Linear algebra (Osnabrück 2024-2025)/Part I/Lecture 16/refcontrol

The determinant

Suppose an ${}n\times n$ -matrix is given. Can we see "at a glance“ whether it is invertible?MDLD/invertible (matrix) Does there exist an expression in the ${}n^{2}$ entries of the matrix to decide this? This question has a positive answer in terms of the determinant.

Definition

Let ${}K$ be a field,MDLD/field and let ${}M$ denote an ${}n\times n$ -matrix MDLD/matrix over ${}K$ with entries ${}a_{ij}$ . For ${}i\in \{1,\ldots ,n\}$ , let ${}M_{i}$ denote the ${}(n-1)\times (n-1)$ -matrix, which arises from ${}M$ , when we remove the first column and the ${}i$ -th row. Then one defines recursively the determinant of ${}M$ by

{}\det M={\begin{cases}a_{11}\,,&{\text{ for }}n=1\,,\\\sum _{i=1}^{n}(-1)^{i+1}a_{i1}\det M_{i}&{\text{ for }}n\geq 2\,.\end{cases}}\,

The determinant is only defined for square matrices. For small ${}n$ , the determinant can be computed easily.

Example Create referencenumber

For a ${}2\times 2$ -matrix MDLD/matrix

{}M={\begin{pmatrix}a&b\\c&d\end{pmatrix}}\,,

we have

\det {\begin{pmatrix}a&b\\c&d\end{pmatrix}}=ad-cb.

Example Create referencenumber

For a ${}3\times 3$ -matrix MDLD/matrix ${}M={\begin{pmatrix}a_{11}&a_{12}&a_{13}\\a_{21}&a_{22}&a_{23}\\a_{31}&a_{32}&a_{33}\end{pmatrix}}$ , we have

\det {\begin{pmatrix}a_{11}&a_{12}&a_{13}\\a_{21}&a_{22}&a_{23}\\a_{31}&a_{32}&a_{33}\end{pmatrix}}=a_{11}a_{22}a_{33}+a_{12}a_{23}a_{31}+a_{13}a_{21}a_{32}-a_{13}a_{22}a_{31}-a_{11}a_{23}a_{32}-a_{12}a_{21}a_{33}.

This is called the rule of Sarrus.

LemmaLemma 16.4 change

For an upper triangular matrix MDLD/upper triangular matrix

{}M={\begin{pmatrix}b_{1}&\ast &\cdots &\cdots &\ast \\0&b_{2}&\ast &\cdots &\ast \\\vdots &\ddots &\ddots &\ddots &\vdots \\0&\cdots &0&b_{n-1}&\ast \\0&\cdots &\cdots &0&b_{n}\end{pmatrix}}\,,

we have

{}\det M=b_{1}b_{2}\cdots b_{n-1}b_{n}\,.

In particular, for the

identity matrix MDLD/identity matrix we get

{}\det E_{n}=1

.

Proof

This follows with a simple induction directly from the recursive definition of the determinant.MDLD/determinant (rec)

\Box

Multilinear and alternatings mappings

Wir führen zwei Begriffe ein, the we im Moment hauptsächlich zum weiteren Verständnis the Determinante brauchen.

Definition

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

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

is called multilinear if, for every ${}i\in \{1,\ldots ,n\}$ and every ${}(n-1)$ -tuple ${}(v_{1},\ldots ,v_{i-1},v_{i+1},\ldots ,v_{n})$ with ${}v_{j}\in V_{j}$ , the induced mapping

V_{i}\longrightarrow W,v_{i}\longmapsto \Phi (v_{1},\ldots ,v_{i-1},v_{i},v_{i+1},\ldots ,v_{n}),

is

{}K

-linear.MDLD/linear (map)

For ${}n=2$ , this property is called bilinear. For example, the multiplikation in a field ${}K$ , that is, the mapping

K\times K\longrightarrow K,(x,y)\longmapsto xy,

is bilinear. Also, for a ${}K$ -vector space MDLD/vector space ${}V$ and its dual space MDLD/dual space ${}{V}^{*}$ , the evaluation mapping

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

is bilinear.

