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Math could not have been represented in a more interesting way. The fact that he solved and created a interdimensional portal using math felt unreal
Glorious.

I followed SOME of the math there.

Like Nolan's movies have, is there an "explainer" or a for dummies narration of what's going on here?

It’s all about imaginary numbers, the basic trig functions, Euler’s identity, and the relationships between them. Theses all related ways of talking about rotations. The imaginary numbers are on a number line perpendicular to the real numbers, so a multiplication by i is a 90° rotation, or a quarter turn. We can compute rotations by some other angle θ using the formula cos(θ) + i sin(θ). Euler proved that this is entirely equivalent to e^iθ as long as the angle θ is in radians. A 180° rotation (a half turn) is equal to a rotation by π radians, so cos(π) + i sin(π) = e^iπ. If you start at 1 and rotate by 180° you end up at −1, so e^iπ = −1.

e^iπ multiplies itself by i several times in order to teleport away from the animated stick figure. This works because ie^iπ = i−1 = −i, putting it in the imaginary plane below the reals. You might also notice that both e^iπ and the stick figure are hit by flying minus signs, which flip them horizontally and/or cause them to run in the opposite direction.

In the video, when e^iπ starts to defend itself it transforms into the equivalent infinite sum e^x = Σ (x^n)/n!. This is a much scarier version of the formula, but it just allows you to compute e^x using basic arithmetic. Written as an infinite sum it looks like (x^1)/1! + (x^2)/2! + (x^3)/3! + (x^4)/4! + (x^5)/5! + …. The projectiles that these flying sums fire are just the decimal expansion of successive terms of this sequence.

The animation fires back by building a gun out of the sin(x)/cos(x) function, also known as tan(x). The tangent of π radians is zero, so a hit from this weapon is very effective against e^iπ.

After the stick figure and e^iπ stop fighting, the stick figure asks e^iπ if he can be returned to his own reality, using the analogy of multiplying himself by iπ. e^iπ demonstrates multiplying himself by i⁴ (aka multiplying by 1) to teleport to his own location, but that won’t really help the stick figure. e^iπ does some more complicated math involving an infinite sum which uses the gamma function, but unless this part is beyond me then the author of the video is taking a bit of liberty in the interpretation. Even after all the manipulations of the formula, it still just computes e^iπ, which as we know equals −1. It shouldn’t do anything special, but it’s fun.

e^iπ is seen walking away with the Riemann Zeta function, the golden ratio, and a giant aleph. All of these are fun mathematical concepts which aren’t otherwise involved in the video; the stick figure didn’t happen to discover them in his brief visit.

I found this via my YouTube recommendations today:

Seems to be a reasonable attempt at explaining all the references in that original video --

https://youtu.be/tbqU9APUuYI

That was really fun. Play it again!