Printable version Study Notes of “Introduction to MATRIX ALGEBRA”
Summary
- Addition of matrices
Two matrices $[A]$ and $[B]$ can be added only if they are the same size. The addition is then shown as $$[C]=[A]+[B]$$ where $$c_{ij}=a_{ij} + b_{ij}$$ For example $$\begin{bmatrix}5& 2& 3\\ 1& 2& 7\end{bmatrix} + \begin{bmatrix}6& 7& -2\\ 3& 5& 19\end{bmatrix}$$ $$= \begin{bmatrix}5 + 6& 2 + 7& 3 - 2\\ 1 + 3& 2 + 5& 7 + 19\end{bmatrix} = \begin{bmatrix}11& 9& 1\\ 4& 7& 26\end{bmatrix}$$ - Subtraction of matrices
Two matrices $[A]$ and $[B]$ can be subtracted only if they are the same size. The subtraction is then given by $$[D] = [A]-[B]$$ where $$d_{ij}=a_{ij} - b_{ij}$$ For example $$\begin{bmatrix}5& 2& 3\\ 1& 2& 7\end{bmatrix} - \begin{bmatrix}6& 7& -2\\ 3& 5& 19\end{bmatrix}$$ $$= \begin{bmatrix}5 - 6& 2 - 7& 3 -(-2)\\ 1 - 3& 2 - 5& 7 - 19\end{bmatrix} = \begin{bmatrix}-1& -5& 5\\ -2& -3& -12\end{bmatrix}$$ - Multiplication of matrices
Two matrices $[A]$ and $[B]$ can be multiplied only if the number of columns of $[A]$ is equal to the number of rows of $[B]$ to give $$[C]_{m\times n}=[A]_{m\times p}\cdot[B]_{p\times n}$$ where $$c_{ij}=a_{i1}b_{1j}+a_{i2}b_{2j}+\cdots+a_{ip}b_{pj}= \sum_{k=1}^{p}a_{ik}b_{kj}$$ for each $i=1, \cdots, m$ and $j=1, \cdots, n$.
That is, the $i$-th row and the $j$-th column of $[C]$ is calculated by multiplying the $i$-th row of $[A]$ by the $j$-th column of $[B]$: $$c_{ij}=\begin{bmatrix}a_{i1} & a_{i2}& \cdots & a_{ip}\end{bmatrix}\cdot \begin{bmatrix}b_{1j}\\ b_{2j}\\ \vdots\\ b_{pj}\end{bmatrix}$$ For example, $$A=\begin{bmatrix}5& 2& 3\\ 1& 2& 7\end{bmatrix},\ B=\begin{bmatrix}3& -2\\ 5& -8\\ 9& -10\end{bmatrix},\ C=A\cdot B$$ we have $$c_{11}=\begin{bmatrix}5& 2& 3\end{bmatrix}\cdot \begin{bmatrix}3\\ 5\\ 9\end{bmatrix}=15+10+27=52,\ c_{12}=\begin{bmatrix}5& 2& 3\end{bmatrix}\cdot \begin{bmatrix}-2\\ -8\\ -10\end{bmatrix}=-10 -16 -30 = -56,$$ $$c_{21}=\begin{bmatrix}1& 2& 7\end{bmatrix}\cdot \begin{bmatrix}3\\ 5\\ 9\end{bmatrix}=3+10+63=76,\ c_{22}=\begin{bmatrix}1& 2& 7\end{bmatrix}\cdot \begin{bmatrix}-2\\ -8\\ -10\end{bmatrix}=-2-16-70=-88,$$ $$\Rightarrow C=\begin{bmatrix}52& -56\\ 76& -88\end{bmatrix}.$$ - Scalar product of matrices
If $[A]$ is a $m\times n$ matrix and $k$ is a real number, then the multiplication $[A]$ by a scalar $k$ is another $m\times n$ matrix $[B]$, where $b_{ij}=ka_{ij}$ for all $i$, $j$. For example, $$2\cdot\begin{bmatrix}5& 2& 3\\ 1& 2& 7\end{bmatrix} = \begin{bmatrix}10& 4& 6\\ 2& 4& 14\end{bmatrix}$$
- Linear combination of matrices
If $[A_1]$, $[A_2]$, $\cdots$, $[A_{p}]$ are matrices of the same size and $k_1$, $k_2$, $\cdots$, $k_p$ are scalars, then $$k_1A_1 + k_2A_2 + \cdots + k_pA_p$$ is called a linear combination of $[A_1]$, $[A_2]$, $\cdots$, $[A_{p}]$. - Rules of binary matrix operation
- Commutative law of addition
If $[A]$ and $[B]$ are $m\times n$ matrices, then $$[A]+[B] = [B] + [A]$$ - Associative law of addition
If $[A]$, $[B]$, and $[C]$ are all $m\times n$ matrices, then $$[A]+([B] + [C]) = ([A] + [B]) + [C]$$ - Associate law of multiplication
If $[A]$, $[B]$, and $[C]$ are $m\times n$, $n\times p$, and $p\times r$ size matrices. respectively. Then $$[A]\cdot([B]\cdot[C]) = ([A]\cdot[B])\cdot[C]$$ and the resulting matrix size on both sides of the equation is $m\times r$. - Distributive law
If $[A]$ and $[B]$ are $m\times n$ size matrices, and $[C]$ and $[D]$ are $n\times p$ size matrices, then $$[A]\cdot([C] + [D]) = [A]\cdot[C] + [A]\cdot[D]$$ $$([A] + [B])\cdot[C] = [A]\cdot[C] + [B]\cdot[C]$$ and the resulting matrix size on both sides of the equation is $m\times p$.
