Linear algebra (Osnabrück 2024-2025)/Part I/Exercise sheet 16

Exercise for the break

Show that, for a ${\displaystyle {}K}$-vector space ${\displaystyle {}V}$ with dual space ${\displaystyle {}{V}^{*}}$, the evaluation mapping

${\displaystyle V\times {V}^{*}\longrightarrow K,(v,f)\longmapsto f(v),}$

is bilinear.

Exercises

Compute the determinant of the matrix

${\displaystyle {\begin{pmatrix}1+3{\mathrm {i} }&5-{\mathrm {i} }\\3-2{\mathrm {i} }&4+{\mathrm {i} }\end{pmatrix}}.}$

Compute the determinant of the matrix

${\displaystyle {\begin{pmatrix}1&3&5\\2&1&3\\8&7&4\end{pmatrix}}.}$

We consider the matrix

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

1. Compute the determinant of ${\displaystyle {}M}$.
2. Determine the determinant for every matrix that arises when we remove from ${\displaystyle {}M}$ a row and a column.

Prove by induction that the determinant of an upper triangular matrix is equal to the product of the diagonal elements.

Prove by induction that the determinant of a lower triangular matrix is equal to the product of the diagonal elements.

Let ${\displaystyle {}K}$ be a field, let ${\displaystyle {}V}$ and ${\displaystyle {}W}$ be ${\displaystyle {}K}$-vector spaces, and let

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

denote a ${\displaystyle {}K}$-linear mapping. Show that ${\displaystyle {}\varphi }$ is multilinear and alternating.

Let ${\displaystyle {}K}$ be a field. Show that the multiplication

${\displaystyle K\times K=K^{2}\longrightarrow K,(a,b)\longmapsto a\cdot b,}$

is multilinear. Is it also alternating?

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}n\in \mathbb {N} }$. Show that the mapping

${\displaystyle K^{n}\times K^{n}\longrightarrow K,({\begin{pmatrix}u_{1}\\\vdots \\u_{n}\end{pmatrix}},{\begin{pmatrix}v_{1}\\\vdots \\v_{n}\end{pmatrix}})\longmapsto (u_{1},\ldots ,u_{n})\circ {\begin{pmatrix}v_{1}\\\vdots \\v_{n}\end{pmatrix}},}$

is multilinear.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}I}$ and ${\displaystyle {}J}$ denote finite index sets. Show that the mapping

${\displaystyle \operatorname {Map} \,{\left(I,K\right)}\times \operatorname {Map} \,{\left(J,K\right)}\longrightarrow \operatorname {Map} \,{\left(I\times J,K\right)},(f,g)\longmapsto f\otimes g,}$

given by

${\displaystyle {}(f\otimes g)(i,j):=f(i)\cdot g(j)\,,}$

is multilinear.

Check the multilinearity and the property to be alternating, directly for the determinant of a ${\displaystyle {}2\times 2}$-matrix.

Check the multilinearity and the property to be alternating, directly for the determinant of a ${\displaystyle {}3\times 3}$-matrix.

Show that, for every elementary matrix ${\displaystyle {}E}$, the relation

${\displaystyle {}\det E=\det {E^{\text{tr}}}\,}$

holds.

Use the image to convince yourself that, given two vectors ${\displaystyle {}(x_{1},y_{1})}$ and ${\displaystyle {}(x_{2},y_{2})}$, the determinant of the ${\displaystyle {}2\times 2}$-matrix defined by these vectors is equal (up to sign) to the area of the plane parallelogram spanned by the vectors.

Let ${\displaystyle {}M}$ be a ${\displaystyle {}2\times 2}$-matrix. Show that

${\displaystyle {}\operatorname {trace} {\left(M\right)}=1+\det M-\det {\left(E_{2}-M\right)}\,}$

holds.

Let ${\displaystyle {}z\in \mathbb {C} }$ and let

${\displaystyle \mathbb {C} \longrightarrow \mathbb {C} ,w\longmapsto zw,}$

be the associated multiplication. Compute the determinant of this map, considering it as a real-linear map

${\displaystyle {}\mathbb {R} ^{2}\rightarrow \mathbb {R} ^{2}}$.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V_{1},\ldots ,V_{n}}$ and ${\displaystyle {}W}$ be vector spaces over ${\displaystyle {}K}$. Let

${\displaystyle \Phi \colon V_{1}\times \cdots \times V_{n}\longrightarrow W}$

be a multilinear mapping, and let ${\displaystyle {}v_{1j},\ldots ,v_{m_{j}j}\in V_{j}}$ and ${\displaystyle {}a_{ij}\in K}$. Show that

