Unit 2, Lesson 16
Solving Systems by Elimination (Part 3)
Algebra 1
16.1
Warm-up
Standards Alignment
Building On
HSA-REI.A.1
Explain each step in solving a simple equation as following from the equality of numbers asserted at the previous step, starting from the assumption that the original equation has a solution. Construct a viable argument to justify a solution method.
Addressing
HSA-REI.C.5
Prove that, given a system of two equations in two variables, replacing one equation by the sum of that equation and a multiple of the other produces a system with the same solutions.
Building Toward
Instructional Routines
Graph ItMaterials
To Gather
Graphing technologyActivity Narrative
In this Warm-up, experiment with the graphical effects of multiplying by a factor both sides of an equation in two variables.
Students are prompted to multiply one equation in a system by several factors to generate several equivalent equations. They then graph these equations on the same coordinate plane that shows the graphs of the original system. Students notice that no new graphs appear on the coordinate plane and reason about why this might be the case.
The work here reminds students that equations that are equivalent have all the same solutions, so their graphs are also identical. Later, students will rely on this insight to explain why we can multiply one equation in a system by a factor—which produces an equivalent equation—and solve a new system containing that equation instead.
Launch
Display the equation for all to see. Ask students:
- "What is the solution to this equation?" ()
- "If we multiply both sides of the equation by a factor, say, 4, what equation would we have?" () "What is the solution to this equation?" ()
- "What if we multiply both sides by 100?" () "By 0.5?" ()
- "Is the solution to each of these equations still ?" (Yes)
Remind students that these equations are one-variable equations, and that multiplying both sides of a one-variable equation by the same factor produces an equivalent equation with the same solution.
Ask students: "What if we multiply both sides of a two-variable equation by the same factor? Would the resulting equation have the same solutions as the original equation?" Tell students that they will now investigate this question by graphing.
Arrange students in groups of 2–4, and provide access to graphing technology to each group. To save time, consider asking group members to divide up the tasks. (For example, one person could be in charge of graphing while the others write equivalent equations, and all analyze the graphs together.)
Activity Synthesis
Invite students to share their observations about the graphs they created. Ask students why the graphs of Equations A1, A2, and A3 all coincide with the graphs of the original Equation A. Discuss with students:
- "How can we explain the identical graphs?" (Equations A1, A2, and A3 are equivalent to Equation A, so they all have the same solutions as Equation A, and their graphs are the same line as the graph of Equation A.)
- "What move was made to generate Equations A1, A2, and A3? Why did it create equations that are equivalent to Equation A?" (The two sides of Equation A were multiplied by the same factor, which keeps the two sides equal.)
To further illustrate that Equations A1, A2, and A3 are equivalent to Equation A, and if time permits, consider:
- Using tables to visualize the identical pairs. For example:
x y 0 1 1 -3 2 -7 3 -11 x y 0 1 1 -3 2 -7 3 -11 x y 0 1 1 -3 2 -7 3 -11 - Remind students that, earlier in the unit, they saw that isolating one variable is a way to see if two equations are equivalent. If we isolate in Equations A, A1, A2, and A3, the rearranged equations will be identical: .
16.2
Activity
Instructional Routines
NoneMaterials
To Gather
Graphing technologyActivity Narrative
In an earlier lesson, students learned that adding the two equations in a system creates a new equation that shares a solution with the system. In the Warm-up, they saw that multiplying an equation by a factor creates an equivalent equation that shares all the same solutions as the original equation.
Here students learn that each time we perform a move that creates one or more new equations, we are in fact creating a new system that is equivalent to the original system. Equivalent systems are systems with the same solution set, and we can write a series of them to help us get closer to finding the solution of an original system.
For instance, if and form a system, and is a multiple of the second equation, then the equations and form an equivalent system that can help us eliminate and make progress toward finding the value of .
Students also learn to make an argument that explains why each new system is indeed equivalent to the one that came before it (MP3), building on the work of justifying equivalent equations in earlier lessons.
16.3
Activity
Materials
To Copy (from Blackline Masters)
What Comes Next Cards
Activity Narrative
Earlier, students encountered the idea of equivalent systems. They described the moves that lead to equivalent equations and explained why the solution to those equations was the same as the solution to the original system. This activity reinforces that work.
Given an unordered set of equivalent systems, students work with a partner to arrange the systems such that the order constitutes logical steps toward solving an original system. Along the way, they take turns describing how each system came from the previous one and explaining how they know it has the same solution as its predecessor. The work allows students to practice constructing logical arguments and critiquing those of others (MP3).
