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Let $f$ be a function such that :$f:\mathbb{R+}\to \mathbb{R+}$ and $f^{-1}$ is a compositional inverse of $f$ , I have tried to find solution of the following functional $f(x)^{f^{-1}(x)}=x^2$, I took $f(x)=x$ but it doesn't work it coincide only for $x=1$ and for $f(x)=\exp(x)$ I come up to $x^x=x^2$ then coincide only for $x=1$ and $x=2$ , so $f(x)^{f^{-1}(x)} > x$ for $x >2$ which means no trivial solution exists probably a formel power series exist arround $x=1$ or $x=2$,Then my question here is : How I can solve $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ ?

Edit I suspect such trigonometric function would be works for the titled function,like $\tan x$ as shown [here]here but this need a restriction of our Domain of definitions for which $\tan x$ to be defined

Edit I have edited the question according to the answer given by @Robert I without changing the meaning I missed that I search about a real valued function not complex as stated in the below answer [here]:https://www.wolframalpha.com/input/?i=tan+x%5E%28arctan+x%29%3Dx%5E2

Let $f$ be a function such that :$f:\mathbb{R+}\to \mathbb{R+}$ and $f^{-1}$ is a compositional inverse of $f$ , I have tried to find solution of the following functional $f(x)^{f^{-1}(x)}=x^2$, I took $f(x)=x$ but it doesn't work it coincide only for $x=1$ and for $f(x)=\exp(x)$ I come up to $x^x=x^2$ then coincide only for $x=1$ and $x=2$ , so $f(x)^{f^{-1}(x)} > x$ for $x >2$ which means no trivial solution exists probably a formel power series exist arround $x=1$ or $x=2$,Then my question here is : How I can solve $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ ?

Edit I suspect such trigonometric function would be works for the titled function,like $\tan x$ as shown [here] but this need a restriction of our Domain of definitions for which $\tan x$ to be defined

Edit I have edited the question according to the answer given by @Robert I without changing the meaning I missed that I search about a real valued function not complex as stated in the below answer [here]:https://www.wolframalpha.com/input/?i=tan+x%5E%28arctan+x%29%3Dx%5E2

Let $f$ be a function such that :$f:\mathbb{R+}\to \mathbb{R+}$ and $f^{-1}$ is a compositional inverse of $f$ , I have tried to find solution of the following functional $f(x)^{f^{-1}(x)}=x^2$, I took $f(x)=x$ but it doesn't work it coincide only for $x=1$ and for $f(x)=\exp(x)$ I come up to $x^x=x^2$ then coincide only for $x=1$ and $x=2$ , so $f(x)^{f^{-1}(x)} > x$ for $x >2$ which means no trivial solution exists probably a formel power series exist arround $x=1$ or $x=2$,Then my question here is : How I can solve $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ ?

Edit I suspect such trigonometric function would be works for the titled function,like $\tan x$ as shown here but this need a restriction of our Domain of definitions for which $\tan x$ to be defined

Edit I have edited the question according to the answer given by @Robert I without changing the meaning I missed that I search about a real valued function not complex as stated in the below answer

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Function satisfying $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ and $f:\mathbb{R+}\to \mathbb{R+}$?

Let $f$ be a function such that :$f:\mathbb{R}\to \mathbb{R}$$f:\mathbb{R+}\to \mathbb{R+}$ and $f^{-1}$ is a compositional inverse of $f$ , I have tried to find solution of the following functional $f(x)^{f^{-1}(x)}=x^2$, I took $f(x)=x$ but it doesn't work it coincide only for $x=1$ and for $f(x)=\exp(x)$ I come up to $x^x=x^2$ then coincide only for $x=1$ and $x=2$ , so $f(x)^{f^{-1}(x)} > x$ for $x >2$ which means no trivial solution exists probably a formel power series exist arround $x=1$ or $x=2$,Then my question here is : How I can solve $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ ?

Edit I suspect such trigonometric function would be works for the titled function,like $\tan x$ as shown here[here] but this need a restriction of our Domain of definitions for which $\tan x$ to be defined

Edit I have edited the question according to the answer given by @Robert I without changing the meaning I missed that I search about a real valued function not complex as stated in the below answer [here]:https://www.wolframalpha.com/input/?i=tan+x%5E%28arctan+x%29%3Dx%5E2

Function satisfying $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$?

