Evaluate $\frac{d}{dx}ⁿx$ which $ⁿx=x^{x^{x^{...}}}$, total $n$ $x$'s.
I have tried to observe when $n=1,2,3,4,5$, but it's difficult to see the pattern. Can anyone get it? Thank you.
Evaluate $\frac{d}{dx}ⁿx$ which $ⁿx=x^{x^{x^{...}}}$, total $n$ $x$'s.
I have tried to observe when $n=1,2,3,4,5$, but it's difficult to see the pattern. Can anyone get it? Thank you.
As I said in my comment above, define $y= ^n\!\!x$. Then $\log y=\log ^nx=\log x^{^{n-1}x}=\, ^{n-1}x\log x.$
Differentiating implicitly, we get $\frac{d y}{d x}\frac{1}{y}=\frac{d}{dx}(\, ^{n-1}x)\log x+\, ^{n-1}x\frac{1}{x},$ from which we see $\frac{d}{dx}(\, ^{n}x)=\frac{\, ^{n}x}{x}\left(x\log x\frac{d}{dx}(\, ^{n-1}x)+\, ^{n-1}x\right).$
For the first few values of $n$, we get
$n=1:\quad\frac{d}{dx}(\, ^{1}x)=\frac{d}{dx}(x)=1$
$n=2:\quad\frac{d}{dx}(\, ^{2}x)=\frac{\, ^{2}x}{x}\left(x\log x\frac{d}{dx}(\, ^{1}x)+\, ^{1}x\right)=x^x(\log x+1)$
$n=3:\quad\frac{d}{dx}(\, ^{3}x)=\frac{\, ^{3}x}{x}\left(x\log x\frac{d}{dx}(\, ^{2}x)+\, ^{2}x\right)=x^{x^x}\left(x^x(\log x+1)\log x+x^{x-1}\right)$