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lecture_6

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lecture_6 [2016/02/09 10:51] rupertlecture_6 [2017/02/07 10:14] (current) rupert
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- ==== Examples ====+==== Examples ====
  
 === Example 1 === === Example 1 ===
 +
 +A function $f(x)$ has the form \[ f(x)=ax^2+bx+c\] where $a,b,c$ are
 +constants. Given that $f(1)=3$, $f(2)=2$ and $f(3)=4$, find $f(x)$.
 +
 +== Solution ==
 +
 +\begin{gather*} f(1)=3\implies a\cdot 1^2+b\cdot 1 +c = 3\implies a+b+c=3\\
 +f(2)=2\implies a\cdot 2^2+b\cdot 2 +c = 3\implies 4a+2b+c=2\\
 +f(3)=4\implies a\cdot 3^2+b\cdot 3 +c = 3\implies 9a+3b+c=4
 +\end{gather*}
 +
 +
 +We get a system of three linear equations in the variables $a,b,c$:
 +\begin{gather*} 
 + a+b+c=3\\
 +4a+2b+c=2\\
 +9a+3b+c=4
 +\end{gather*}
 +
 +Let's reduce the augmented matrix for this system to RREF.
 +
 +\begin{align*} 
 +\def\go#1#2#3{\begin{bmatrix}#1\\#2\\#3\end{bmatrix}}
 +\def\ar#1{\\[6pt]\xrightarrow{#1}&}
 +&\go{1&1&1&3}{4&2&1&2}{9&3&1&4}
 +\ar{R2\to R2-4R1\text{ and }R3\to R3-9R1}
 +\go{1&1&1&3}{0&-2&-3&-10}{0&-6&-8&-23}
 +\ar{R2\to -\tfrac12 R2}
 +\go{1&1&1&3}{0&1&\tfrac32&5}{0&-6&-8&-23}
 +\ar{R3\to R3+6R2}
 +\go{1&1&1&3}{0&1&\tfrac32&5}{0&0&1&7}
 +\ar{R1\to R1-R3\text{ and }R2\to R2-\tfrac32R3}
 +\go{1&1&0&-4}{0&1&0&-5.5}{0&0&1&7}
 +\ar{R1\to R1-R2}
 +\go{1&0&0&1.5}{0&1&0&-5.5}{0&0&1&7}
 +\end{align*}
 +So $a=1.5$, $b=-5.5$ and $c=7$; so 
 +\[ f(x)=1.5x^2-5.5x+7.\]
 +
 +
 +=== Example 2 ===
  
 Solve the linear system Solve the linear system
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-=== Example ===+=== Example ===
  
 Solve the linear system Solve the linear system
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 \go{1&0&1&1&2}{3&1&-2&4&5}{4&2&-6&6&0} \go{1&0&1&1&2}{3&1&-2&4&5}{4&2&-6&6&0}
 \ar{R2\to R2-3R1\text{ and }R3\to R3-4R1} \ar{R2\to R2-3R1\text{ and }R3\to R3-4R1}
-\go{1&0&1&1&2}{&0&1&-5&1&-1}{0&2&-10&2&-8}+\go{1&0&1&1&2}{0&1&-5&1&-1}{0&2&-10&2&-8}
 \ar{R3\to R3-2R2} \ar{R3\to R3-2R2}
 \go{1&0&1&1&2}{0&1&-5&1&-1}{0&0&0&0&-6} \go{1&0&1&1&2}{0&1&-5&1&-1}{0&0&0&0&-6}
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 {{page>inconsistent}} {{page>inconsistent}}
  
-=== Example ===+=== Example ===
  
 For which value(s) of $k$ does the following linear system have For which value(s) of $k$ does the following linear system have
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 $k=4$. $k=4$.
  
 +/*
 ==== One more example ==== ==== One more example ====
  
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 Now $z$ is a free variable, say $z=t$ where $t\in \mathbb{R}$, and from row 2 we get $y=2-1.5t$ and row 1 gives $x=0.5t$, so the solution is Now $z$ is a free variable, say $z=t$ where $t\in \mathbb{R}$, and from row 2 we get $y=2-1.5t$ and row 1 gives $x=0.5t$, so the solution is
 \[ \begin{bmatrix}x\\y\\z\end{bmatrix}=\begin{bmatrix}0\\2\\0\end{bmatrix}+t\begin{bmatrix}0.5\\-1.5\\1\end{bmatrix},\quad t\in\mathbb{R}.\] \[ \begin{bmatrix}x\\y\\z\end{bmatrix}=\begin{bmatrix}0\\2\\0\end{bmatrix}+t\begin{bmatrix}0.5\\-1.5\\1\end{bmatrix},\quad t\in\mathbb{R}.\]
 +*/
  
 ===== Observations about Gaussian elimination ===== ===== Observations about Gaussian elimination =====
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 {{page>gaussian elimination remarks}} {{page>gaussian elimination remarks}}
  
 +====== Chapter 2: The algebra of matrices ======
 +
 +=== Definition ===
 +
 +{{page>matrix}}
 +
 +{{page>(i,j) entry}}
 +
 +=== Example ===
  
 +If $B=\begin{bmatrix} 99&3&5\\7&-20&14\end{bmatrix}$, then $B$ is a $2\times 3$ matrix, and the $(1,1)$ entry of $B$ is $b_{11}=99$, the $(1,3)$ entry of $B$ is $b_{13}=5$, the $(2,1)$ entry is $b_{21}=7$, etc.
  
  
lecture_6.1455015109.txt.gz · Last modified: by rupert
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