Derivatives of PGF of Bernoulli Distribution

Theorem
Let $X$ be a discrete random variable with the Bernoulli distribution with parameter $p$.

Then the derivatives of the PGF of $X$ w.r.t. $s$ are:


 * $\dfrac {d^k} {ds^k} \Pi_X \left({s}\right) = \begin{cases}

p & : k = 1 \\ 0 & : k > 1 \end{cases}$

Proof 1
The Probability Generating Function of Bernoulli Distribution is:
 * $\Pi_X \left({s}\right) = q + ps$

where $q = 1 - p$.

We have that for a given Bernoulli distribution, $p$ and $q$ are constant.

So, from Derivative of Constant, Sum Rule for Derivatives, Derivative of Identity Function and Derivative of Constant Multiple:
 * $\dfrac d {ds} \Pi_X \left({s}\right) = p$

Again, $p$ is constant, so from Derivative of Constant:
 * $\dfrac d {ds} p = 0$

Higher derivatives are also of course zero, also from Derivative of Constant.

Proof 2
We can directly use the result Derivatives of PGF of Binomial Distribution, setting $n = 1$.