Mathematics for Applied Sciences (Osnabrück 2023-2024)/Part I/Exercise sheet 23/refcontrol

Exercises

Exercise Create referencenumber

Write in ${}\mathbb {Q} ^{2}$ the vector

(2,-7)

as a linear combination of the vectors

(5,-3){\text{ and }}(-11,4).

Exercise Create referencenumber

Write in ${}\mathbb {C} ^{2}$ the vector

(1,0)

as a linear combination MDLD/linear combination of the vectors

(3+5{\mathrm {i} },-3+2{\mathrm {i} }){\text{ and }}(1-6{\mathrm {i} },4-{\mathrm {i} }).

===Exercise Exercise 23.3

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Let ${}K$ be a field,MDLD/field and let ${}V$ be a ${}K$ -vector space.MDLD/vector space Show that the following statements hold.

For a family ${}v_{i}$ , ${}i\in I$ , of elements in ${}V$ , linear span MDLD/linear span is a linear subspace MDLD/linear subspace of ${}V$ .
The family ${}v_{i}$ , ${}i\in I$ , is a spanning system of ${}V$ if and only if
${}\langle v_{i},\,i\in I\rangle =V\,.$

Exercise Create referencenumber

Let ${}K$ be a field,MDLD/field and let ${}V$ be a ${}K$ -vector space.MDLD/vector space Let ${}v_{i}$ , ${}i\in I$ , be a family of vectors in ${}V$ and ${}w_{j}$ , ${}j\in J$ , another family of vectors in ${}V$ . Then, for the spanned linear subspaces,MDLD/spanned linear subspaces the inclusion ${}\langle v_{i},\,i\in I\rangle \subseteq \langle w_{j},\,j\in J\rangle$ holds, if and only if ${}v_{i}\in \langle w_{j},\,j\in J\rangle$ holds for all ${}i\in I$ .

Exercise Create referencenumber

Let ${}K$ be a field,MDLD/field and let ${}V$ be a ${}K$ -vector space.MDLD/vector space Let ${}v_{i}$ , ${}i\in I$ , be a family of vectors in ${}V$ , and let ${}w\in V$ be another vector. Assume that the family

w,v_{i},i\in I,

is a system of generators of ${}V$ , and that ${}w$ is a linear combination of the ${}v_{i}$ , ${}i\in I$ . Prove that also ${}v_{i}$ , ${}i\in I$ , is a system of generators of ${}V$ .

Exercise Create referencenumber

We consider in ${}\mathbb {Q} ^{3}$ the linear subspaces MDLD/linear subspaces

{}U=\langle {\begin{pmatrix}2\\1\\4\end{pmatrix}},{\begin{pmatrix}3\\-2\\7\end{pmatrix}}\rangle \,

and

{}W=\langle {\begin{pmatrix}5\\-1\\11\end{pmatrix}},{\begin{pmatrix}1\\-3\\3\end{pmatrix}}\rangle \,.

Show that ${}U=W$ .

Exercise Create referencenumber

Show that the three vectors

{\begin{pmatrix}0\\1\\2\\1\end{pmatrix}},\,{\begin{pmatrix}4\\3\\0\\2\end{pmatrix}},\,{\begin{pmatrix}1\\7\\0\\-1\end{pmatrix}}

in ${}\mathbb {R} ^{4}$ are linearly independent.MDLD/linearly independent

Exercise Create referencenumber

Find, for the vectors

{\begin{pmatrix}7\\-5\\3\end{pmatrix}},\,{\begin{pmatrix}-4\\1\\-6\end{pmatrix}},\,{\begin{pmatrix}2\\8\\0\end{pmatrix}},\,{\begin{pmatrix}5\\-5\\8\end{pmatrix}}

in ${}\mathbb {Q} ^{3}$ , a non-trivial representation of the zero vector.

Exercise Create referencenumber

Give an example of three vectors in ${}\mathbb {R} ^{3}$ such that each two of them is linearly independent, but all three vectors together are linearly dependent.

===Exercise Exercise 23.10

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Let ${}K$ be a field, let ${}V$ be a ${}K$ -vector space and let ${}v_{i}$ , ${}i\in I$ , be a family of vectors in ${}V$ . Prove the following facts.

