Linear algebra (Osnabrück 2024-2025)/Part I/Exercise sheet 27

Exercise for the break

Show that the matrix

${\displaystyle {\begin{pmatrix}-2&4\\-1&2\end{pmatrix}}}$

is nilpotent.

Exercises

Show that the complex matrix

${\displaystyle {\begin{pmatrix}1&{\mathrm {i} }\\{\mathrm {i} }&-1\end{pmatrix}}}$

is nilpotent.

We consider the matrix

${\displaystyle {}M={\begin{pmatrix}0&a&b&c&d\\0&0&e&f&g\\0&0&0&h&i\\0&0&0&0&j\\0&0&0&0&0\end{pmatrix}}\,}$

over a field ${\displaystyle {}K}$. Show that the fifth power of ${\displaystyle {}M}$ equals ${\displaystyle {}0}$, that is,

${\displaystyle {}M^{5}=MMMMM=0\,.}$

Let ${\displaystyle {}A={\left(a_{ij}\right)}}$ and ${\displaystyle {}B={\left(b_{ij}\right)}}$ be square matrices of length ${\displaystyle {}n}$. Suppose that ${\displaystyle {}a_{ij}=0}$ holds for ${\displaystyle {}j\leq i+d}$, and ${\displaystyle {}b_{ij}=0}$ holds for ${\displaystyle {}j\leq i+e}$ for some ${\displaystyle {}d,e\in \mathbb {Z} }$. Show that the entries ${\displaystyle {}c_{ij}}$ of the product ${\displaystyle {}AB}$ fulfill the condition ${\displaystyle {}c_{ij}=0}$ for ${\displaystyle {}j\leq i+d+e+1}$.

Let

${\displaystyle D\colon \mathbb {R} [X]_{\geq m}\longrightarrow \mathbb {R} [X]_{\geq m}}$

be the restriction of the derivation operator ${\displaystyle {}P\mapsto P'}$ to the space of polynomials of degree ${\displaystyle {}\leq m}$. Show that ${\displaystyle {}D}$ is nilpotent. Show also that

${\displaystyle D\colon \mathbb {R} [X]\longrightarrow \mathbb {R} [X]}$

is not nilpotent.

Let ${\displaystyle {}V}$ be a ${\displaystyle {}K}$-vector space, and

${\displaystyle \varphi \colon V\longrightarrow V}$

an injective linear mapping. Show that ${\displaystyle {}\varphi }$ is not nilpotent.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V}$ denote a finite-dimensional ${\displaystyle {}K}$-vector space. Let

${\displaystyle \varphi \colon V\longrightarrow V}$

be a nilpotent linear mapping. Show that ${\displaystyle {}\varphi ^{n}=0}$, where ${\displaystyle {}n}$ is the dimension of ${\displaystyle {}V}$.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V}$ denote a ${\displaystyle {}K}$-vector space. Let

${\displaystyle \varphi \colon V\longrightarrow V}$

be a nilpotent linear mapping. Show that ${\displaystyle {}0}$ is the only eigenvalue of ${\displaystyle {}\varphi }$.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V}$ denote a finite-dimensional ${\displaystyle {}K}$-vector space. Let

${\displaystyle \varphi \colon V\longrightarrow V}$

be a nilpotent linear mapping. Suppose that ${\displaystyle {}\varphi }$ is diagonalizable. Show

${\displaystyle {}\varphi =0\,.}$

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V}$ denote a finite-dimensional ${\displaystyle {}K}$-vector space. Let

${\displaystyle \varphi \colon V\longrightarrow V}$

be a nilpotent linear mapping. What is the determinant of ${\displaystyle {}\varphi }$?

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V}$ denote a finite-dimensional ${\displaystyle {}K}$-vector space. Let

${\displaystyle \varphi \colon V\longrightarrow V}$

be a nilpotent linear mapping. What is the trace of ${\displaystyle {}\varphi }$?