Let $f$ be a function such that :$f:\mathbb{R}\to \mathbb{R}$ and $f^{-1}$ is a compositional inverse of $f$ , I have tried to find solution of the following functional $f(x)^{f^{-1}(x)}=x^2$, I took $f(x)=x$ but it doesn't work it coincide only for $x=1$ and for $f(x)=\exp(x)$ I come up to $x^x=x^2$ then coincide only for $x=1$ and $x=2$ , so $f(x)^{f^{-1}(x)} > x$ for $x >2$ which means no trivial solution exists probably a formel power series exist arround $x=1$ or $x=2$,Then my question here is : How I can solve $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ ?

Edit I suspect such trigonometric function would be works for the titled function,like $\tan x$ as shown here but this need a restriction of our Domain of definitions for which $\tan x$ to be defined

Function satisfying $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ and $f:\mathbb{R+}\to \mathbb{R+}$?

Let $f$ be a function such that :$f:\mathbb{R+}\to \mathbb{R+}$ and $f^{-1}$ is a compositional inverse of $f$ , I have tried to find solution of the following functional $f(x)^{f^{-1}(x)}=x^2$, I took $f(x)=x$ but it doesn't work it coincide only for $x=1$ and for $f(x)=\exp(x)$ I come up to $x^x=x^2$ then coincide only for $x=1$ and $x=2$ , so $f(x)^{f^{-1}(x)} > x$ for $x >2$ which means no trivial solution exists probably a formel power series exist arround $x=1$ or $x=2$,Then my question here is : How I can solve $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ ?

Edit I suspect such trigonometric function would be works for the titled function,like $\tan x$ as shown [here] but this need a restriction of our Domain of definitions for which $\tan x$ to be defined

Edit I have edited the question according to the answer given by @Robert I without changing the meaning I missed that I search about a real valued function not complex as stated in the below answer [here]:https://www.wolframalpha.com/input/?i=tan+x%5E%28arctan+x%29%3Dx%5E2

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Let $f$ be a function such that :$f:\mathbb{R}\to \mathbb{R}$ and $f^{-1}$ is a compositional inverse of $f$ , I have tried to find solution of the following functional $f(x)^{f^{-1}(x)}=x^2$, I took $f(x)=x$ but it doesn't work it coincide only for $x=1$ and for $f(x)=\exp(x)$ I come up to $x^x=x^2$ then coincide only for $x=1$ and $x=2$ , so $f(x)^{f^{-1}(x)} > x$ for $x >2$ which means no trivial solution exists probably a formel power series exist arround $x=1$ or $x=2$,Then my question here is : How I can solve $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ ?

Edit I suspect such trigonometric function would be an approximate solutionworks for the titled function,like $\tan x$ as shown here but this need a restriction of our Domain of definitions for which $\tan x$ to be defined

Let $f$ be a function such that :$f:\mathbb{R}\to \mathbb{R}$ and $f^{-1}$ is a compositional inverse of $f$ , I have tried to find solution of the following functional $f(x)^{f^{-1}(x)}=x^2$, I took $f(x)=x$ but it doesn't work it coincide only for $x=1$ and for $f(x)=\exp(x)$ I come up to $x^x=x^2$ then coincide only for $x=1$ and $x=2$ , so $f(x)^{f^{-1}(x)} > x$ for $x >2$ which means no trivial solution exists probably a formel power series exist arround $x=1$ or $x=2$,Then my question here is : How I can solve $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ ?

Edit I suspect such trigonometric function would be an approximate solution for the titled function,like $\tan x$ as shown here but this need a restriction of our Domain of definitions for which $\tan x$ to be defined

Let $f$ be a function such that :$f:\mathbb{R}\to \mathbb{R}$ and $f^{-1}$ is a compositional inverse of $f$ , I have tried to find solution of the following functional $f(x)^{f^{-1}(x)}=x^2$, I took $f(x)=x$ but it doesn't work it coincide only for $x=1$ and for $f(x)=\exp(x)$ I come up to $x^x=x^2$ then coincide only for $x=1$ and $x=2$ , so $f(x)^{f^{-1}(x)} > x$ for $x >2$ which means no trivial solution exists probably a formel power series exist arround $x=1$ or $x=2$,Then my question here is : How I can solve $f(x)^{f^{-1}(x)}=x^2$ with $ f^{-1}$ is a compositional inverse of $f$ ?

Edit I suspect such trigonometric function would be works for the titled function,like $\tan x$ as shown here but this need a restriction of our Domain of definitions for which $\tan x$ to be defined

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