Endomorphism/Minimal polynomial/Introduction/Section

For the identity ${\displaystyle {}\operatorname {Id} _{V}}$ on a ${\displaystyle {}K}$-vector space ${\displaystyle {}V}$, the minimal polynomial is just ${\displaystyle {}X-1}$. This polynomial is sent under the evaluation homomorphism to

${\displaystyle {}\operatorname {Id} _{V}-\operatorname {Id} _{V}=0\,.}$

A constant polynomial ${\displaystyle {}a_{0}}$ is sent to ${\displaystyle {}a_{0}\operatorname {Id} }$, which is not, with the exception of ${\displaystyle {}a_{0}=0}$ or ${\displaystyle {}V=0}$, the zero mapping.

For a homothety, that is, a mapping of the form ${\displaystyle {}\lambda \operatorname {Id} _{V}}$, the minimal polynomial is ${\displaystyle {}X-\lambda }$, under the condition ${\displaystyle {}\lambda \neq 0}$ and ${\displaystyle {}V\neq 0}$. For the zero mapping on ${\displaystyle {}V\neq 0}$, the minimal polynomial is ${\displaystyle {}X}$, in case ${\displaystyle {}V=0}$, it is the constant polynomial ${\displaystyle {}1}$.

For a diagonal matrix

${\displaystyle {}M={\begin{pmatrix}d_{1}&0&\cdots &0\\0&d_{2}&\ddots &\vdots \\\vdots &\ddots &\ddots &0\\0&\cdots &0&d_{n}\end{pmatrix}}\,}$

with different entries ${\displaystyle {}d_{i}}$, the minimal polynomial is

${\displaystyle {}P=(X-d_{1})(X-d_{2})\cdots (X-d_{n})\,.}$

This polynomial is sent under the substitution to

${\displaystyle (M-d_{1}E_{n})\circ (M-d_{2}E_{n})\circ (M-d_{n}E_{n}).}$

We apply this to a standard vector ${\displaystyle {}e_{i}}$. Then factor ${\displaystyle {}(M-d_{j}E_{n})}$ sends ${\displaystyle {}e_{i}}$to ${\displaystyle {}(d_{i}-d_{j})e_{i}}$. Therefore, the ${\displaystyle {}i}$-th factor ensures that ${\displaystyle {}e_{i}}$ is annihilated. Since a basis is mapped under ${\displaystyle {}P(M)}$ to ${\displaystyle {}0}$, it must be the zero mapping.

Assume now that ${\displaystyle {}P}$ is not the minimal polynomial ${\displaystyle {}\mu }$. Then there exists, due to fact, a polynomial ${\displaystyle {}Q}$ with

${\displaystyle {}P=Q\mu \,,}$

and, because of fact, ${\displaystyle {}\mu }$ is a partial product of the linear factors of ${\displaystyle {}P}$. But as soon as one factor of ${\displaystyle {}P}$ is removed, say we remove ${\displaystyle {}X-d_{i}}$, then ${\displaystyle {}e_{i}}$ is not annihilated by the corresponding mapping.

For the matrix

${\displaystyle {}M={\begin{pmatrix}0&1\\0&0\end{pmatrix}}\,,}$

${\displaystyle {}X^{2}}$ is the minimal polynomial. This polynomial becomes, after the substitution, the zero mapping, because of

${\displaystyle {}M^{2}={\begin{pmatrix}0&0\\0&0\end{pmatrix}}\,.}$

The factors of ${\displaystyle {}X^{2}}$ of smaller degree are the constant polynomials ${\displaystyle {}\neq 0}$ and ${\displaystyle {}a_{1}X}$ with ${\displaystyle {}a_{1}\neq 0}$, but these polynomials do not annihilate ${\displaystyle {}M}$.