The infinite tetration is defined as $f(x)=x^{x^{\cdot^{\cdot}}}$
This function is defined for $e^{-e} \leq x \leq e^{e-1}$.
(Wikipedia image)
Can one determine the derivative of this function?
The infinite tetration is defined as $f(x)=x^{x^{\cdot^{\cdot}}}$
This function is defined for $e^{-e} \leq x \leq e^{e-1}$.
(Wikipedia image)
Can one determine the derivative of this function?
Letting $h(x)$ be your infinite power tower, one can solve the functional equation $h(x)=x^{h(x)}$ in terms of the Lambert function $W(x)$, the inverse function of $x\exp\,x$. More specifically, we have
$h(x)=\exp(-W(-\log\,x))$
One can then apply the chain rule as usual. The formula
$W^\prime(x)=\frac{\exp(-W(x))}{1+W(x)}$
is easily derived through implicit differentiation of the relationship $W(x)\exp(W(x))=x$.
We thus have
$h^\prime(x)=\frac{\exp(-2 W(-\log\,x))}{x (1+W(-\log\,x))}=\frac{h(x)^2}{x(1-h(x)\log\,x)}$
As lhf says, the functional equation for $h(x)$ can be differentiated implicitly, without needing to take the Lambert route:
$\begin{align*} h^\prime(x)&=\frac{\mathrm d}{\mathrm dx}x^{h(x)}\\ h^\prime(x)&=x^{h(x)}\left(\frac{h(x)}{x}+h^\prime(x)\log\,x\right)\\ h^\prime(x)&=\frac{h(x)^2}{x}+h(x)h^\prime(x)\log\,x\\ h^\prime(x)-h(x)h^\prime(x)\log\,x&=\frac{h(x)^2}{x}\\ h^\prime(x)&=\frac{h(x)^2}{x(1-h(x)\log\,x)}\\ \end{align*}$
its given that $y=f(x)=x^{x^{x^{x^\cdots}}}$ I can write this function as,
$y=x^{y}$
Taking $log_e$ on both sides, we have,
$\log y=y\log x$
Now, differentiate w.r.to $x$ on both sides,
$\frac 1 y y'=\frac y x + y'\log x $
$ \left(\frac 1 y-\log x\right)y'=\frac y x$ $y'=\frac {y^2}{x(1-x\log x)}$
$f'(x)=\frac {x^{x^{x^{x^\cdots}}}}{x(1-x\log x)}$