grandes-ecoles 2014 QII.C.2

grandes-ecoles · France · centrale-maths1__psi Sequences and series, recurrence and convergence Series convergence and power series analysis

We use the notation $R$ introduced in part I and $V_n(z) = U_{n+1}(z,-1)$. Let $z \in \mathbb{C}$ such that $z^2 \neq 1$, with $r$, $s$, $t$, $h$ as defined in II.C.1. What can be said about the radius of convergence of the power series $Z \mapsto \sum_{n=0}^{+\infty} V_n(z) Z^n$? We denote $g_z$ its sum.

We use the notation $R$ introduced in part I and $V_n(z) = U_{n+1}(z,-1)$. Let $z \in \mathbb{C}$ such that $z^2 \neq 1$, with $r$, $s$, $t$, $h$ as defined in II.C.1.\\
What can be said about the radius of convergence of the power series $Z \mapsto \sum_{n=0}^{+\infty} V_n(z) Z^n$?\\
We denote $g_z$ its sum.

Paper Questions

QI.A.1 QI.A.2 QI.A.3 QI.A.4 QI.A.5 QI.A.6 QI.A.7 QI.B.1 QI.B.2 QI.B.3 QI.B.4 QII.A.1 QII.A.2 QII.B.1 QII.B.2 QII.C.1 QII.C.2 QII.C.3 QII.C.4 QII.C.5 QII.C.6 QII.C.7 QIII.A.1 QIII.A.2 QIII.A.3 QIII.B.1 QIII.B.2 QIII.B.3 QIII.B.4 QIII.B.5 QIII.C.1 QIII.C.2 QIII.C.3 QIII.C.4 QIII.C.5 QIII.C.6