Unit 5, Lesson 6
Features of Graphs
Algebra 1
6.1
Warm-up
Instructional Routines
NoneMaterials
NoneActivity Narrative
This Warm-up is an opportunity to practice interpreting statements in function notation. It also draws attention to statements that correspond to the intercepts of a graph of a function (for instance, and ), preparing students to reason about them in the lesson (particularly in the second activity).
Launch
NoneActivity
NoneDiego is walking home from school at a constant rate. This graph represents function , which gives his distance from home, in kilometers, minutes since leaving the school.
Use the graph to find or estimate:
- the solution to
- the solution to
Activity Synthesis
Ask students to interpret each statement in function notation before soliciting their response to each question. Make sure students understand, for instance, that represents Diego’s distance from school at the time of leaving (or at 0 minutes) and represents his distance from home being 0 km, minutes after leaving school.
If time permits, discuss with students:
- “Is the relationship between time and Diego’s distance from school a linear function? How can we tell?” (Yes. The graph is a line, which means the function’s value changes at a constant rate.)
- “Can we tell from the graph how far away Diego’s house is from school? How?” (Yes. From the graph, we can see that at the time he leaves school, he is 2.25 km from home.)
- “Can we tell from the graph how long it took Diego to get home? How?” (Yes. From the graph, we can see the distance reaching 0 km when the time is 20 minutes.)
- “Why does the graph slant downward (or have a negative slope)?” (As the input, , increases, the output, , decreases.)
Lesson Synthesis
Keep students in groups of 2. Display the graph and two possible descriptions of functions that could be represented by the graph for all students to see:
- Function gives the vertical distance (or the height) of a bee from the ground as a function of time, .
- Function gives the distance of a child from where his mom is sitting as a function of time, .
Tell students that the outputs of both functions are measured in feet and the inputs are both measured in seconds.
Ask partners to choose a function. For that function, they should take turns identifying the following features on the graph and interpreting them in terms of the situations:
- vertical intercept
- horizontal intercept
- maximum
- minimum
- intervals in which the function is increasing
- intervals in which the function is decreasing
- intervals in which the function is staying constant
- solution or solutions to or
Then, discuss questions such as:
- “How can you tell that a point on the graph is a maximum, a minimum, or neither?” (Look to the left and to the right of it to see whether the given point is higher than all the other points, lower than all the others, or neither.)
- “How many intercepts can the graph of a function have?” (There is an unlimited number on the horizontal axis, but only one on the vertical axis.)
Student Lesson Summary
The graph of the function can give us useful information about the quantities in a situation. Some points and features of a graph are particularly informative, so we pay closer attention to them.
Let’s look at the graph of function , which gives the height, in meters, of a ball seconds after it is tossed up in the air. From the graph, we can see that:
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The point is the vertical intercept of the graph, or the point where the graph intersects the vertical axis.
This point tells us that the initial height of the ball is 20 meters, because when is 0, the value of is 20.
The statement captures this information.
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The point is the highest point on the graph, so it is a maximum of the graph.
The value 25 is also the maximum value of the function . It tells us that the highest point the ball reaches is 25 meters, and that this happens 1 second after the ball is tossed.
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The point is a horizontal intercept of the graph, a point where the graph intersects the horizontal axis. This point is also the lowest point on the graph, so it represents a minimum of the graph.
This point tells us that the ball hits the ground 3.2 seconds after being tossed up, so the height of the ball is 0 when is 3.2, which we can write as . Because cannot have any lower value, 0 is also the minimum value of the function.
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The height of the graph increases when is between 0 and 1. (A graph is increasing where the function’s values get greater as the graph is read left to right.) Then, the graph changes direction, and the height decreases when is between 1 and 3.2. (A graph is decreasing where the function’s values get lesser as the graph is read left to right.) Neither the increasing part nor the decreasing part is a straight line.
This suggests that the ball increases in height in the first second after being tossed and then starts falling between 1 second and 3.2 seconds. It also tells us that the height does not increase or decrease at a constant rate.
Because the intercepts of a graph are points on an axis, at least one of their coordinates is 0. The 0 corresponds to the input or the output of a function, or both.
- A vertical intercept is on the vertical axis, so its coordinates have the form , where the first coordinate is 0 and can be any number. The 0 is the input.
- A horizontal intercept is on the horizontal axis, so its coordinates have the form , where can be any number and the second coordinate is 0. The 0 is an output.
- A graph that passes through intersects both axes so that point is both a horizontal intercept and a vertical intercept. Both the input and output are 0.