${\displaystyle \Phi {\left(\sum _{i=1}^{m_{1}}a_{i1}v_{i1},\ldots ,\sum _{i=1}^{m_{n}}a_{in}v_{in}\right)}=\sum _{(i_{1},\ldots ,i_{n})\in \{1,\ldots ,m_{1}\}\times \cdots \times \{1,\ldots ,m_{n}\}}a_{i_{1}}\cdots a_{i_{n}}\Phi {\left(v_{i_{1}1},\ldots ,v_{i_{n}n}\right)}\,}$

holds.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V_{1},\ldots ,V_{n}}$ and ${\displaystyle {}W}$ denote vector spaces over ${\displaystyle {}K}$. Let ${\displaystyle {}v_{i_{j}}}$, ${\displaystyle {}i_{j}\in I_{j}}$, be generating systems of ${\displaystyle {}V_{j}}$, ${\displaystyle {}j=1,\ldots ,n}$. Show that a multilinear mapping

${\displaystyle \triangle \colon V_{1}\times \cdots \times V_{n}\longrightarrow W}$

is determined by

${\displaystyle \triangle (v_{i_{1}},\ldots ,v_{i_{n}}).}$

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

${\displaystyle \triangle \colon V\times V\longrightarrow K}$

be a multilinear and alternating mapping. Let ${\displaystyle {}u,v,w\in V}$. Simplify

${\displaystyle \triangle {\begin{pmatrix}u+2v\\v+3w\end{pmatrix}}.}$

Let ${\displaystyle {}K}$ be a field. Show that the mapping

${\displaystyle \operatorname {Mat} _{2}(K)\longrightarrow K,{\begin{pmatrix}a&b\\c&d\end{pmatrix}}\longmapsto ad+cb,}$

is multilinear, but not alternating.

Let ${\displaystyle {}K}$ be a field. Is the mapping

${\displaystyle \operatorname {Mat} _{2}(K)\longrightarrow K,{\begin{pmatrix}a&b\\c&d\end{pmatrix}}\longmapsto ac-bd,}$

multilinear in den rows? In the columns?

Let ${\displaystyle {}K}$ be a field and ${\displaystyle {}n\in \mathbb {N} _{+}}$. Show that the determinant

${\displaystyle \operatorname {Mat} _{n}(K)=(K^{n})^{n}\longrightarrow K,M\longmapsto \det M,}$

fulfills (for arbitrary ${\displaystyle {}k\in \{1,\ldots ,n\}}$ and arbitrary ${\displaystyle {}n-1}$ vectors ${\displaystyle {}v_{1},\ldots ,v_{k-1},v_{k+1},\ldots ,v_{n}\in K^{n}}$, for ${\displaystyle {}u\in K^{n}}$ and for ${\displaystyle {}s\in K}$) the equality

${\displaystyle {}\det {\begin{pmatrix}v_{1}\\\vdots \\v_{k-1}\\su\\v_{k+1}\\\vdots \\v_{n}\end{pmatrix}}=s\det {\begin{pmatrix}v_{1}\\\vdots \\v_{k-1}\\u\\v_{k+1}\\\vdots \\v_{n}\end{pmatrix}}\,.}$

Let ${\displaystyle {}M}$ be the following square matrix

${\displaystyle {}M={\begin{pmatrix}A&B\\0&D\end{pmatrix}}\,,}$

where ${\displaystyle {}A}$ and ${\displaystyle {}D}$ are square matrices. Prove that ${\displaystyle {}\det M=\det A\cdot \det D}$.

Let ${\displaystyle {}M}$ be a square matrix of the form

${\displaystyle {}M={\begin{pmatrix}A&B\\C&D\end{pmatrix}}\,}$

with square matrices ${\displaystyle {}A,B,C}$ and ${\displaystyle {}D}$. Show by an example that the equality

${\displaystyle {}\det M=\det A\cdot \det D-\det B\cdot \det C\,}$

does not hold in general.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V}$ and ${\displaystyle {}W}$ denote a ${\displaystyle {}K}$-vector space. Determine whether the mapping

${\displaystyle \operatorname {Hom} _{K}{\left(V,W\right)}\times V\longrightarrow W,(\varphi ,v)\longmapsto \varphi (v),}$

is multilinear.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V_{1},\ldots ,V_{n}}$ and ${\displaystyle {}W}$ denote vector spaces over ${\displaystyle {}K}$. Let

${\displaystyle \Phi \colon V_{1}\times \cdots \times V_{n}\longrightarrow W}$

be a multilinear mapping. Show that the set

${\displaystyle {\left\{\left(v_{1},\,\ldots ,\,v_{n}\right)\in V_{1}\times \cdots \times V_{n}\mid \Phi \left(v_{1},\,\ldots ,\,v_{n}\right)=0\right\}}}$

is, in general, not a linear subspace of ${\displaystyle {}V_{1}\times \cdots \times V_{n}}$.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V_{1},\ldots ,V_{n}}$ and ${\displaystyle {}W}$ denote vector spaces over ${\displaystyle {}K}$. Show that the set of all multilinear mappings is, in a natural way, a vector space, denoted by ${\displaystyle {}\operatorname {Mult} _{K}{\left(V_{1},\ldots ,V_{n},W\right)}}$.