Launch
Arrange students in groups of 2. Give one set of pre-cut slips or cards from the blackline master to each group. Ask students to find the slip or card that shows a system of equations and is labeled “Start here.”
Explain that all the other slips contain equivalent systems that represent steps in solving the starting system. Ask students to arrange the slips in an order that would lead to its solution, and to make sure that they can explain what moves take each system to the next system and why each system is equivalent to the one before it.
Partners should take turns finding the next step in the solving process and explaining their reasoning. As one student explains, the partner's job is to listen and make sure that they agree and that the explanation makes sense. If they disagree, the partners should discuss until they reach an agreement.
Give students 5 minutes to arrange the systems. Follow with a whole-class discussion.
MLR8 Discussion Supports. Students should take turns finding the next step and explaining their reasoning to their partner. Display the following sentence frames for all to see: “I noticed _____, so I matched . . . .” Encourage students to challenge each other when they disagree.
Advances: Speaking, Representing
Advances: Speaking, Representing
Action and Expression: Internalize Executive Functions. Chunk this task into more manageable parts to support students who benefit from support with organization and problem solving. For example, guide students in a strategy by prompting them to begin by identifying the first and last cards. Next, ask students to identify the card where the solution for first appears, and to explain how they know. Encourage students to use these three cards as benchmarks for sorting the remaining cards.
Supports accessibility for: Organization, Attention
Supports accessibility for: Organization, Attention
16.4
Activity
Optional
Instructional Routines
NoneMaterials
NoneActivity Narrative
This optional activity gives students another opportunity to identify moves that lead to equivalent systems and to explain why the resulting systems have the same solution (MP3). It also prompts students to build their own equivalent systems, which encourages them to think strategically about what to do to reach the goal of solving the system, rather than to rely on a particular solution path.
As students work, prompt students to articulate the reasoning and assumptions. Ask questions such as:
- "How do you know the factor to use when multiplying an equation so a variable can be eliminated?"
- "Can the factor be a fraction? A negative number? Why or why not?"
- "Why doesn't adding one equation to another equation change the solution of the system?"
Launch
Keep students in groups of 2, if desired.
Activity
NoneLesson Synthesis
Refer to the systems that students have ordered in the "What Comes Next?" activity. Invite students to explain what move takes one system to the next and how they know that the new system is equivalent to the one before it (even though one equation has been transformed).
As students share their responses, record the descriptions of moves and the justifications for all to see. Consider using a graphic organizer, as shown here. (Students could preserve a completed organizer and use it later as a reference.)
| step | system | What move was made? | Why is the new system equivalent to the previous one? |
|---|---|---|---|
| 0 | |||
| 1 | |||
| 2 | |||
| . . . |
If time is limited, focus on discussing the justifications (the last column in the graphic organizer) for why one system in the sequence is equivalent to the system before it.
Highlight statements such as: "Adding equal amounts to the two sides of an equation keeps the two sides equal, so the same - and -values that make the first equation true also make this new equation true. This means that the same pair of values is also a solution to the new system." If no students explained in this way, demonstrate it.
Student Lesson Summary
We now have two algebraic strategies for solving systems of equations: by substitution and by elimination. In some systems, the equations may give us a clue as to which strategy to use. For example:
In this system, is already isolated in one equation. We can solve the system by substituting for in the second equation and finding .
This system is set up nicely for elimination because of the opposite coefficients of the -variable. Adding the two equations eliminates so we can solve for .
In other systems, which strategy to use is less straightforward, either because no variables are isolated, or because no variables have equal or opposite coefficients. For example:
To solve this system by elimination, we first need to rewrite one or both equations so that one variable can be eliminated. To do that, we can multiply both sides of an equation by the same factor. Remember that doing this doesn't change the equality of the two sides of the equation, so the - and -values that make the first equation true also make the new equation true.
There are different ways to eliminate a variable with this approach. For instance, we could:
- Multiply Equation A by 3 to get . Adding this equation to Equation B eliminates .
-
Multiply Equation B by to get . Subtracting this equation from Equation A eliminates .
- Multiply Equation A by to get and multiply Equation B by to get . Subtracting one equation from the other eliminates .
Each multiple of an original equation is equivalent to the original equation. So each new pair of equations is equivalent to the original system and has the same solution.
Let’s solve the original system using the first equivalent system we found earlier.
- Adding the two equations eliminates , leaving a new equation , or .
- Putting together and the original gives us another equivalent system.
- Substituting 7 for in the second equation allows us to solve for .
When we solve a system by elimination, we are essentially writing a series of equivalent systems, or systems with the same solution. Each equivalent system gets us closer and closer to the solution of the original system.