I am stuck on this computation of the Fourier coefficients of Eisenstein series.  For $\Gamma = SL(2, \mathbb{Z})$ and $\Gamma_\infty = \left\{ \left( \begin{array}{cc} 1 & m \\ 0 & 1 \end{array}\right): m \in \mathbb{Z} \right\}$ we can define an Eisenstein series as the sum over the cosets:

$$ E_\Gamma(z,s) = \sum_{\gamma \in \Gamma_\infty \backslash \Gamma} (y(\gamma z))^s $$

The Fourier coefficients of this Eisenstein series are written in terms of an L-function and Bessel functions:

$$ \int_0^1 E_\Gamma(z,s) e^{2\pi i m x} \, dx= \begin{cases} 
y^s + \left( \sum_{c \geq 0} \frac{r_{0, \Gamma}(c)}{c^{2s}} \right) \frac{\pi^{1/2}\Gamma(s - \frac{1}{2})}{\Gamma(s)} y^{1-s} & m = 0 \\
 \left( \sum_{c \geq 0} \frac{r_{n, \Gamma}(c)}{c^{2s}} \right) \frac{2\pi^s|m|^{s - \frac{1}{2}}K_{s- \frac{1}{2}}(2\pi|m|y)}{\Gamma(s)}& m \neq 0
\end{cases} $$

Not begin an expert on Automorphic forms (in fact a total newbie), I consulted Anton Dietmar's text and found not-quite the same formula:

$$ E(z,s) = \pi^{-s} \Gamma(s) \zeta(2s) \sum_{\Gamma_\infty \backslash \Gamma} \mathrm{Im}(\gamma z)^s $$

This formula looks the same up to some factors of gamma and zeta functions.  Then 

$$ \int_0^1 E(z,s) e^{2\pi i m x} \, dx= \begin{cases} 
\pi^{-s}\Gamma(s) \zeta(2s)y^s + \pi^{s-1} \Gamma(1-s)\zeta(2-2s)y^{1-s} & m = 0 \\
2|m|^{2 - \frac{1}{2}}\sigma_{1-2s}(|m|)\sqrt{y}K_{s - \frac{1}{2}}(2\pi|m|y)& m \neq 0
\end{cases} $$

I don't understand why in the first case I get [Ramanujan sums](https://en.wikipedia.org/wiki/Ramanujan%27s_sum) and in the second case, I get the [sum-of-divisors](https://en.wikipedia.org/wiki/Divisor_function) function:

$$ r_m(c) = \sum_{(c,d)=1} e^{2\pi i m \frac{d}{c}}$$

Is this consistent?  I know the two version of $E$ are written slightly differently, but I have not yet verified that they agree.