If the family is linearly independent, then for each subset ${}J\subseteq I$ , also the family ${}v_{i}$ , ${}i\in J$ is linearly independent.
The empty family is linearly independent.
If the family contains the null vector, then it is not linearly independent.
If a vector appears several times in the family, then the family is not linearly independent.
A vector ${}v$ is linearly independent if and only if ${}v\neq 0$ .
Two vectors ${}v$ and ${}u$ are linearly independent if and only if ${}u$ is not a scalar multiple of ${}v$ and vice versa.

Exercise Create referencenumber

Let ${}K$ be a field, let ${}V$ be a ${}K$ -vector space, and let ${}v_{i}$ , ${}i\in I$ be a family of vectors in ${}V$ . Let ${}\lambda _{i}$ , ${}i\in I$ be a family of elements ${}\neq 0$ in ${}K$ . Prove that the family ${}v_{i}$ , ${}i\in I$ , is linearly independent (a system of generators of ${}V$ , a basis of ${}V$ ), if and only if the same holds for the family ${}\lambda _{i}v_{i}$ , ${}i\in I$ .

Exercise Create referencenumber

Determine a basis for the solution space of the linear equation

{}3x+4y-2z+5w=0\,.

Exercise Create referencenumber

Determine a basis for the solution space of the linear system of equations

-2x+3y-z+4w=0{\text{ and }}3z-2w=0.

Exercise Create referencenumber

Prove that in ${}\mathbb {R} ^{3}$ , the three vectors

{\begin{pmatrix}2\\1\\5\end{pmatrix}}\,,{\begin{pmatrix}1\\3\\7\end{pmatrix}}\,,{\begin{pmatrix}4\\1\\2\end{pmatrix}}

are a basis.

Exercise Create referencenumber

Establish if in ${}\mathbb {C} ^{2}$ the two vectors

{\begin{pmatrix}2+7{\mathrm {i} }\\3-{\mathrm {i} }\end{pmatrix}}{\text{ and }}{\begin{pmatrix}15+26{\mathrm {i} }\\13-7{\mathrm {i} }\end{pmatrix}}

form a basis.

Exercise Create referencenumber

Let ${}K$ be a field. Find a linear system of equations in three variables, whose solution space is exactly

{\left\{\lambda {\begin{pmatrix}3\\2\\-5\end{pmatrix}}\mid \lambda \in K\right\}}.

Exercise Create referencenumber

Let ${}K$ be a field, and let

{}{\begin{pmatrix}a_{1}\\\vdots \\a_{n}\end{pmatrix}}\in K^{n}\,

be a nonzero vector. Find a linear system of equations in ${}n$ variables with ${}n-1$ equations, whose solution space is exactly

{\left\{\lambda {\begin{pmatrix}a_{1}\\\vdots \\a_{n}\end{pmatrix}}\mid \lambda \in K\right\}}.

===Exercise Exercise 23.18

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Let ${}K$ be a field, and let ${}V$ be a ${}K$ -vector space of dimension ${}n=\dim _{}{\left(V\right)}$ . Suppose that ${}n$ vectors ${}v_{1},\ldots ,v_{n}$ in ${}V$ are given. Prove that the following facts are equivalent.

${}v_{1},\ldots ,v_{n}$ form a basis for ${}V$ .
${}v_{1},\ldots ,v_{n}$ form a system of generators for ${}V$ .
${}v_{1},\ldots ,v_{n}$ are linearly independent.

Exercise Create referencenumber

Let ${}K$ be a field, and let ${}K[X]$ denote the polynomial ringMDLD/polynomial ring (field 1) over ${}K$ . Let ${}d\in \mathbb {N}$ . Show that the set of all polynomials of degree ${}\leq d$ is a finite dimensionalMDLD/finite dimensional subspaceMDLD/subspace of ${}K[X]$ . What is its dimension?MDLD/dimension (vs)

Exercise Create referencenumber

Show that the set of all real polynomialsMDLD/polynomials (field 1) of degree MDLD/degree (polynomial) ${}\leq 4$ , which have a zero for ${}-2$ and for ${}3$ , form a finite-dimensionalMDLD/finite-dimensional linear subspace MDLD/linear subspace in ${}\mathbb {R} [X]$ . Determine its dimension.MDLD/dimension (vs)

Exercise * Create referencenumber

Let ${}K$ be a field, and let ${}V$ and ${}W$ be two finite-dimensional ${}K$ vector spaces with

{}\dim _{}{\left(V\right)}=n\,

and

{}\dim _{}{\left(W\right)}=m\,.

