So I just finished watching an [interesting video]. It basically shows that the function

${\displaystyle f(x)={\sqrt[{\phi }]{\phi ^{-1}}}x^{\phi }}$

has an unusual property. The derivative

${\displaystyle f'(x)=\phi {\sqrt[{\phi }]{\phi ^{-1}}}x^{\phi ^{-1}}}$

is equivalent to the compositional inverse of ${\displaystyle f(x)}$. In other words ${\displaystyle x=f'(f(x))}$.

For some reason that strikes me as quite amazing. Has this function been well studied? I can't think of any good search terms that might help either. Earl of Arundel (talk) 21:53, 2 June 2021 (UTC)[reply]

(Note that ${\displaystyle \phi }$ stands for the golden ratio 1.61803···.) There is a mistake above in the exponent of ${\displaystyle x}$ in the rhs for the derivative; ${\displaystyle x^{\phi ^{-1}}}$ should be ${\displaystyle x^{\phi -1}.}$ I don't think this has function been studied to any degree; it strikes me as an isolated curiosity. By playing around a bit you can derive strange identities such as

${\displaystyle {\frac {d}{dx}}f(f(x))=xf'(x)}$

and

${\displaystyle f''(f(x))=(f'(x))^{{-}1},}$

but I spotted nothing that seemed to tie in with other stuff in the web of interesting mathematics. Differential equations often have a physical interpretation, but this function is necessarily between dimensionless domains.  --Lambiam 22:47, 2 June 2021 (UTC)[reply]

"${\displaystyle x^{\phi ^{-1}}}$ should be ${\displaystyle x^{\phi -1}}$" In fact ${\displaystyle \phi ^{-1}=\phi -1}$. (Indeed it's this coincidence that makes the example work.) --JBL (talk) 23:44, 2 June 2021 (UTC)[reply]

Tricky ${\displaystyle \phi }$ strikes again! Earl of Arundel (talk) 01:07, 3 June 2021 (UTC)[reply]

Also, the equation ${\displaystyle f(x)=f'(x)}$ in the unknown ${\displaystyle x}$ has two solutions (in the nonnegative reals):

${\displaystyle f(0)\,=f'(0)=0,}$

${\displaystyle f(\phi )=f'(\phi )=\phi .}$

 --Lambiam 23:01, 2 June 2021 (UTC)[reply]

Ok so basically just an interesting curiosity. Now when you say "dimensionless", what exactly do you mean by that? Considering that the input and output of the function map to a two dimensional space that just seems like a very enigmatic statement. Earl of Arundel (talk) 01:07, 3 June 2021 (UTC)[reply]

2D space? Not just ${\displaystyle \mathbb {R} }$?

In the sense of dimensional analysis, as in Dimensionless quantity. (I am not endorsing Lambiam's claim -- I haven't thought about it at all -- but that's the sense being invoked.) --JBL (talk) 02:35, 3 June 2021 (UTC)[reply]

In my reply I used "[[dimensionless]]", which redirects to Dimensionless quantity. If the position of a physical object is given as a length quantity as a function of a time quantity, the position function maps T-quantities to L-quantities, or, for short, T to L. Its inverse, time as a function of position, maps L to T. Its derivative, the speed of the object, maps T to LT⁻¹. This generalizes to arbitrary dimensions. Let ${\displaystyle f}$ be a function mapping X to Y, where X and Y are dimensions (possibly 1, the dimemsion of dimensionless quantities). Then ${\displaystyle f^{{-}1}}$ maps Y to X and ${\displaystyle f'}$ maps X to YX⁻¹. So if now ${\displaystyle f'=f^{{-}1},}$ this function both maps Y to X and X to YX⁻¹, which gives us two equations: Y = X and X = YX⁻¹. Using the first of these to substitute X for Y in the second gives us X = 1, and so also Y = 1. Our function ${\displaystyle f}$ is a map between dimensionless quantities.  --Lambiam 07:53, 3 June 2021 (UTC)[reply]

Well that truly IS mind-bending! (And brilliantly explained, I might add.) It might take a while for all of that to sink in anyhow. So that's vaguely analogous to how ${\displaystyle g(x)=g'(x)=e^{x}}$. I wonder if the two functions are somehow connected. Or is that a bit of a stretch? Earl of Arundel (talk) 18:42, 3 June 2021 (UTC)[reply]

On second thought, maybe not. (Considering that ${\displaystyle g^{{-}1}(x)=ln(x)}$ .) Earl of Arundel (talk) 18:51, 3 June 2021 (UTC)[reply]