We denote $\mathcal { D }$ the open unit disk of $\mathbb { C } : \mathcal { D } = \{ z \in \mathbb { C } ; | z | < 1 \}$. For $z \in \mathcal { D }$, we denote $\Phi _ { p } ( z ) = \sum _ { n = 0 } ^ { + \infty } ( n + p ) ( n + p - 1 ) \cdots ( n + 1 ) a _ { n + p } z ^ { n }$. Let $p \in \mathbb { N } ^ { * }$. Show that the power series $\sum _ { n \geqslant 0 } ( n + p ) ( n + p - 1 ) \cdots ( n + 1 ) a _ { n + p } x ^ { n }$ converges normally on $[ 0,1 ]$ and give the value of $\sum _ { n = 0 } ^ { + \infty } ( n + p ) ( n + p - 1 ) \cdots ( n + 1 ) a _ { n + p }$.
We denote $\mathcal { D }$ the open unit disk of $\mathbb { C } : \mathcal { D } = \{ z \in \mathbb { C } ; | z | < 1 \}$. For $z \in \mathcal { D }$, we denote $\Phi _ { p } ( z ) = \sum _ { n = 0 } ^ { + \infty } ( n + p ) ( n + p - 1 ) \cdots ( n + 1 ) a _ { n + p } z ^ { n }$.
Let $p \in \mathbb { N } ^ { * }$. Show that the power series $\sum _ { n \geqslant 0 } ( n + p ) ( n + p - 1 ) \cdots ( n + 1 ) a _ { n + p } x ^ { n }$ converges normally on $[ 0,1 ]$ and give the value of $\sum _ { n = 0 } ^ { + \infty } ( n + p ) ( n + p - 1 ) \cdots ( n + 1 ) a _ { n + p }$.