- Commutative law of addition
1. For the following matrices $$A=\begin{bmatrix}3& 0\\ -1& 2\\ 1& 1\end{bmatrix},\ B=\begin{bmatrix}4& -1\\ 0& 2\end{bmatrix},\ C=\begin{bmatrix}5& 2\\ 3& 5\\ 6& 7\end{bmatrix}.$$ Find where possible $4[A] + 5[C]$, $[A]\cdot[B]$, $[A]-2[C]$.
Solution:
$$4[A] + 5[C] = \begin{bmatrix}12& 0\\ -4& 8\\ 4& 4\end{bmatrix} + \begin{bmatrix}25& 10\\ 15& 25\\ 30& 35\end{bmatrix} = \begin{bmatrix}37& 10\\ 11& 33\\ 34& 39\end{bmatrix}$$ $$[A] \cdot [B] = \begin{bmatrix}12& -3\\ -4& 5\\ 4& 1\end{bmatrix}$$ $$[A]-2[C] = \begin{bmatrix}3& 0\\ -1& 2\\ 1& 1\end{bmatrix} - \begin{bmatrix}10& 4\\ 6& 10\\ 12& 14\end{bmatrix} = \begin{bmatrix}-7& -4\\ -7& -8\\ -11& -13\end{bmatrix}$$
2. Food orders are taken from two engineering departments for a takeout. The order is tabulated in Table 1.
However they have a choice of buying this food from three different restaurants. Their prices for the three food items are tabulated in Table 2.
Show how much each department will pay for their order at each restaurant. Which restaurant would be more economical to order from for each department?
Solution:
Denote the food order and price matrices as $$[A]=\begin{bmatrix}25& 35& 25\\ 21& 20& 21\end{bmatrix},\ [B]=\begin{bmatrix}2.42 & 2.38 & 2.46\\ 0.93 & 0.90 & 0.89\\ 0.95 & 1.03 & 1.13 \end{bmatrix}$$ The total fees matrix $[C]$ is the product of $[A]$ and $[B]$: $$[C]=[A]\cdot [B] = \begin{bmatrix}116.8 & 116.75 & 120.9\\ 89.37 & 89.61 & 93.19\end{bmatrix}$$ Covert it using tabular is shown in Table 3.
Thus, Burcholestrol is the cheapest for the Mechanocal department, which is 116.75. And MacFat is the cheapest for the Civil department, which is 89.37.
3. Given $$[A] = \begin{bmatrix}2& 3& 5\\ 6& 7& 9\\ 2& 1& 3\end{bmatrix},\ [B]= \begin{bmatrix}3& 5\\ 2& 9\\ 1& 6\end{bmatrix} ,\ [C]= \begin{bmatrix}5& 2\\ 3& 9\\ 7& 6\end{bmatrix}.$$ Illustrate the distributive law of binary matrix operations: $$[A]\cdot([B]+[C]) = [A]\cdot[B] + [A]\cdot[C]$$
Solution:
$$[B]+[C] = \begin{bmatrix}8& 7\\ 5& 18\\ 8& 12\end{bmatrix},\ [A]\cdot([B]+[C]) = \begin{bmatrix}71& 128\\ 155& 276\\ 45& 68\end{bmatrix}$$ $$[A]\cdot [B]=\begin{bmatrix}17& 67\\ 41& 147\\ 11& 37\end{bmatrix},\ [A]\cdot [C] = \begin{bmatrix}54& 61\\ 114& 129\\ 34& 31\end{bmatrix}\, [A]\cdot [B]+[A]\cdot [C]= \begin{bmatrix}71& 128\\ 155& 276\\ 45& 68\end{bmatrix}$$ Thus $$[A]\cdot([B]+[C]) = [A]\cdot[B] + [A]\cdot[C]$$
4. Let $[I]$ be a $n\times n$ identity matrix. Show that $[A]\cdot[I] = [I]\cdot[A]=[A]$ for every $n\times n$ matrix $[A]$.
Solution:
Let $[C]_{n\times n}=[A]_{n\times n}\cdot[I]_{n\times n}$. So we have $$c_{ij}=a_{i1}i_{1j} + \cdots + a_{i, j-1}i_{j-1, j} + a_{ij}i_{jj} + a_{i, j+1}i_{j+1, j}+\cdots + a_{in}i_{nj} = \sum_{p=1}^{n} a_{ip}i_{pj}$$ for each of $i=1, \cdots, n$ and $j=1, \cdots, n$. Since $$i_{ij}=\begin{cases}0 & i\neq j \\ 1 & i=j\end{cases}$$ Thus $$c_{ij} = \sum_{p=1}^{n} a_{ip}i_{pj} = a_{ij}i_{jj} = a_{ij}$$ That is, $[A]\cdot[I] = [A]$.
