4.3.5: Solving More Systems

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Illustrative Mathematics
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Lesson

Let's solve systems of equations.

Exercise \(\PageIndex{1}\): Algebra Talk: Solving Systems Mentally

Solve these without writing anything down:

\[\left\{\begin{array}{l}{x=5}\\{y=x-7}\end{array}\right.\nonumber\]

\[\left\{\begin{array}{l}{y=4}\\{y=x+3}\end{array}\right.\nonumber\]

\[\left\{\begin{array}{l}{x=8}\\{y=-11}\end{array}\right.\nonumber\]

Exercise \(\PageIndex{2}\): Challenge Yourself

Here are a lot of systems of equations:

\(\left\{\begin{array}{l}{y=4}\\{x=-5y+6}\end{array}\right.\)
\(\left\{\begin{array}{l}{y=7}\\{x=3y-4}\end{array}\right.\)
\(\left\{\begin{array}{l}{y=\frac{3}{2}x+7}\\{x=-4}\end{array}\right.\)
\(\left\{\begin{array}{l}{y=-3x+10}\\{y=-2x+6}\end{array}\right.\)
\(\left\{\begin{array}{l}{y=-3x-5}\\{y=4x+30}\end{array}\right.\)
\(\left\{\begin{array}{l}{y=3x-2}\\{y=-2x+8}\end{array}\right.\)
\(\left\{\begin{array}{l}{y=3x}\\{x=-2y+56}\end{array}\right.\)
\(\left\{\begin{array}{l}{x=2y-15}\\{y=-2x}\end{array}\right.\)
\(\left\{\begin{array}{l}{3x+4y=10}\\{x=2y}\end{array}\right.\)
\(\left\{\begin{array}{l}{y=3x+2}\\{2x+y=47}\end{array}\right.\)
\(\left\{\begin{array}{l}{y=-2x+5}\\{2x+3y=31}\end{array}\right.\)
\(\left\{\begin{array}{l}{x+y=10}\\{x=2y+1}\end{array}\right.\)

Without solving, identify 3 systems that you think would be the least difficult to solve and 3 systems that you think would be the most difficult to solve. Be prepared to explain your reasoning.
Choose 4 systems to solve. At least one should be from your "least difficult" list and one should be from your "most difficult" list.

Exercise \(\PageIndex{3}\): Five Does Not Equal Seven

Tyler was looking at this system of equations:

\[\left\{\begin{array}{l}{x+y=5}\\{x+y=7}\end{array}\right.\nonumber\]

He said, "Just looking at the system, I can see it has no solution. If you add two numbers, that sum can’t be equal to two different numbers.”

Do you agree with Tyler?

Are you ready for more?

In rectangle \(ABCD\), side \(AB\) is 8 centimeters and side \(BC\) is 6 centimeters. \(F\) is a point on \(BC\) and \(E\) is a point on \(AB\). The area of triangle \(DFC\) is 20 square centimeters, and the area of triangle \(DEF\) is 16 square centimeters. What is the area of triangle \(AED\)?

Summary

When we have a system of linear equations where one of the equations is of the form \(y=\text{ [stuff]}\) or \(x=\text{ [stuff]}\), we can solve it algebraically by using a technique called substitution. The basic idea is to replace a variable with an expression it is equal to (so the expression is like a substitute for the variable). For example, let's start with the system:

\[\left\{\begin{array}{l}{y=5x}\\{2x-y=9}\end{array}\right.\nonumber\]

Since we know that \(y=5x\), we can substitute \(5x\) for \(y\) in the equation \(2x-y=9\),

\(2x-(5x)=9\),

and then solve the equation for \(x\),

\(x=-3\).

We can find \(y\) using either equation. Using the first one: \(y=5\cdot -3\). So

\((-3,15)\)

is the solution to this system. We can verify this by looking at the graphs of the equations in the system:

Figure \(\PageIndex{1}\): Graph of two lines, origin O, with grid. Horizontal axis, x, scale negative 10 to 10, by 2’s. Vertical axis, y, scale negative 30 to 30, by 10’s. One line is labeled as y equals 5 x. Another line is labeled as 2 x minus y equals 9. The lines intersect at negative 3 comma negative 15.

Sure enough! They intersect at \((-3,-15)\).

We didn't know it at the time, but we were actually using substitution in the last lesson as well. In that lesson, we looked at the system

\[\left\{\begin{array}{l}{y=2x+6}\\{y=-3x-4}\end{array}\right.\nonumber\]

and we substituted \(2x+6\) for \(y\) into the second equation to get \(2x+6=-3x-4\). Go back and check for yourself!

Glossary Entries

Definition: System of Equations

A system of equations is a set of two or more equations. Each equation contains two or more variables. We want to find values for the variables that make all the equations true.

These equations make up a system of equations:

\[\left\{\begin{array}{l}{x+y=-2}\\{x-y=12}\end{array}\right.\nonumber\]

The solution to this system is \(x=5\) and \(y=-7\) because when these values are substituted for \(x\) and \(y\), each equation is true: \(5+(-7)=-2\) and \(5-(-7)=12\).

Practice

Exercise \(\PageIndex{4}\)

Solve:

\[\left\{\begin{array}{l}{y=6x}\\{4x+y=7}\end{array}\right.\nonumber\]

Exercise \(\PageIndex{5}\)

Solve:

\[\left\{\begin{array}{l}{y=3x}\\{x=-2y+70}\end{array}\right.\nonumber\]

Exercise \(\PageIndex{6}\)

\(y=-1.5x+6\)
\(y=-1.5x\)
\(2y=-3x+6\)
\(2y+3x=6\)
\(y=-2x+3\)

Exercise \(\PageIndex{7}\)

The system \(x=6y=4\), \(3x-18y=4\) has no solution.

Change one constant or coefficient to make a new system with one solution.
Change one constant or coefficient to make a new system with an infinite number of solutions.

Exercise \(\PageIndex{8}\)

Match each graph to its equation.

Figure \(\PageIndex{2}\): Four graphs, each with a line in the x y plane. Graph A. The line crosses the y axis at 3 and passes through the point negative 1 comma 1. Graph B. The line crosses the y axis at negative 3 and passes through the point 1 comma negative 1. Graph C. The line crosses the y axis at 3 and passes through the point 1 comma 1. Graph D. The line crosses the y axis at negative 3 and passes through the point negative 1 comma negative 1.

\(y=2x+3\)
\(y=-2x+3\)
\(y=2x-3\)
\(y=-2x-3\)

(From Unit 3.3.3)

Exercise \(\PageIndex{9}\)

Here are two points: \((-3,4)\), \((1,7)\). What is the slope of the line between them?

\(\frac{4}{3}\)
\(\frac{3}{4}\)
\(\frac{1}{6}\)
\(\frac{2}{3}\)

(From Unit 3.3.2)

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