LemmaLemma 16.6 change

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

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

be a multilinear mapping,MDLD/multilinear mapping and let ${}v_{1j},\ldots ,v_{m_{j}j}\in V_{j}$ and ${}a_{ij}\in K$ . Then

\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)}\,.

Proof

See Exercise 16.17 .

\Box

Definition

Let ${}K$ be a field,MDLD/field let ${}V$ and ${}W$ denote ${}K$ -vector spaces,MDLD/vector spaces and let ${}n\in \mathbb {N}$ . A multilinear mapping MDLD/multilinear mapping

\Phi \colon V^{n}=\underbrace {V\times \cdots \times V} _{n{\text{-mal}}}\longrightarrow W

is called alternating if the following holds: Whenever in ${}v=(v_{1},\ldots ,v_{n})$ , two entries are identical, that is ${}v_{i}=v_{j}$ for a pair ${}i\neq j$ , then

{}\Phi (v)=0\,.

For an alternating mapping, there is only one vector space occurring several times in the product on the left.

LemmaLemma 16.8 change

Let ${}K$ be a field,MDLD/field let ${}V$ and ${}W$ denote ${}K$ -vector spaces,MDLD/vector spaces and let ${}n\in \mathbb {N}$ . Suppose that

\Phi \colon V^{n}=\underbrace {V\times \cdots \times V} _{n{\text{-mal}}}\longrightarrow W

is an alternating mapping.MDLD/alternating mapping Then

\Phi (v_{1},\ldots ,v_{r-1},v_{r},v_{r+1},\ldots ,v_{s-1},v_{s},v_{s+1},\ldots ,v_{n})=-\Phi (v_{1},\ldots ,v_{r-1},v_{s},v_{r+1},\ldots ,v_{s-1},v_{r},v_{s+1},\ldots ,v_{n})\,.

This means that if we swap two vectors, them the sign is changing.

Proof

Due to the definition of alternating and Lemma 16.6 , we have

{}{\begin{aligned}0&=\Phi (v_{1},\ldots ,v_{r-1},v_{r}+v_{s},v_{r+1},\ldots ,v_{s-1},v_{r}+v_{s},v_{s+1},\ldots ,v_{n})\\&=\Phi (v_{1},\ldots ,v_{r-1},v_{r},v_{r+1},\ldots ,v_{s-1},v_{s},v_{s+1},\ldots ,v_{n})+\Phi (v_{1},\ldots ,v_{r-1},v_{s},v_{r+1},\ldots ,v_{s-1},v_{r},v_{s+1},\ldots ,v_{n}).\end{aligned}}

\Box

The determinant is an alternating mapping

We want to show that the recursively defined determinant is a multilinear and alternating mapping. To make sense of this, we identify

{}\operatorname {Mat} _{n}(K)\cong (K^{n})^{n}\,,

that is, we identify a matrix with the ${}n$ -tuple of its rows. Thus, in the following, we consider a matrix as a column tuple

{\begin{pmatrix}v_{1}\\\vdots \\v_{n}\end{pmatrix}},

where the entries ${}v_{i}$ are row vectors of length ${}n$ .

TheoremTheorem 16.9 change

Let ${}K$ be a field, and ${}n\in \mathbb {N} _{+}$ . Then the determinant MDLD/determinant

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

is multilinear.MDLD/multilinear This means that for every ${}k\in \{1,\ldots ,n\}$ , and for every choice of ${}n-1$ vectors ${}v_{1},\ldots ,v_{k-1},v_{k+1},\ldots ,v_{n}\in K^{n}$ , and for any ${}u,w\in K^{n}$ , the identity

{}\det {\begin{pmatrix}v_{1}\\\vdots \\v_{k-1}\\u+w\\v_{k+1}\\\vdots \\v_{n}\end{pmatrix}}=\det {\begin{pmatrix}v_{1}\\\vdots \\v_{k-1}\\u\\v_{k+1}\\\vdots \\v_{n}\end{pmatrix}}+\det {\begin{pmatrix}v_{1}\\\vdots \\v_{k-1}\\w\\v_{k+1}\\\vdots \\v_{n}\end{pmatrix}}\,

holds, and for ${}s\in K$ , the identity

{}\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}}\,

holds.

