and infinity. It's transcendental. However, I've seen that it's possible to extend the inverse of the function (specifically the "super-root" inverse, instead of the logarithmic one) to these by using an extended form of the W-Lambert function. There's also no elementary integral, but I found the derivative of the integer case expressed in terms of the previous derivative. As far as I could tell and with my methods I couldn't find a neat universal form to express it, but the form I could express it in was quite simple and elegant. I'll paste it here if you're interested. As far as the integral is concerned, I currently have no idea. Do you have any knowledge on how to analyse these functions? Is there anything we can do with non-elementary/transcendental functions to generally work with them (maybe through series expressions?)? Thanks.
Nice surname.
@@sergiokorochinsky49 You too
Aren't the first 2 proofs also correct? Because the statements you proved were "If [x^(x^(x^(... ] = 4, then x = sqrt(2)" and "If [x^(x^(x^(... ] = 2, then x = sqrt(2)". Both are true statements, it's just that only one of the 2 hypotheses is true.
The idea is that only one of them is possible within the setup of the problem... this is what we are alluding to when talking about cobweb diagrams and stable/unstable points.
so is it just a coincidence that the sqrt(2)^x graph intersect the y=x graph at 2 AND 4 ? 9:40
4 is a solution, but it is unstable which means the iterative process that grant talks about will never end up there unless you start at exactly that point. If you start at 4 + epsilon then you never get back to 4.
Thank you for taking the time to reply!
Yeah i found the same question in other comments, and saw that you had replyed there :) im still not sure i understand it though 😅
I don't think you ever answered why it works for 2 and not 4! The answer is, you assumed the seed was 1. Since the value wasn't e^(1/e) where it crossed at exactly one point, there's two solutions. When you come from below 2 (like 1 is) you converge upto 2. When you come from above 4, you converge down to 4.
Actually you will diverge to infinity if you come from above 4
For example, starting with 5:
Step 1: (2^(1/2))^5 ≈ 5,65
Step 2: (2^(1/2))^5,65 ≈ 7,10
Step 3: (2^(1/2))^7,10 ≈ 11,72
Step 4: (2^(1/2))^11,72 ≈ 58,17
Step 5: (2^(1/2))^58,17 ≈ 82,27
The 'solution' at 4 is an unstable point on the cobweb diagram which is why it will diverge.
I did not know 3blue1brown was human
can confirm
They didn't explain what was wronng with the 4 answer of the inteo
They did. You can't solve an equation before knowing if the solution exists or not.
Video Length 16:15
Golden Ratio 🤨🤨
And I thought no-one would spot it...
5:43 Pov: You joined the Matrix
hello nice to meet you
You too :)
Best Colab present in RUclips !!
Was quite easy though
At 2:32, x = Sqrt(sqrt2).
I think it's still sqrt(2) as we are taking 4 to the power of 1/4, which is the same as square rotting twice.
Filooooo, los amo
Actually it’s not a paradox. Cause you just prove that IF x^x......^x = 4 THEN x should be equal to sqrt(2). But you still have to verify that sqrt(2) is indeed a solution. It appears that is not so this equation has no solution.
if a = e^(1/e) then a^a^a^.... = e!!!
the felt tip pen noises kind of shredded inside my skull. great video otherwise.
This video changed my mind. It makes me think about the nature of infinity and the quantum nature of reality. I hope to write a paper and have you both as co-authors
Either way thanks for the inspiration. Maths is beautiful
they are math mates
we sure are!
Awww mr . Puppy dog ‘ s never going to understand any of the algebraic structures responsible for this iteratively natural construction ….
Inverse function theorem . The question is whether it exists : this is an excellent logical demonstration of degeneracy
Woof woof
@2:50
Over an algebraically closed field , one would most sensibly see that the composition of the exp and its inverse in an algebraically natural way is responsible for the composition : which is not natural …
All of fourier analysis surrounds themes that will always ‘ sit beaneath ‘ this peak of iteration :
If it ‘ s some random point on a wave , the problem sheet is what are the wave structures derived from the source - of - mind .
* this composition
* all of my
Great. Now kiss.
I understood nothing🤐
There is some terrible electronic noise throughout this
💙💙💙 OTP 🤎