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Here are two graphs that could represent a variety of different situations.
Andre claims that the line in the graph on the left has a greater slope because it is steeper. Do you agree with Andre? Explain your reasoning.
The goal of this discussion is to emphasize the importance of paying attention to scale when making sense of graphs. Display the two images from the activity for all to see. Identify 1–2 students to share their reasoning. Here are some questions for discussion:
Arrange students in groups of 2. Provide access to straightedges.
Ask students, “What are some different ways the communities you are a part of raise money for a cause?” (Walk-a-thon, put on an event and sell tickets, car wash, hold a raffle, sell coupon books). After a brief quiet think time, invite students to share their experiences.
Explain that an Origami Club wants to take a trip to see an origami exhibit at an art museum. Then read, or have a student read the Description in the Student Task Statement out loud. Explain that the same information is also shown in the table. Give students 3–4 minutes of quiet work time followed by a whole-class discussion.
Here are two ways to represent a situation.
Description:
The Origami Club is doing a car wash fundraiser to raise money for a trip. They charge the same price for every car. After 11 cars, they raised a total of \$93.50. After 23 cars, they raised a total of \$195.50.
| number of cars |
amount raised in dollars |
|---|---|
| 11 | 93.50 |
| 23 | 195.50 |
Create a graph that represents this situation.
The purpose of this discussion is to introduce students to the term “rate of change.” Begin by inviting 2–3 students to share the graphs they created. Emphasize how different scales can be used, but in order to be helpful, the scale for the number of cars, , on the horizontal axis should extend to at least 23 and the scale for the amount raised in dollars, , on the vertical axis should extend to at least 200.
Next, tell students that an equation that represents this situation is , where is the number of cars, and is the total dollars raised. Display this equation for all to see, then discuss:
“What is the constant of proportionality and what does it mean?” (The constant of proportionality is 8.5 and it means that each car washed raised $8.50.)
“How can you see the constant of proportionality in the graph and the table? (Graph: The slope of the line is equivalent to 8.5. Table: For any given row, the amount raised in dollars divided by the number of cars washed equals 8.5.)
“Which representation do you think is more useful when calculating the constant of proportionality? Why?”
Explain that the constant of proportionality can be thought of as the rate of change: the amount one variable changes by when the other variable increases by 1. In the case of the Origami Club’s car wash, the rate of change of , the amount they raise in dollars, with respect to , the number of cars they wash, is 8.50 dollars per car.
The goal of this discussion is for students to consider the importance of choosing a scale when creating graphs. Display this image or a similar blank coordinate plane and tell students that the proportional relationship includes the point on its graph.
Ask what an appropriate scale might be to show this point on a pair of axes with a 10 by 10 grid. (Each horizontal grid line could represent 2 units and each vertical grid line could represent 10 or 20 units.)
Next ask students, “What are some important ideas to remember when analyzing or creating a graph in the future?” Consider creating a classroom display with their responses. Important ideas to highlight include:
When studying a graph, pay attention to the label on each axis. For example, the placement of the variables may mean a graph is showing the pace of a bug instead of the speed of a bug.
When studying a graph, pay attention to the scale. For example, one graph may appear steeper than another graph, but it is the actual value of the slopes that matters.
When creating a graph, consider the question being asked and the information given when determining the scale. For example, make sure that the scale chosen extends far enough to show the necessary data.
The scales we choose when graphing a relationship often depend on what information we want to know. For example, consider two water tanks filled at different constant rates.
The relationship between time in minutes and volume in liters of Tank A can be described by the equation .
For Tank B the relationship can be described by the equation
These equations tell us that Tank A is being filled at a constant rate of 2.2 liters per minute and Tank B is being filled at a constant rate of 2.75 liters per minute.
If we want to use graphs to see at what times the two tanks will have 110 liters of water, then using an axis scale from 0 to 10, as shown here, isn't very helpful.
graph, horizontal axis, time in minutes, scale 0 to 9, by 1's. vertical axis, volume in liters, 0 to 9, by 1's. lines, first line passing through origin and 2 comma 5 and 5 tenths. second line passing through origin and 2 comma 4 and 5 tenths.
graph, horizontal axis, time in minutes, scale 0 to 90, by 10's. vertical axis, volume in liters, 0 to 140, by 10's. 2 lines, first line passing through origin and 40 comma 110. second line passing through origin and 50 comma 110.
If we use a vertical scale that goes to 150 liters, a bit beyond the 110 we are looking for, and a horizontal scale that goes to 100 minutes, we get a much more useful set of axes for answering our question.
Now we can see that the two tanks will reach 110 liters 10 minutes apart—Tank B after 40 minutes of filling and Tank A after 50 minutes of filling.
It is important to note that both of these graphs are correct, but one uses a range of values that helps answer the question. In order to always pick a helpful scale, we should consider the situation and the questions asked about it.
What representation we choose for a proportional relationship also depends on our purpose. For example, if Tank C fills at a constant rate of 2.5 liters per minute and we want to see the change in volume every 30 minutes, we could use a table:
| minutes (t) | liters (v) |
|---|---|
| 0 | 0 |
| 30 | 75 |
| 60 | 150 |
| 90 | 225 |
No matter the representation or the scale used, the constant of proportionality is evident in each. In the equation, it is the number we multiply by. In the graph it is the slope, and in the table it is the number by which we multiply values in the left column to get values in the right column. We can think of the constant of proportionality as a rate of change: the amount one variable changes by when the other variable increases by 1. For Tank A, the rate of change of with respect to is 2.2 liters per minute.
Your teacher will give you a set of cards. Each card contains a graph of a proportional relationship.
Two large water tanks are filling with water. Tank A is not filled at a constant rate, and the relationship between its volume of water and time is graphed on each set of axes. Tank B is filled at a constant rate of liters per minute. The relationship between its volume of water and time can be described by the equation , where is the time in minutes, and is the total volume in liters of water in the tank.
graph, horizontal axis, time in minutes, scale 0 to 1 and 8 tenths, by 2 tenth's. vertical axis, volume in liters, 0 to 1 and 8 tenths, by 2 tenth's. curved line passing through origin, 1 comma 1 and 1 and 4 tenths comma 1 and 3 tenths.
graph, horizontal axis, time in minutes, scale 0 to 80, by 20's. vertical axis, volume in liters, 0 to 50, by 10's. curved line passing through origin, 20 comma 12 and 60 comma 30.</p>
Answer the following questions and say which graph you used to find your answer.
If students are unsure how to scale the axes on their graphs, consider asking:
“What are the largest values that need to be shown on the graph?”
“How many grid lines are there?”