An at first easy looking question has been giving me problems.
Given is the function $f(x)=e^x$ on the interval $[0,1]$, asked are the areas of its surfaces of revolution about the $x$-axis and $y$-axis.
$x$-axis:
We have $A=2\pi\int\limits_0^1f(x)\sqrt{1+(f'(x))^2}dx=2\pi\int\limits_0^1e^x\sqrt{1+e^{2x}}dx=2\pi\int\limits_1^e\sqrt{1+u^2}du$
Here we can substitute $u=\textrm{tan}(\theta)$ and we get $A=2\pi\int\limits_{\textrm{atan}(1)}^{\textrm{atan}(e)}\frac{1}{\textrm{cos}^3(\theta)}d\theta$. I don't really know how to approach this integral and would appreciate help. Wolfram Alpha suggests using a reduction formula but we haven't learnt this formula and I don't think we're meant to use it.
$y$-axis:
For this one we have $A=2\pi\int\limits_0^1x\sqrt{1+(f'(x))^2}dx=2\pi\int\limits_0^1x\sqrt{1+e^{2x}}dx$. I have tried many things and not gotten anywhere. Furthermore Wolfram Alpha suggests a complicated function as the indefinite integral of the integrand which leads me to think I have done something else wrong as well.
Any help is appreciated