What is the dimension of the Cartesian product ${}V\times W$ ?

Exercise Create referencenumber

Let ${}V$ be a finite-dimensional vector space over the complex numbers, and let ${}v_{1},\ldots ,v_{n}$ be a basis of ${}V$ . Prove that the family of vectors

v_{1},\ldots ,v_{n}{\text{ and }}{\mathrm {i} }v_{1},\ldots ,{\mathrm {i} }v_{n}

form a basis for ${}V$ , considered as a real vector space.

Exercise Create referencenumber

Let ${}K$ be a finite fieldMDLD/finite field with ${}q$ elements, and let ${}V$ be an ${}n$ -dimensional MDLD/dimensional (vs) vector space.MDLD/vector space Let ${}v_{1},v_{2},v_{3},\ldots$ be an enumeration (without repetitions) of the elements from ${}V$ . After how many elements can we be sure that these form a generating system MDLD/generating system (vs) of ${}V$ .

Hand-in-exercises

Exercise (3 marks) Create referencenumber

Write in ${}\mathbb {Q} ^{3}$ the vector

(2,5,-3)

as a linear combination of the vectors

(1,2,3),(0,1,1){\text{ und }}(-1,2,4).

Prove that it cannot be expressed as a linear combination of two of the three vectors.

Exercise (4 marks) Create referencenumber

We consider in ${}\mathbb {Q} ^{4}$ the linear subspaces MDLD/linear subspaces

{}U=\langle {\begin{pmatrix}3\\1\\-5\\2\end{pmatrix}},{\begin{pmatrix}2\\-2\\4\\-3\end{pmatrix}},{\begin{pmatrix}1\\0\\3\\2\end{pmatrix}}\rangle \,

and

{}W=\langle {\begin{pmatrix}6\\-1\\2\\1\end{pmatrix}},{\begin{pmatrix}0\\-2\\-2\\-7\end{pmatrix}},{\begin{pmatrix}9\\2\\-1\\10\end{pmatrix}}\rangle \,.

Show that ${}U=W$ .

Exercise (2 marks) Create referencenumber

Establish if in ${}\mathbb {R} ^{3}$ the three vectors

{\begin{pmatrix}2\\3\\-5\end{pmatrix}}\,,{\begin{pmatrix}9\\2\\6\end{pmatrix}}\,,{\begin{pmatrix}-1\\4\\-1\end{pmatrix}}

form a basis.

Exercise (2 marks) Create referencenumber

Establish if in ${}\mathbb {C} ^{2}$ the two vectors

{\begin{pmatrix}2-7{\mathrm {i} }\\-3+2{\mathrm {i} }\end{pmatrix}}{\text{ and }}{\begin{pmatrix}5+6{\mathrm {i} }\\3-17{\mathrm {i} }\end{pmatrix}}

form a basis.

Exercise (4 marks) Create referencenumber

Let ${}\mathbb {Q} ^{n}$ be the ${}n$ -dimensional standard vector space over ${}\mathbb {Q}$ , and let ${}v_{1},\ldots ,v_{n}\in \mathbb {Q} ^{n}$ be a family of vectors. Prove that this family is a ${}\mathbb {Q}$ -basis of ${}\mathbb {Q} ^{n}$ if and only if the same family, considered as a family in ${}\mathbb {R} ^{n}$ , is a ${}\mathbb {R}$ -basis of ${}\mathbb {R} ^{n}$ .

Exercise (4 marks) Create referencenumber

Show that the set of all real polynomialsMDLD/polynomials (field 1) of degreeMDLD/degree (Polynom) ${}\leq 6$ , which have a zero at ${}-1$ , at ${}0$ and at ${}1$ , is a finite dimensionalMDLD/finite dimensional subspaceMDLD/subspace (linear) of ${}\mathbb {R} [X]$ . Determine the dimension MDLD/dimension (vs) of this vector space.

Exercise (2 marks) Create referencenumber

Let ${}K$ be a field, and let ${}V$ be a ${}K$ -vector space. Let ${}v_{1},\ldots ,v_{m}$ be a family of vectors in ${}V$ , and let

{}U=\langle v_{i},\,i=1,\ldots ,m\rangle \,

be the linear subspace MDLD/linear subspace they span. Prove that the family is linearly independent if and only if the dimension of ${}U$ is exactly ${}m$ .

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