Solutions To Mathematics Textbooks/Algebra (9780132413770)/Chapter 4

Exercise 1.1[edit | edit source]

Let ${\displaystyle f(M):F^{m\times n}\rightarrow F^{l\times p}}$ such that ${\displaystyle f(M)=AMB}$ where ${\displaystyle A\in F^{l\times m},B\in F^{n\times p}}$. Then for ${\displaystyle M,N\in F^{m\times n}}$ and ${\displaystyle \alpha ,\beta \in F}$ it holds ${\displaystyle f(\alpha M+\beta N)=A(\alpha M+\beta N)B=\alpha AMB+\beta ANB=\alpha f(M)+\beta f(N)}$ , so ${\displaystyle f}$ is a linear transformation.

Exercise 1.3[edit | edit source]

The matrix ${\displaystyle A\in F^{m\times n}}$ is a linear mapping ${\displaystyle A:F^{n}\rightarrow F^{m}}$. Let ${\displaystyle {\mathsf {B}}=\{v_{1},\ldots ,v_{n}\}}$ be a basis for ${\displaystyle F^{n}}$. Then the space ${\displaystyle {\textrm {im}}~A={\textrm {Span}}(A(v_{1}),\ldots ,A(v_{n}))}$ has dimension at most ${\displaystyle \min(n,m)}$. Then, using the dimension formula we have ${\displaystyle \dim({\textrm {im}}~A)+\dim(\ker A)=\dim F^{n}=n}$, so rearranging we get ${\displaystyle \dim(\ker A)=n-\dim({\textrm {im}}~A)\geq n-\min(m,n)\geq n-m}$.

Exercise 1.4[edit | edit source]

Let ${\displaystyle A\in F^{m\times n}}$ be a matrix of rank 1. Then, the image of ${\displaystyle A}$ is a space spanned by a single vector, say ${\displaystyle v\in F^{n}}$, and ${\displaystyle Av=w}$ for some nonzero ${\displaystyle w\in F^{m}}$. We can assume that ${\displaystyle v=(1,0,\ldots ,0)}$, since the vector is unique up to a scaling and change of basis. Then, the kernel of ${\displaystyle A}$ is given by the vectors ${\displaystyle e_{i}}$ for ${\displaystyle i=2,\ldots ,n}$. Next, consider the matrix ${\displaystyle B={\frac {1}{v^{t}v}}wv^{t}}$, so that ${\displaystyle Bv=w}$ as well, and ${\displaystyle Be_{i}=0,i=2,\ldots ,n}$. It is easy to see that ${\displaystyle A}$ and ${\displaystyle B}$ describe the same linear transformation, so they are equal as matrices. The representation of ${\displaystyle B}$ is not unique, since we could scale one of the vectors ${\displaystyle v}$ and ${\displaystyle w}$ arbitrarily as long as we scale the other accordingly.

Exercise 1.5[edit | edit source]

a) It is very easy to see that performing the vector space operations coordinate-wise preserves the vector space structure in the product space.

b) Let ${\displaystyle T(u,v)=u+v}$. Then we have ${\displaystyle T(u_{1}+u_{2},v_{1}+v_{2})=u_{1}+v_{1}+u_{2}+v_{2}=T(u_{1},v_{1})+T(u_{2},v_{1})}$ and ${\displaystyle T(au,av)=au+av=aT(u,v)}$, so ${\displaystyle T}$ is a linear operator.

c) We have ${\displaystyle \dim({\textrm {im}}~T)+\dim(\ker T)=\dim(U\times W)}$ where ${\displaystyle \ker T=\{(u,w)\in U\times W:u=-w\}=\{(v,-v):v\in U\cap W\}}$ so ${\displaystyle \dim(\ker T)=\dim(U\cap W)}$. Furthermore, we have by definition that ${\displaystyle {\textrm {im}}~T=U\oplus W}$, and ${\displaystyle \dim(U\times W)=\dim U+\dim W}$. Therefore, the dimension formula has the form ${\displaystyle \dim(U\cap W)+\dim(U\oplus W)=\dim U+\dim W}$.