Proof

Let

M:={\begin{pmatrix}v_{1}\\\vdots \\v_{k-1}\\u\\v_{k+1}\\\vdots \\v_{n}\end{pmatrix}}\,,M':={\begin{pmatrix}v_{1}\\\vdots \\v_{k-1}\\w\\v_{k+1}\\\vdots \\v_{n}\end{pmatrix}}{\text{ and }}{\tilde {M}}:={\begin{pmatrix}v_{1}\\\vdots \\v_{k-1}\\u+w\\v_{k+1}\\\vdots \\v_{n}\end{pmatrix}},

where we denote the entries and the matrices arising from deleting a row in an analogous way. In particular, ${}u=\left(a_{k1},\,\ldots ,\,a_{kn}\right)$ and ${}w=\left(a_{k1}',\,\ldots ,\,a_{kn}'\right)$ . We prove the statement by induction over ${}n$ , For ${}i\neq k$ , we have ${}{\tilde {a}}_{i1}=a_{i1}=a'_{i1}$ and

{}\det {\tilde {M}}_{i}=\det M_{i}+\det M'_{i}\,

due to the induction hypothesis. For ${}i=k$ , we have ${}M_{k}=M_{k}'={\tilde {M}}_{k}$ and ${}{\tilde {a}}_{k1}=a_{k1}+a'_{k1}$ . Altogether, we get

{}{\begin{aligned}\det {\tilde {M}}&=\sum _{i=1}^{n}(-1)^{i+1}{\tilde {a}}_{i1}\det {\tilde {M}}_{i}\\&=\sum _{i=1,\,i\neq k}^{n}(-1)^{i+1}a_{i1}(\det {M}_{i}+\det {M}'_{i})+(-1)^{k+1}(a_{k1}+a'_{k1})(\det {\tilde {M}}_{k})\\&=\sum _{i=1,\,i\neq k}^{n}(-1)^{i+1}a_{i1}\det {M}_{i}+\sum _{i=1,\,i\neq k}^{n}(-1)^{i+1}a_{i1}\det {M}'_{i}+(-1)^{k+1}a_{k1}\det M_{k}+(-1)^{k+1}a'_{k1}\det M_{k}\\&=\sum _{i=1}^{n}(-1)^{i+1}a_{i1}\det {M}_{i}+\sum _{i=1,\,i\neq k,\,}^{n}(-1)^{i+1}a_{i1}\det {M}'_{i}+(-1)^{k+1}a'_{k1}\det M_{k}\\&=\sum _{i=1}^{n}(-1)^{i+1}a_{i1}\det {M}_{i}+\sum _{i=1}^{n}(-1)^{i+1}a'_{i1}\det {M}'_{i}\\&=\det M+\det M'.\end{aligned}}

The compatibility with the scalar multiplication is proved in a similar way, see Exercise 16.22 .

\Box

TheoremTheorem 16.10 change

Let ${}K$ be a field MDLD/field and ${}n\in \mathbb {N} _{+}$ . Then the determinant MDLD/determinant

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

is

alternating.MDLD/alternating

Proof

We proof the statement by induction over ${}n$ , So suppose that ${}n\geq 2$ and set ${}M={\begin{pmatrix}v_{1}\\\vdots \\v_{n}\end{pmatrix}}={\left(a_{ij}\right)}_{ij}$ . Let ${}v_{r}$ and ${}v_{s}$ with ${}r<s$ be the relevant row. By definition, we have ${}\det M=\sum _{i=1}^{n}(-1)^{i+1}a_{i1}\det M_{i}$ . Due to the induction hypothesis, we have ${}\det M_{i}=0$ for ${}i\neq r,s$ , because two rows coincide in these cases. Therefore,