Let ${\displaystyle {}K}$ be a field.

a) Characterize the nilpotent ${\displaystyle {}2\times 2}$-matrices

${\displaystyle {\begin{pmatrix}x&y\\z&w\end{pmatrix}}}$

over ${\displaystyle {}K}$ by two equations in the variables ${\displaystyle {}x,y,z,w}$.

b) Are these equations linear?

a) Let ${\displaystyle {}M}$ be a ${\displaystyle {}2\times 2}$-matrix that is trigonalizable, but neither diagonalizable nor invertible. Show that ${\displaystyle {}M}$ is nilpotent.

b) Give an example of a ${\displaystyle {}3\times 3}$-matrix ${\displaystyle {}M}$ that is trigonalizable, but neither diagonalizable, nor invertible, nor nilpotent.

Give an example of a linear mapping ${\displaystyle {}\varphi \colon K^{3}\rightarrow K^{3}}$ that is trigonalizable, where the trace and the determinant are ${\displaystyle {}0}$, and that is not nilpotent.

Show that the linear subspaces ${\displaystyle {}U_{i}}$, constructed in the proof of Lemma 27.11 , are not ${\displaystyle {}\varphi }$-invariant in general.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V}$ denote a finite-dimensional ${\displaystyle {}K}$-vector space. Let

${\displaystyle \varphi \colon V\longrightarrow V}$

be a nilpotent linear mapping. Suppose that the kernel of ${\displaystyle {}\varphi }$ is one-dimensional. Let

${\displaystyle {}V_{i}=\operatorname {kern} \varphi ^{i}\,,}$

and let ${\displaystyle {}s}$ be the minimal number with

${\displaystyle {}\varphi ^{s}=0\,.}$

1. Show that all ${\displaystyle {}V_{i}}$, ${\displaystyle {}1\leq i\leq s}$, have a direct decomposition

   ${\displaystyle {}V_{i}=V_{i-1}\oplus U_{i}\,,}$

   where ${\displaystyle {}U_{i}}$ is one-dimensional.

2. Show that the restrictions

   ${\displaystyle \varphi \colon U_{i}\longrightarrow V_{i-1}}$

   are bijective for ${\displaystyle {}1<i<s}$.

3. Show that ${\displaystyle {}s}$ equals the dimension of ${\displaystyle {}V}$.

Let

${\displaystyle \varphi \colon V\longrightarrow V}$

be a nilpotent endomorphism on a finite-dimensional ${\displaystyle {}K}$-vector space ${\displaystyle {}V}$. Let

${\displaystyle {}V_{i}:=\operatorname {kern} \varphi ^{i}\,.}$

Show that for the dimension jumps, the relation

${\displaystyle {}\dim _{K}{\left(V_{i}\right)}-\dim _{K}{\left(V_{i}-1\right)}\geq \dim _{K}{\left(V_{i+1}\right)}-\dim _{K}{\left(V_{i}\right)}\,}$

holds.

Show that there exists a family of (up to) ${\displaystyle {}2^{n-1}}$ ${\displaystyle {}n\times n}$-matrices with the property that every nilpotent endomorphism on an ${\displaystyle {}n}$-dimensional vector space ${\displaystyle {}V}$, can be described, in a suitable basis, by one of these matrices.

Show that every nilpotent endomorphism, on a four-dimensional space, can be brought into exactly one of the following forms.

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

Let ${\displaystyle {}v_{1},\ldots ,v_{6}}$ be a basis of the ${\displaystyle {}K}$-vector space ${\displaystyle {}V}$, and let ${\displaystyle {}\varphi \colon V\rightarrow V}$ denote the linear mapping, given by

${\displaystyle v_{1},v_{2}\mapsto v_{4},\,v_{3},v_{5}\mapsto v_{6},\,v_{4}\mapsto 0,\,v_{6}\mapsto v_{2}.}$

1. Show that ${\displaystyle {}\varphi }$ is nilpotent.
2. Determine the minimal ${\displaystyle {}s}$ satisfying ${\displaystyle {}\varphi ^{s}=0}$.
3. Determine the kernel of ${\displaystyle {}\varphi }$.
4. Find a basis of ${\displaystyle {}V}$ such that the describing matrix of ${\displaystyle {}\varphi }$, with respect to this basis, is in Jordan normal form.

