grandes-ecoles 2021 Q9c

grandes-ecoles · France · x-ens-maths2__mp Sequences and Series Evaluation of a Finite or Infinite Sum
Let $s > 1$ be a real number and let $X$ be a random variable taking values in $\mathbb{N}^*$ following the zeta distribution with parameter $s$. We recall that $\chi_4(2n) = 0$ and $\chi_4(2n-1) = (-1)^{n-1}$ for $n \in \mathbb{N}^*$. We set $g(n) = r_1(n) - r_3(n)$ where $r_i(n) = \operatorname{Card}\{d \in \mathbb{N} : d \equiv i [4] \text{ and } d \mid n\}$.
Deduce that the series $$\sum_{n=0}^{+\infty} \frac{(-1)^n}{(2n+1)^s}$$ is convergent and that its sum equals $E(g(X))$. 
Let $s > 1$ be a real number and let $X$ be a random variable taking values in $\mathbb{N}^*$ following the zeta distribution with parameter $s$. We recall that $\chi_4(2n) = 0$ and $\chi_4(2n-1) = (-1)^{n-1}$ for $n \in \mathbb{N}^*$. We set $g(n) = r_1(n) - r_3(n)$ where $r_i(n) = \operatorname{Card}\{d \in \mathbb{N} : d \equiv i [4] \text{ and } d \mid n\}$.

Deduce that the series
$$\sum_{n=0}^{+\infty} \frac{(-1)^n}{(2n+1)^s}$$
is convergent and that its sum equals $E(g(X))$.
Paper Questions
Q1a Q1b Q2a Q2b Q3a Q3b Q3c Q4a Q4b Q5 Q6a Q6b Q7a Q7b Q8a Q8b Q8c Q9a Q9b Q9c Q10a Q10b Q10c Q11a Q11b Q11c Q12 Q13 Q14a Q14b Q15a Q15b Q16 Q17 Q18a Q18b Q18c Q19a Q19b