Exercise 2.1[edit | edit source]

We can write ${\displaystyle A=a_{11}e_{11}+a_{12}e_{12}+a_{21}e_{21}+a_{22}e_{22}}$, ${\displaystyle B=b_{11}e_{11}+b_{12}e_{12}+b_{21}e_{21}+b_{22}e_{22}}$ and ${\displaystyle M=m_{11}e_{11}+m_{12}e_{12}+m_{21}e_{21}+m_{22}e_{22}}$. We have the following multiplication table

	${\displaystyle e_{11}}$	${\displaystyle e_{12}}$	${\displaystyle e_{21}}$	${\displaystyle e_{22}}$
${\displaystyle e_{11}}$	${\displaystyle e_{11}}$	${\displaystyle e_{12}}$	${\displaystyle 0}$	${\displaystyle 0}$
${\displaystyle e_{12}}$	${\displaystyle 0}$	${\displaystyle 0}$	${\displaystyle e_{11}}$	${\displaystyle e_{12}}$
${\displaystyle e_{21}}$	${\displaystyle e_{21}}$	${\displaystyle e_{22}}$	${\displaystyle 0}$	${\displaystyle 0}$
${\displaystyle e_{22}}$	${\displaystyle 0}$	${\displaystyle 0}$	${\displaystyle e_{21}}$	${\displaystyle e_{22}}$

where the first element of a column denotes the matrix that is multiplied from the right by the first element of a given row. Then, ${\displaystyle AM=(a_{11}m_{11}+a_{21}m_{12})e_{11}+(a_{12}m_{11}+a_{22}m_{12})e_{12}+(a_{11}m_{21}+a_{21}m_{22})e_{21}+(a_{12}m_{21}+a_{22}m_{22})e_{22}}$. For ${\displaystyle AMB}$ we have then in the given basis the form

${\displaystyle {\begin{pmatrix}a_{11}m_{11}b_{11}+a_{21}m_{12}b_{11}+a_{11}m_{21}b_{12}+a_{21}m_{22}b_{12}\\a_{12}m_{11}b_{11}+a_{22}m_{12}b_{11}+a_{12}m_{21}b_{12}+a_{22}m_{22}b_{12}\\a_{11}m_{11}b_{21}+a_{21}m_{12}b_{21}+a_{11}m_{21}b_{22}+a_{21}m_{22}b_{22}\\a_{12}m_{11}b_{21}+a_{22}m_{12}b_{21}+a_{12}m_{21}b_{22}+a_{22}m_{22}b_{22}\end{pmatrix}}}$.

Exercise 2.3[edit | edit source]

The matrix with the given property satisfies the equation ${\displaystyle {\begin{pmatrix}a&b\\c&d\end{pmatrix}}{\begin{pmatrix}x\\x\end{pmatrix}}={\begin{pmatrix}x\\3x\end{pmatrix}}}$. Solving this yields that the matrix has to have the form ${\displaystyle {\begin{pmatrix}a&1-a\\c&3-c\end{pmatrix}}}$ for any ${\displaystyle a,c\in \mathbb {R} .}$

Exercise 2.5[edit | edit source]

Exercise 3.3[edit | edit source]

Exercise 4.2[edit | edit source]

Exercise 4.4[edit | edit source]

Exercise 4.6[edit | edit source]

Exercise 4.8[edit | edit source]

Exercise 5.3[edit | edit source]

Exercise 5.5[edit | edit source]

Exercise 5.10[edit | edit source]

Exercise 6.1[edit | edit source]

Exercise 6.4[edit | edit source]

Exercise 6.10[edit | edit source]

Exercise 6.11[edit | edit source]

Exercise 7.1[edit | edit source]

Exercise 7.3[edit | edit source]

Exercise 7.6[edit | edit source]

Exercise 7.7[edit | edit source]

Exercise M.1[edit | edit source]

Exercise M.2a[edit | edit source]

Exercise M.4[edit | edit source]

Exercise M.7[edit | edit source]

Exercise M.10[edit | edit source]

Exercise M.9[edit | edit source]