I'll write it formally:<br> Let $f(1,x) = \sin(x)$,<br> Let $f(n+1,x) = \sin\bigl(f(n,x)\bigr)$ for $n\in \Bbb N$ with $n>1$.<br> What is the limit as $n \to \infty$? It's fairly easy to prove that the absolute value of $f(n,x)$ is decreasing for every constant $x$ as $n$ is increasing, so the limit exists. From what I calculated, it seems like $f(\infty,x)= 0$ for all $x$. Does someone have a proof for that? --- *Follow up:* The limit $f(n,x)\rightarrow 0$ may be a bit trivial. What if we rescale $x$ and ask for the limit of $n^\alpha f(n,n^{-\alpha}x)$ as $n\rightarrow\infty$? For which $\alpha$ does the limit exist and what is it?