Solve a system of two linear equations in two variables.
Subsection3.6.1Activities
Observation3.6.1.
Often times when solving a real-world application, more than one equation is necessary to describe the information. We’ll investigate some of those in this section.
Activity3.6.2.
Admission into a carnival for \(4\) children and \(2\) adults is \(\$128.50\text{.}\) For \(6\) children and \(4\) adults, the admission is \(\$208\text{.}\) Assuming a different price for children and adults, what is the price of the child’s admission and the price of the adult admission?
(a)
Let \(c\) represent the cost of a child’s admission and \(a\) the cost of an adult admission. Write an equation to represent the total cost for 4 children and 2 adults.
\(\displaystyle 4a+2c=128.50\)
\(\displaystyle a+c=128.50\)
\(\displaystyle 4c+2a=128.50\)
\(\displaystyle a+c=336.50\)
Answer.
C: \(4c+2a=128.50\)
(b)
Now write an equation to represent the total cost for 6 children and 4 adults.
\(\displaystyle 6c+4a=208\)
\(\displaystyle a+c=208\)
\(\displaystyle 4a+6c=208\)
\(\displaystyle a+c=336.50\)
Answer.
A: \(6c+4a=208\)
(c)
Using the above equations, check by substitution which admission prices would satisfy both equations?
\(c=\$20\) and \(a=\$24.25\)
\(c=\$24.50\) and \(a=\$15.25\)
\(c=\$20\) and \(a=\$22\)
\(c=\$14.50\) and \(a=\$30.25\)
Answer.
B: \(c=\$24.50\) and \(a=\$15.25\)
Definition3.6.3.
A system of linear equations consists of two or more linear equations made up of two or more variables. A solution to a system of equations is a value for each of the variables that satisfies all the equations at the same time.
Which of the ordered pairs is a solution to the system?
\(\displaystyle (3,10)\)
\(\displaystyle (0,4)\)
\(\displaystyle (1,-1)\)
\(\displaystyle (-1,2)\)
Answer.
D: \((-1,2) \)
Remark3.6.5.
While we can test points to determine if they are solutions, it is not feasible to test every possible point to find a solution. We need a method to solve a system.
Rewrite the first equation in terms of \(y\text{.}\)
(b)
Rewrite the second equation in terms of \(y\text{.}\)
(c)
Graph the two equations on the same set of axes. Where do the lines intersect?
(d)
Check that the point of intersection of the two lines is a solution to the system of equations.
Remark3.6.7.
Sometimes it is difficult to determine the exact intersection point of two lines using a graph. Let’s explore another possible method for solving a system of equations.
While the substitution method will always work, sometimes the resulting equations will be difficult to solve. Let’s explore a third method for solving a system of two linear equations with two variables.
Notice that if you simply add the two equations together, it will not eliminate a variable. Substitution will also be difficult since it involves fractions.
(a)
What value can you multiply the first equation by so that when you add the result to the second equation one variable cancels?
\(-1\) and the \(x\) will cancel
\(2\) and the \(x\) will cancel
\(3\) and the \(y\) will cancel
\(-2\) and the \(y\) will cancel
Answer.
B: Multiply the second equation by \(2\) and the \(x\) will cancel
(b)
Perform the multiplication and add the two equations. What is the resulting equation?
\(\displaystyle -5y=8\)
\(\displaystyle -14y=14\)
\(\displaystyle -14y=8\)
\(\displaystyle -5x=4\)
Answer.
B: \(-14y=14\)
(c)
What is the solution to the system of equations?
\(\displaystyle (-1,-1.6)\)
\(\displaystyle (-1,-0.6)\)
\(\displaystyle (-0.6,-1)\)
\(\displaystyle (-1.6,-1)\)
Answer.
C: \((3,1)\)
Activity3.6.16.
For each system of equations, determine which method (graphical, substitution, or elimination) might be best for solving.