6.05 Solving systems of equations with a variety of methods

There are essentially three different methods to solve systems of equations. They are listed and described briefly below.

Graphical Method

It is easy to use a graphing calculator or utility when the equations within a system have y isolated. In this case, the calculator can be used to graph the equations. The intersection of the two lines will represent the solution to the system of equations.

Worked examples

Question 1 

Solve the following system of equations:

$y=5x$y=5x

$y=x+2$y=x+2

Solve:

Here I have drawn the $y=5x$y=5x line as red and the $y=x+2$y=x+2 line as green:

We can then see that there is only one intersection point and it is $(0.5,2.5)$(0.5,2.5). Therefore the solution that solves the two equations must be when $x=0.5$x=0.5 and $y=2.5$y=2.5.

Substitution Method

There are two different types of systems of equations where substitution is the easiest method. 

Type 1: One variable is isolated in one of the equations. The system is solved by substituting the equation with the isolated term into the other equation.

Worked examples

question 2

Solve following system of equations:

$3y+4=x$3y+4=x

$2+x-y=0$2+x−y=0

Solve:

$2+3y+4-y$2+3y+4−y	$=$=	$0$0
$2+4+3y-y$2+4+3y−y	$=$=	$0$0
$6+2y$6+2y	$=$=	$0$0
$2y$2y	$=$=	$-6$−6
$y$y	$=$=	$-3$−3

Now that we know the value of $y$y we can easily solve for $x$x by using the first equation: $3y+4=x$3y+4=x. Therefore $3\times\left(-3\right)+4=x$3×(−3)+4=x which equals $-5$−5. So our answer is $(-5,-3)$(−5,−3).

Type 2: One variable can be easily isolated. Solve for one variable in one of the equations, then substituting that equation into the second equation. Solve for a in the second equation, then substitute the second equation into the first.

Worked example

question 3

Solve the following system of equations:

$2p-3q=5$2p−3q=5

$p-2q=8$p−2q=8

Solve:

Isolate $p$p in equation 2 - $p=2q+8$p=2q+8

Substitute the value of p into equation 1.

$2\left(2q+8\right)-3q$2(2q+8)−3q	$=$=	$5$5
$4q+16-3q$4q+16−3q	$=$=	$5$5
$q+16$q+16	$=$=	$5$5
$q$q	$=$=	$-11$−11

Now that we know the value of $q$q we can easily solve for $p$p by using the second equation (modified version): $p=2q+8$p=2q+8 . Therefore$p=2\times\left(-11\right)+8$p=2×(−11)+8 which equals $-14$−14. The answer is $(-14,-11)$(−14,−11).

Elimination Method

When both equations within a system are given in standard form: Ax + By = C. The system of equations are usually solved by eliminating a variable and solving for the remaining variable. 

Worked example

Question 4

Solve the following system of equations:

 $2x-y=1$2x−y=1 

$5x+y=2$5x+y=2

Solve:

$2x-y+5x+y$2x−y+5x+y	$=$=	$1+2$1+2
$2x+5x-y+y$2x+5x−y+y	$=$=	$3$3
$7x$7x	$=$=	$3$3
$x$x	$=$=	$\frac{3}{7}$37​

Now, find the y value by substituting the above x value into the either equations. 

 

$5\times\frac{3}{7}+y$5×37​+y	$=$=	$2$2
$\frac{15}{7}+y$157​+y	$=$=	$2$2
$y$y	$=$=	$\frac{14}{7}-\frac{15}{7}$147​−157​
$y$y	$=$=	$\frac{-1}{7}$−17​

Solution: $\text{(-3/7, -1/7)}$(-3/7, -1/7)

We can see that we should use addition when the coefficients of the variable we want to eliminate are equal and opposite in sign, and subtraction when they're equal and the same sign. But what happens when they don't have the same coefficients at all?

question 5

Solve the following system of equations:

$x+3y=5$x+3y=5

$2y+2x=1$2y+2x=1

Solve:

Multiplying the first equation by $-2$−2:

$-2\left(x+3y\right)$−2(x+3y)	$=$=	$-2\times5$−2×5
$-2x-6y$−2x−6y	$=$=	$-10$−10

Add the modified Equation 1 and Equation 2: 

$-2x-6y+2y+2x$−2x−6y+2y+2x	$=$=	$-10+1$−10+1
$-2x-6y+2y+2x$−2x−6y+2y+2x	$=$=	$-9$−9
$-4y$−4y	$=$=	$-9$−9
$y$y	$=$=	$\frac{9}{4}$94​

Now that we have our value for $y$y it's a simple case of substituting it back in any of the equations to get our value for $x$x:

$x+3y$x+3y	$=$=	$5$5
$x+\frac{3\times9}{4}$x+3×94​	$=$=	$5$5
$x+\frac{27}{4}$x+274​	$=$=	$5$5
$x$x	$=$=	$5-\frac{27}{4}$5−274​
$x$x	$=$=	$\frac{-7}{4}$−74​

Solution: $\text{(-7/4, 9/4)}$(-7/4, 9/4)

Practice questions

question 6