The following exercise generalizes the idea to assign a permutation matrix to a permutation.

We consider, on the set

${\displaystyle {}S=\{1,\ldots ,n,*\}\,,}$

the set of mappings

${\displaystyle {}B={\left\{\pi :S\rightarrow S\mid \pi (*)=*\right\}}\,.}$

For ${\displaystyle {}\pi \in B}$, we assign (for a fixed field ${\displaystyle {}K}$) the linear mapping

${\displaystyle \varphi _{\pi }\colon K^{n}\longrightarrow K^{n}}$

given by

${\displaystyle {}\varphi _{\pi }(e_{i})={\begin{cases}e_{\pi (i)},{\text{ if }}\pi (i)\neq *\,,\\0,{\text{ if }}\pi (i)=*\,.\end{cases}}\,}$

We denote by ${\displaystyle {}M_{\pi }}$ the corresponding matrix with respect to the standard basis.

a) Establish the matrix ${\displaystyle {}M_{\pi }}$, in case ${\displaystyle {}n=4}$, for the following ${\displaystyle {}\pi }$:

(1)

${\displaystyle {}x}$	${\displaystyle {}1}$	${\displaystyle {}2}$	${\displaystyle {}3}$	${\displaystyle {}4}$	${\displaystyle {}*}$
${\displaystyle {}\pi (x)}$	${\displaystyle {}2}$	${\displaystyle {}*}$	${\displaystyle {}3}$	${\displaystyle {}*}$	${\displaystyle {}*}$

(2)

${\displaystyle {}x}$	${\displaystyle {}1}$	${\displaystyle {}2}$	${\displaystyle {}3}$	${\displaystyle {}4}$	${\displaystyle {}*}$
${\displaystyle {}\pi (x)}$	${\displaystyle {}*}$	${\displaystyle {}1}$	${\displaystyle {}2}$	${\displaystyle {}3}$	${\displaystyle {}*}$

(3)

${\displaystyle {}x}$	${\displaystyle {}1}$	${\displaystyle {}2}$	${\displaystyle {}3}$	${\displaystyle {}4}$	${\displaystyle {}*}$
${\displaystyle {}\pi (x)}$	${\displaystyle {}*}$	${\displaystyle {}*}$	${\displaystyle {}*}$	${\displaystyle {}*}$	${\displaystyle {}*}$

(4)

${\displaystyle {}x}$	${\displaystyle {}1}$	${\displaystyle {}2}$	${\displaystyle {}3}$	${\displaystyle {}4}$	${\displaystyle {}*}$
${\displaystyle {}\pi (x)}$	${\displaystyle {}2}$	${\displaystyle {}2}$	${\displaystyle {}2}$	${\displaystyle {}2}$	${\displaystyle {}*}$

b) What properties hold for the columns and for the rows of ${\displaystyle {}M_{\pi }}$?

c) For what ${\displaystyle {}\pi }$ is ${\displaystyle {}M_{\pi }}$ bijective?

d) For what ${\displaystyle {}\pi }$ is ${\displaystyle {}M_{\pi }}$ nilpotent?

e) What is the dimension of the kernel of ${\displaystyle {}M_{\pi }}$?

f) Show

${\displaystyle {}M_{\pi \circ \rho }=M_{\pi }\circ M_{\rho }\,.}$

g) Show that every nilpotent ${\displaystyle {}n\times n}$-matrix ${\displaystyle {}M}$ is similar to a matrix of the form ${\displaystyle {}M_{\pi }}$.

Let ${\displaystyle {}V}$ be a ${\displaystyle {}K}$-vector space, and let

${\displaystyle \varphi \colon V\longrightarrow V}$

denote a nilpotent linear mapping. Let

${\displaystyle \psi \colon V\longrightarrow V}$

be another linear mapping satisfying

${\displaystyle {}\psi \circ \varphi =\varphi \circ \psi \,.}$

Show that ${\displaystyle {}\psi \circ \varphi }$ is also nilpotent.

