Endomorphism/Minimal polynomial/Characteristic polynomial/Section

This follows directly from fact and fact.

We have

${\displaystyle {}(f^{k})(v)=\lambda ^{k}v\,.}$

This implies the statement, since the assignment ${\displaystyle {}P\mapsto P(f)}$ is compatible with addition and scalar multiplication.

It follows directly from Cayley-Hamilton that the zeroes of the minimal polynomial are also zeroes of the characteristic polynomial.

To prove the other implication, let ${\displaystyle {}\lambda \in K}$ be a zero of the characteristic polynomial, and let ${\displaystyle {}v\in V}$ denote an eigenvector of ${\displaystyle {}f}$ with eigenvalue ${\displaystyle {}\lambda }$, its existence is guaranteed by fact. We write the minimal polynomial as

${\displaystyle {}\mu _{f}=(X-\lambda _{1})^{m_{1}}\cdots (X-\lambda _{k})^{m_{k}}Q\,,}$

where ${\displaystyle {}Q}$ has no zero. Then

${\displaystyle {}{\begin{aligned}0&=\mu _{f}(f)\\&={\left((X-\lambda _{1})^{m_{1}}\cdots (X-\lambda _{k})^{m_{k}}Q\right)}(f)\\&=(f-\lambda _{1}\operatorname {Id} _{V})^{m_{1}}\cdots (f-\lambda _{k}\operatorname {Id} _{V})^{m_{k}}Q(f).\end{aligned}}}$

We apply this mapping to ${\displaystyle {}v}$. Because of fact, the factors send the vector ${\displaystyle {}v}$ to ${\displaystyle {}(\lambda -\lambda _{i})^{m_{i}}v}$ or to ${\displaystyle {}Q(\lambda )v}$, respectively. Altogether, ${\displaystyle {}v}$ is sent to

${\displaystyle (\lambda -\lambda _{1})^{m_{1}}\cdots (\lambda -\lambda _{k})^{m_{k}}Q(\lambda )v.}$

As the composed mapping is the zero mapping and ${\displaystyle {}Q(\lambda )\neq 0}$, we must have ${\displaystyle {}\lambda _{i}=\lambda }$ for some ${\displaystyle {}i}$.