This should be a PBS sponsored channel for children interested in math. As an added bonus atop the super clear delivery style - that hat really slaps.

I love your videos, you are very articulate and explain math in a way that is simple to understand. Keep up the good work!

Using your video about the w lambert function, I was able to derive a general formula for x^^2 (a.k.a. x^x) = y and was able to solve this equation much faster, thank you soo much for your help

It was going so well until around 8:20 when we get this misunderstanding: _"The actual answer is the positive version, not the negative version, because the negative version will give you imaginary numbers and remember what we want are just the real numbers_ (pointing to 'Find all real solutions' on the board)". The negative "solution" is a real number, so that's not the problem. The problem is simply that if you substitute -1.77 for x, you don't get 216, so the negative value _is not a solution at all._ I hope you can see the difference. Next we had a blatant error: "So if you have a negative number raised to a negative number for whatever reason as long as long as that negative number is not an integer you will always get imaginary answers." That's simply not true. Consider (-1/3)^(-1/3) = cube root of 3. I think we can agree that 1/3 is not an integer, nor is 3^(1/3) imaginary? Similarly for (-0.2)^(-0.2) or any number of the form -1/(2n+1) where n is a natural number. Finally, it's important when you're finding _all_ solutions to remember that the Lambert-W function is multivalued. Fortunately, all but the principal value of W(ln(36)) appear to be complex, -but I can't guarantee that there are no other real solutions.- Edit: I realised that the two values for branches 0 and -1 are sufficient when dealing with reals, and the latter turns out to be complex in this case.

Fixed-point iteration is the simplest solution method: 3x^2*lnx=ln216; x=√[(ln216/3)/lnx] x←√[(ln216/3)/lnx] yields x=1.7707... A negative x would require 3x^2 to be a multiple of 2, which would not satisfy the given equation.

New Brazilian follower here!

Very well explained. You connect with the viewers very well.

My dawg just snuck in the sqrt... lol

Interesting video. On a pedantic note, 8:26, a negative number raised to a negative rational number with an odd denominator will have a real solution. (Doesn't apply to the present problem.)

I've always known math can be almost unimaginably complex, but I've seen some shit on this channel I've never dreamed of imagining. It just keeps getting more and more interesting. 😎😎

Nice one, please represent the square root very well, excellent teaching from you.

Lol dont think I didnt notice that fade in at 7:52

Anyone please find the error: I jump at 3:05: where x^x = 6^(1/2); after following power & reduction, => x= 6^(1/6), which does not match with answer.

No problem ... but there's just one problem LOL - love it. Almost as much as I love that magic /2 that appears. Good job. I almost got through it myself, but now I need to go refresh that W stuff in my head. Thank you.

Please tell a method to calculate the W of integers manually ... It will be really helpful ... Please ..

I didn't see the solution at first, but when you got to 5:07 I had the aha moment. Love the video.

Enjoyed yer style and info.very useful

Flower? I only know about the fish that if you multiply it by e raised to the power of the same fish and use the w function, you get the fish back

What a performance in maths. Thank-you.

How did you choose the value of W?

amazing video!!!!

Please make a video on Newton's method

Why did you developed the equation and did not apply the productlog in the original equation? It was very clear since the beginning that you may need to use the productlog so it will be easier to reshape the original equation to use productlog….or I am wrong?

how a glorious video

hey in this math prb cant we use a to the power a equalsb to the power b then a=b? that way we get x= square root 6??

2^(3•2^2)=4096; log (216)=2,334; (216)^1/6=2,4494 2,4494 - 2,3344=0,115 (0,115)^1/6=0,697 2,449•0,697=1,707 1,707^(3•1,707^2)=107,17 1,77^(3•1,77^2)=214,10 1,77078^(3•1,77078^2)=216,0 x=1,77078

Very good. Thanks Sir

very nice master!

This problem solving consists of an analysis solution and a numerical solution .

From x^x^2 = 6: x^2 lnx = ln6; ln x e^ ln (x^2) = ln6; ln x e^2 ln x =ln 6; 2ln x e^(2 ln x) = 2 ln 6; W (2ln x e^(2 ln x)) = 2ln 6; 2 ln x = W (2ln 6); ln x =[ W (2 ln 6)]/2 Minus is dissapeared! Is it right?

Can you help me x^(1-x) - x = 32? Thank you so much!

Aren’t there three cube roots of 216?

I got stuck at t^t = 6^2, Don't know what W function was supposed to mean

Une solution unique > e^(-0,5)

🎉🎉🎉

x^3x^2=6^3 x^x^2=6

very nice, but if you introduce the ln since x^x^2=6, you have only the positive result

wow bravissimo

You forget the root in the last line.

What is W(ln 36) ? i.e ln(36) / e^ln(y) age 68 so not a child :-)

English speakers need to understand that using the W function is NOT solving the problem

How could I have known that I had to sqare both sides in the step that yields the 36 as a result? Guessing it? I think math is sometimes indeed to hard for me. Or haven't I seen enough of these examples to be capable of guessing the right calculation path? Smh!

BOOOO! Lambert W function never feels like a solution to me. I had a thought though. if t^3 = 216, it doesn't mean that t must be 6. Rather, (t - 6)*(t^2 + 6t + 36) = 0, which allows for two other solutions. As it turns out, those other solutions aren't real, so we can discard them. But, it's good to be aware of them.