grandes-ecoles 2013 Q14b

grandes-ecoles · France · x-ens-maths2__mp Sequences and Series Proof of Inequalities Involving Series or Sequence Terms

Throughout the third part, $f \in \mathcal{C}_{0}$ satisfies property $(\mathcal{P}_{1})$: there exist $x_{0} \in [0,1]$, $s \in ]0,1[$ and $c_{1} \in ]0, +\infty[$, such that for all $(j, k) \in \mathcal{I}$, $$|c_{j,k}(f)| \leq c_{1} (2^{-j} + |k 2^{-j} - x_{0}|)^{s}$$ We fix $x_{0}$, $s$, $c_{1}$ and $x \in [0,1] \backslash \{x_{0}\}$. Let $n_{0}$ be the unique natural integer such that $2^{-n_{0}-1} < |x - x_{0}| \leq 2^{-n_{0}}$.
Deduce that, by setting $c_{2} = 8(2^{1-s} - 1)^{-1} (3/2)^{s} c_{1}$, $$\sum_{j=0}^{n_{0}} \sum_{k \in \mathcal{T}_{j}} |c_{j,k}(f)| |\theta_{j,k}(x) - \theta_{j,k}(x_{0})| \leq c_{2} |x - x_{0}|^{s}$$

Throughout the third part, $f \in \mathcal{C}_{0}$ satisfies property $(\mathcal{P}_{1})$: there exist $x_{0} \in [0,1]$, $s \in ]0,1[$ and $c_{1} \in ]0, +\infty[$, such that for all $(j, k) \in \mathcal{I}$,
$$|c_{j,k}(f)| \leq c_{1} (2^{-j} + |k 2^{-j} - x_{0}|)^{s}$$
We fix $x_{0}$, $s$, $c_{1}$ and $x \in [0,1] \backslash \{x_{0}\}$. Let $n_{0}$ be the unique natural integer such that $2^{-n_{0}-1} < |x - x_{0}| \leq 2^{-n_{0}}$.

Deduce that, by setting $c_{2} = 8(2^{1-s} - 1)^{-1} (3/2)^{s} c_{1}$,
$$\sum_{j=0}^{n_{0}} \sum_{k \in \mathcal{T}_{j}} |c_{j,k}(f)| |\theta_{j,k}(x) - \theta_{j,k}(x_{0})| \leq c_{2} |x - x_{0}|^{s}$$

Paper Questions

Q1a Q1b Q1c Q2 Q3a Q3b Q3c Q4a Q4b Q5a Q5b Q5c Q5d Q6 Q7a Q7b Q8a Q8b Q9a Q9b Q9c Q10a Q10b Q11a Q11b Q12 Q13 Q14a Q14b Q15 Q16 Q17 Q18a Q18b Q19