{}\det M=(-1)^{r+1}a_{r1}\det M_{r}+(-1)^{s+1}a_{s1}\det M_{s}\,,

where ${}a_{r1}=a_{s1}$ . The matrices ${}M_{r}$ and ${}M_{s}$ consist in the same rows, however, the row ${}z=v_{r}=v_{s}$ is in ${}M_{r}$ the ${}(s-1)$ -th row and in ${}M_{s}$ the ${}r$ -th row. All other rows occur in both matrices in the same order. By swapping altogether ${}s-r-1$ times adjacent rows, we can transform ${}M_{r}$ into ${}M_{s}$ . Due to the induction hypothesis and Lemma 16.8 , their determinants are related by the factor ${}(-1)^{s-r-1}$ , thus ${}\det M_{s}=(-1)^{s-r-1}\det M_{r}$ . Using this, we obtain

{}{\begin{aligned}\det M&=(-1)^{r+1}a_{r1}\det M_{r}+(-1)^{s+1}a_{s1}\det M_{s}\\&=a_{r1}{\left((-1)^{r+1}\det M_{r}+(-1)^{s+1}(-1)^{s-r-1}\det M_{r}\right)}\\&=a_{r1}{\left((-1)^{r+1}+(-1)^{2s-r}\right)}\det M_{r}\\&=a_{r1}{\left((-1)^{r+1}+(-1)^{r}\right)}\det M_{r}\\&=0.\end{aligned}}

\Box

The property of the determinant to be alternating simplifies its computation. In particular, it is clear how the determinat behaves under elementary row operations. If a row is multiplied with a number ${}s$ , the determinant has to be multiplied with ${}s$ as well. If two rows are swapped, then the sign of the determinant changes. If a row (or a multiple of a row) is added to another row, then the determinant does not change.

TheoremTheorem 16.11 change

Let ${}K$ be a field,MDLD/field and let ${}M$ denote an ${}n\times n$ -matrix MDLD/matrix

over

{}K

. Then the following statements are equivalent.

We have ${}\det M\neq 0$ .
The rows of ${}M$ are linearly independent.MDLD/linearly independent
${}M$ is invertible.MDLD/invertible (matrix)
We have ${}\operatorname {rk} \,M=n$ .

Proof

The relation between rank, invertibility and linear independence was proven in Corollary 12.16 . Suppose now that the rows are linearly dependent.MDLD/linearly dependent After exchanging rows, we may assume that ${}v_{n}=\sum _{i=1}^{n-1}s_{i}v_{i}$ . Then, due to Theorem 16.9 and Theorem 16.10 , we get

{}\det M=\det {\begin{pmatrix}v_{1}\\\vdots \\v_{n-1}\\\sum _{i=1}^{n-1}s_{i}v_{i}\end{pmatrix}}=\sum _{i=1}^{n-1}s_{i}\det {\begin{pmatrix}v_{1}\\\vdots \\v_{n-1}\\v_{i}\end{pmatrix}}=0\,.

Now suppose that the rows are linearly independent. Then, by exchanging of rows, scaling and addition of a row to another row, we can transform the matrix successively into the identity matrix. During these manipulations, the determinant is multiplied with some factor ${}\neq 0$ . Since the determinant of the identity matrix is ${}1$ , the determinant of the initial matrix is ${}\neq 0$ .

\Box

Remark

In case ${}K=\mathbb {R}$ , the determinant MDLD/determinant is in tight relation to volumes of geometric objects. If we consider in ${}\mathbb {R} ^{n}$ vectors ${}v_{1},\ldots ,v_{n}$ , then they span a parallelotope. This is defined by

{}P:={\left\{s_{1}v_{1}+\cdots +s_{n}v_{n}\mid s_{i}\in [0,1]\right\}}\,.

It consists of all linear combinations MDLD/linear combinations of these vectors, where all the scalars belong to the unit interval. If the vectors are linearly independent, then this is a "voluminous“ body, otherwise it is an object of smaller dimension. Now the relation

{}\operatorname {vol} \,P=\vert {\det {\left(v_{1},\ldots ,v_{n}\right)}}\vert \,

holds, saying that the volume of the parallelotope is the modulus of the determinant of the matrix, consisting of the spanning vectors as columns.

For a proof of the relation between determinant and volume just mentioned, see Fact *****.

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