Given that $f$ is continuous and non-negative on $[0,1]$, I was asked to find the limit of:
$\displaystyle\lim_{n \rightarrow \infty}\left(\int_0^1(f(x))^{n} dx\right)^{\frac{1}{n}}$
Given that $f$ is continuous and non-negative on $[0,1]$, I was asked to find the limit of:
$\displaystyle\lim_{n \rightarrow \infty}\left(\int_0^1(f(x))^{n} dx\right)^{\frac{1}{n}}$
Let $M=\sup_{x\in[0,1]}f(x)$. It's not difficult to see that $M\geq \displaystyle\lim_{n \rightarrow \infty}\left(\int_0^1(f(x))^{n} dx\right)^{\frac{1}{n}}.$
On the other hand, there exists $x_0\in[0,1]$ such that $f(x_0)=M$ since $f$ is continuous on $[0,1]$. Again, by the continuity of $f$, for any $\epsilon>0$, there exists $\delta>0$ such that $\tag{1}f(x)>M-\epsilon\mbox{ whenever }x\in (x_0-\delta,x_0+\delta)\cap[0,1].$ Hence, we have $\tag{2}\int_0^1(f(x))^{n} dx\geq \int_{(x_0-\delta,x_0+\delta)\cap[0,1]}(f(x))^{n} dx\geq m((x_0-\delta,x_0+\delta)\cap[0,1])(M-\epsilon)^n,$ where the first inequality follows from the assumption that $f$ is nonnegative, and the second inequality follows from $(1)$. Also, $m((x_0-\delta,x_0+\delta)\cap[0,1])$ is the "length" of the interval $(x_0-\delta,x_0+\delta)\cap[0,1]$. For example, if $(x_0-\delta,x_0+\delta)\subset[0,1]$, then $m((x_0-\delta,x_0+\delta)\cap[0,1])=2\delta$; if $x_0=0$, then $m((x_0-\delta,x_0+\delta)\cap[0,1])=\delta$. In any case, we always have $m((x_0-\delta,x_0+\delta)\cap[0,1])\geq\delta>0.$ (This is important when we take $n$-root and as $n$ goes to infinity.)
Now taking $n$-th root of $(2)$, you will get the answer. I think you can work out the details from here.