This one’s really only for the Maths teachers of there. But I saw it and just had to reblog it! Awesome. SC.

Continuous Everywhere but Differentiable Nowhere

Today in Precalculus I went on a bit of a 7 minute digression, talking about continued fractions. You see, a recursive problem showed up (we’re doing sequences): Write out the first five terms of the following sequence:

$latex a_{n+1}=sqrt{2+a_n}$ where $latex a_1=sqrt{2}$

So obviously they go like: $latex a_1=sqrt{2}$,$latex a_2=sqrt{2+sqrt{2}}$, $latex a_3=sqrt{2+sqrt{2+sqrt{2}}}$, $latex a_4=sqrt{2+sqrt{2+sqrt{2+sqrt{2}}}}$, and $latex a_5=sqrt{2+sqrt{2+sqrt{2+sqrt{2+sqrt{2}}}}}$

So great. Awesome. NOT. *Booooring*. So I showed them the decimal expansions:

$latex approx 1.414, approx 1.848, approx 1.961, approx 1.990, approx 1.998, approx 1.999, approx 1.9998, approx 1.99996, approx 1.999991, approx 1.999997647$

WHOA! This is getting closer and closer to 2… Weiiiird…

And then I say I can show them this will continue, and we can find a way to show that $latex sqrt{2+sqrt{2+sqrt{2+sqrt{2+sqrt{2+…}}}}}$ [where the pattern continues *forever*] will practically become 2.

*DIGRESSION WHICH IS ACTUALLY WHY I WANTED TO BLOG ABOUT THIS*

To do this, I start with something else. I…

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