MST10030 notes wiki

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Example

Use EROs to find the intersection of the planes \begin{align*} 3x+4y+7z&=2\\x+3z&=0\\y-2z&=5\end{align*}

Solution 1

\begin{align*} \def\go#1#2#3{\begin{bmatrix}#1\\#2\\#3\end{bmatrix}} \def\ar#1{\\[6pt]\xrightarrow{#1}&} &\go{3&4&7&2}{1&0&3&0}{0&1&-2&5} \ar{\text{reorder rows}}\go{1&0&3&0}{0&1&-2&5}{3&4&7&2} \ar{R3\to R3-3R1}\go{1&0&3&0}{0&1&-2&5}{0&4&-2&2} \ar{R3\to R3-4R2}\go{1&0&3&0}{0&1&-2&5}{0&0&6&-18} \ar{R3\to \tfrac16 R3}\go{1&0&3&0}{0&1&-2&5}{0&0&1&-3} \end{align*}

So

from the last row, we get $z=-3$
from the second row, we get $y-2z=5$, so $y-2(-3)=5$, so $y=-1$
from the first row, we get $x+3z=0$, so $x+3(-3)=0$, so $x=9$

The conclusion is that \[ \begin{bmatrix}x\\y\\z\end{bmatrix}=\begin{bmatrix}9\\-1\\-3\end{bmatrix}\] is the only solution.

Solution 2

We start in the same way, but by performing more EROs we make the algebra at the end simpler.

\begin{align*} \def\go#1#2#3{\begin{bmatrix}#1\\#2\\#3\end{bmatrix}} \def\ar#1{\\[6pt]\xrightarrow{#1}&} &\go{3&4&7&2}{1&0&3&0}{0&1&-2&5} \ar{\text{reorder rows}}\go{1&0&3&0}{0&1&-2&5}{3&4&7&2} \ar{R3\to R3-3R1}\go{1&0&3&0}{0&1&-2&5}{0&4&-2&2} \ar{R3\to R3-4R2}\go{1&0&3&0}{0&1&-2&5}{0&0&6&-18} \ar{R3\to \tfrac16 R3}\go{1&0&3&0}{0&1&-2&5}{0&0&1&-3} \ar{R2\to R2+2R3}\go{1&0&3&0}{0&1&0&-1}{0&0&1&-3} \ar{R1\to R1-3R3}\go{1&0&0&9}{0&1&0&-1}{0&0&1&-3} \end{align*}

So

from the last row, we get $z=-3$
from the second row, we get $y=-1$
from the first row, we get $x=9$

The conclusion is again that \[ \begin{bmatrix}x\\y\\z\end{bmatrix}=\begin{bmatrix}9\\-1\\-3\end{bmatrix}\] is the only solution.

Discussion

In both of these solutions we used EROs to transform the augmented matrix into a nice form.

In solution 1, we ended up with the matrix $\left[\begin{smallmatrix}1&0&3&0\\0&1&-2&5\\0&0&1&-3\end{smallmatrix}\right]$ which has a staircase pattern, with zeros below the staircase, and 1s just above the “steps” of the staircase. This is an example of a matrix in row echelon form (see below). We needed a bit of easy algebra, called back substitution, to finish off the solution.
In solution 2, we ended up with the matrix $\left[\begin{smallmatrix}1&0&0&9\\0&1&0&-1\\0&0&1&-3\end{smallmatrix}\right]$ which has a staircase pattern with zeros below the staircase and 1s just above the “steps” of the staircase, and the additional property that we only have zeros above the 1s on the steps. This is an example of a matrix in reduced row echelon form (see below). Finding the solution from this matrix needed no extra algebra.