Give an example of two nilpotent linear mappings

${\displaystyle \varphi ,\psi \colon K^{2}\longrightarrow K^{2}}$

such that neither ${\displaystyle {}\varphi \circ \psi }$ nor ${\displaystyle {}\varphi +\psi }$ are nilpotent.

Let ${\displaystyle {}a\in \mathbb {R} }$ be a real number with ${\displaystyle {}\vert {a}\vert <1}$. As is known from analysis, we have

${\displaystyle {}\lim _{n\rightarrow \infty }a^{n}=0\,.}$

Is the linear mapping

${\displaystyle \mathbb {R} \longrightarrow \mathbb {R} ,x\longmapsto ax}$

nilpotent?

Hand-in-exercises

Let ${\displaystyle {}M}$ be a ${\displaystyle {}2\times 2}$-matrix over a field ${\displaystyle {}K}$. Show that ${\displaystyle {}M}$ is nilpotent if and only if the determinant and the trace of ${\displaystyle {}M}$ are ${\displaystyle {}0}$.

Let ${\displaystyle {}\varphi \colon V\rightarrow V}$ be a linear mapping, and let ${\displaystyle {}V=U\oplus W}$ be a direct sum of ${\displaystyle {}\varphi }$-invariant linear subspaces. Show that ${\displaystyle {}\varphi }$ is nilpotent if and only if ${\displaystyle {}\varphi {|}_{U}}$ and ${\displaystyle {}\varphi {|}_{W}}$ are nilpotent.

Let ${\displaystyle {}v_{1},\ldots ,v_{7}}$ be a basis of the ${\displaystyle {}\mathbb {R} }$-vector space ${\displaystyle {}V}$, and let ${\displaystyle {}\varphi \colon V\rightarrow V}$ denote the linear mapping given by

${\displaystyle v_{3},v_{2}\mapsto v_{5},\,v_{5}\mapsto 4v_{6},\,v_{1},v_{4}\mapsto 0,\,v_{6}\mapsto 5v_{4},\,v_{7}\mapsto 3v_{2}.}$

1. Show that ${\displaystyle {}\varphi }$ is nilpotent.
2. Determine the minimal ${\displaystyle {}s}$ satisfying ${\displaystyle {}\varphi ^{s}=0}$.
3. Determine den kernel of ${\displaystyle {}\varphi }$.
4. Find a basis of ${\displaystyle {}V}$, such that the matrix describing ${\displaystyle {}\varphi }$ with respect to this basis is in Jordan normal form.

Let ${\displaystyle {}V}$ be a ${\displaystyle {}K}$-vector space with a basis ${\displaystyle {}v_{n}}$, ${\displaystyle {}n\in \mathbb {N} _{+}}$. Let

${\displaystyle \varphi \colon V\longrightarrow V}$

be the linear mapping given by

${\displaystyle {}\varphi (v_{1})=0\,}$

and

${\displaystyle {}\varphi (v_{n})=v_{n-1}\,}$

for all ${\displaystyle {}n\geq 2}$. Is ${\displaystyle {}\varphi }$ nilpotent?

Let ${\displaystyle {}V}$ be a finite-dimensional ${\displaystyle {}K}$-vector space, and let

${\displaystyle \varphi \colon V\longrightarrow V}$

be nilpotent. Show that

${\displaystyle {}\psi :=\operatorname {Id} +\varphi \,}$

is bijective.

Let ${\displaystyle {}V}$ be a ${\displaystyle {}K}$-vector space, and let

${\displaystyle \varphi ,\psi \colon V\longrightarrow V}$

denote nilpotent linear mappings, satisfying the relation

${\displaystyle {}\varphi \circ \psi =\psi \circ \varphi \,.}$

Show that also ${\displaystyle {}\psi +\varphi }$ is nilpotent.

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