Let ${\displaystyle {}K}$ be a field, let ${\displaystyle {}V}$ and ${\displaystyle {}W}$ be vector spaces over ${\displaystyle {}K}$, and ${\displaystyle {}n\in \mathbb {N} }$. Show that the set of all alternating mappings (denoted by ${\displaystyle {}\operatorname {Alt} _{K}^{n}{\left(V,W\right)}}$) is a linear subspace of ${\displaystyle {}\operatorname {Mult} _{K}{\left(V,\ldots ,V,W\right)}}$ (where the vector space ${\displaystyle {}V}$ appears ${\displaystyle {}n}$-fold).

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

field, let ${\displaystyle {}V}$ and ${\displaystyle {}W}$ be ${\displaystyle {}K}$-vector spaces, and let

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

denote a ${\displaystyle {}K}$-linear mapping, Let

${\displaystyle \triangle \colon W^{m}\longrightarrow K}$

denote a multilinear mapping. Show that the composed mapping

${\displaystyle V^{m}\longrightarrow K,(v_{1},\ldots ,v_{m})\longmapsto \triangle \left(\varphi (v_{1}),\,\ldots ,\,\varphi (v_{m})\right),}$

is multilinear. Moreover, show that, if ${\displaystyle {}\triangle }$ is alternating, then also ${\displaystyle {}\triangle \circ \varphi ^{n}}$ is alternating, and that, if ${\displaystyle {}\varphi }$ is bijective, also the converse holds.

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V_{1},\ldots ,V_{n},W_{1},\ldots ,W_{n}}$ and ${\displaystyle {}Z}$ be vector spaces over ${\displaystyle {}K}$. Let

${\displaystyle \varphi _{i}\colon V_{i}\longrightarrow W_{i}}$

denote linear mappings, and let

${\displaystyle \pi \colon W_{1}\times \cdots \times W_{n}\longrightarrow Z}$

be a multilinear mapping. Show that the mapping

${\displaystyle \pi \circ (\varphi _{1}\times \cdots \times \varphi _{n})\colon V_{1}\times \cdots \times V_{n}\longrightarrow Z,(v_{1},\ldots ,v_{n})\longmapsto \pi (\varphi _{1}(v_{1}),\ldots ,\varphi _{n}(v_{n})),}$

is also multilinear.

Compute for the  

(complex) matrix

${\displaystyle {}M={\begin{pmatrix}1+{\mathrm {i} }&2{\mathrm {i} }&3\\0&1-{\mathrm {i} }&-1+3{\mathrm {i} }\\4-{\mathrm {i} }&0&2\end{pmatrix}}\,}$

the determinant and the inverse matrix.

Determine for which ${\displaystyle {}x\in \mathbb {C} }$ the matrix

${\displaystyle {\begin{pmatrix}x^{2}+x&-x\\-x^{3}+2x^{2}+5x-1&x^{2}-x\end{pmatrix}}}$

is invertible.

Hand-in-exercises

Let ${\displaystyle {}M\in \operatorname {Mat} _{n}(\mathbb {Q} )}$. Show that it does not make a difference, whether we compute the determinant in ${\displaystyle {}\mathbb {Q} }$, in ${\displaystyle {}\mathbb {R} }$, or in ${\displaystyle {}\mathbb {C} }$.

Compute the determinant of the elementary matrices.

Compute the determinant of the matrix

${\displaystyle {\begin{pmatrix}1+{\mathrm {i} }&3-2{\mathrm {i} }&5\\{\mathrm {i} }&1&3-{\mathrm {i} }\\2{\mathrm {i} }&-4-{\mathrm {i} }&2+{\mathrm {i} }\end{pmatrix}}.}$

Compute the determinant of the matrix

${\displaystyle {}A={\begin{pmatrix}2&1&0&-2\\1&3&3&-1\\3&2&4&-3\\2&-2&2&3\end{pmatrix}}\,.}$

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

${\displaystyle \triangle \colon V\times V\times V\longrightarrow K}$

be a multilinear and alternating mapping. Let ${\displaystyle {}u,v,w\in V}$. Simplify the term

${\displaystyle \triangle {\begin{pmatrix}u+v+w\\2u+3z\\4w-5z\end{pmatrix}}.}$

Let ${\displaystyle {}K}$ be a field, and let ${\displaystyle {}V_{1},\ldots ,V_{n}}$ vector spaces over ${\displaystyle {}K}$. Let

${\displaystyle \varphi _{i}\colon V_{i}\longrightarrow K}$

(${\displaystyle {}i=1,\ldots ,n}$), denote linear mappings. Show that the mapping

${\displaystyle \varphi \colon V_{1}\times \cdots \times V_{n}\longrightarrow K,{\left(v_{1},\ldots ,v_{n}\right)}\longmapsto \varphi _{1}(v_{1})\cdots \varphi _{n}(v_{n}),}$

is multilinear.

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