Similarly, denote $[D]_{n\times n}=[I]_{n\times n}\cdot [A]_{n\times n}$, and $$d_{ij}=i_{i1}a_{1j} + \cdots + i_{i, i-1}a_{i-1, j} + i_{ii}a_{ij} + i_{i, i+1}a_{i+1, j}+\cdots + i_{in}a_{nj} = \sum_{p=1}^{n} i_{ip}a_{pj}$$ Because $i_{ij}=1$ when $i=j$, otherwise $i_{ij}=0$. Thus, $$d_{ij}= \sum_{p=1}^{n} i_{ip}a_{pj} = a_{ij}$$ That is, $[I]\cdot[A]=[A]$.
5. Consider there are only two computer companies in a country. The companies are named Dude and Imac. Each year, company Dude keeps ${1/5}^{th}$ of its customers, while the rest switch to Imac. Each year, Imac keeps ${1/3}^{rd}$ of its customers, while the rest switch to Dude. If in 2002, Dude has ${1/6}^{th}$ of the market and Imac has ${5/6}^{th}$ of the market.
(A) What is the distribution of the customers between the two companies in 2003? Write the answer first as multiplication of two matrices.
(B) What would be distribution when the market becomes stable?
Solution:
(A) Denote $D_n$ and $M_n$ as the market share of Dude and Imac in the $n$-th year, respectively. $$\begin{bmatrix}D_n \\ M_n \end{bmatrix} = \begin{bmatrix}{1\over5} & {2\over3} \\ {4\over5} & {1\over3}\end{bmatrix}\cdot \begin{bmatrix}D_{n-1} \\ M_{n-1} \end{bmatrix}$$ Thus $$\begin{bmatrix}D_{2003} \\ M_{2003} \end{bmatrix} = \begin{bmatrix}{1\over5} & {2\over3} \\ {4\over5} & {1\over3}\end{bmatrix}\cdot \begin{bmatrix}D_{2002} \\ M_{2002} \end{bmatrix} = \begin{bmatrix}{1\over5} & {2\over3} \\ {4\over5} & {1\over3}\end{bmatrix}\cdot \begin{bmatrix}{1\over6} \\ {5\over6} \end{bmatrix}= \begin{bmatrix}{53\over90} \\ {37\over90} \end{bmatrix}$$
(B) The stable system means the market share will not be changed from year to year, that is, $$\begin{cases}D = {1\over5}D+{2\over3}M \\ M = {4\over5}D + {1\over3}M\end{cases}\Rightarrow {4\over5}D-{2\over3}M=0$$ On the other hand, $D + M =1$, thus we have $$\begin{cases}{4\over5}D-{2\over3}M=0\\ D + M =1\end{cases}\Rightarrow\begin{cases}D={5\over11}\\ M={6\over11}\end{cases}$$ Hence the stable market share of Dude and Imac is ${5\over11}$ and ${6\over11}$, respectively.
6. Given $$[A]=\begin{bmatrix}12.3& -12.3& 10.3\\ 11.3& -10.3& -11.3\\ 10.3& -11.3& -12.3\end{bmatrix},\ [B]=\begin{bmatrix}2& 4\\ -5& 6\\ 11& -20\end{bmatrix}$$ if $[C] = [A]\cdot[B]$, then what is $c_{31}$?
Solution:
$$c_{31} = \begin{bmatrix}10.3& -11.3& -12.3\end{bmatrix} \cdot \begin{bmatrix}2\\-5\\11\end{bmatrix} = 10.3\times2+11.3\times5-12.3\times11 = -58.2$$
7. $[A]$ and $[B]$ are square matrices of $n\times n$ order. Then $([A] - [B])([A] - [B])$ is equal to ( ).
Solution:
$$([A]-[B])([A]-[B]) = [A]([A]-[B])-[B]([A]-[B])=[A]^2-[A][B]-[B][A]+[B]^2$$ Note that $[A][B]$ and $[B][A]$ is not equal to each other unless $[A][B]=[B][A]$.
8. Given $[A]$ is a rectangular matrix and $c[A]=0$, then what are the values of $c$ and $[A]$?
Solution:
$c[A]=0\Rightarrow c=0$ or $[A]=[0]$.
9. You sell Jupiter and Fickers Candy bars. The sales in January are 25 and 30 of Jupiter and Fickers, respectively. In February, the sales are 75 and 35 of Jupiter and Fickers, respectively. If a Jupiter bar costs \$2 and a Fickers bar costs \$7, then what is the total sales amount in each month?
Solution:
$$\begin{bmatrix}25& 30\\ 75& 35\end{bmatrix}\cdot\begin{bmatrix} 2 \\ 7 \end{bmatrix} =\begin{bmatrix} 260 \\ 395 \end{bmatrix} $$ Thus, the total sales amount in January and February are \$260 and \$395, respectively.
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