Graphing Stories: Quadratic Functions

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Presentation transcript:

Graphing Stories: Quadratic Functions Algebra 1 Module 1, Lesson 2 Graphing Stories: Quadratic Functions

Student Outcome Students will be able to represent graphically a non-linear relationship between two quantities and interpret features of the graph. They will understand the relationship between physical quantities via the graph.

Describe the motion of the ball in words… Bullet Points Are Ok Let's get the ball rolling... (Example 1) Students work in pairs for 2-3 minutes to develop a description. Walk around the room offering support. 2. Direct the class to focus on the change of elevation of the ball over time and begin to put into words specific details linking elevation with time. ~ "It first started at the top of the ramp." ~ "It rolled down the ramp for about 2 seconds." ~ "After it hit the bottom of the ramp, it rolled across the floor.” etc…

Graph the Story Example 1 Your graph must include: Suggestions: Labels on the axes Units on the axes Title Suggestions: Think about start and finish coordinates (points) Use the bottom of the ball for elevation Use a straight edge to draw lines 1. Students work in pairs for 2-3 minutes to develop a graph. Walk around the room offering support. 2. Have a pair come to the board to copy their graph while asking them.. ~ “How should we label the vertical axis? What unit of measurement should we choose?” Why? ~ “How should we label the horizontal axis? What unit of measurement should we choose?” Why? ~ “The ball starts at the top of the ramp. Where would that be located on the graph?” Why? 3. Begin a discussion that leads students through issues of formalizing the diagram: The labels and units of the axes, a title for the graph, the meaning of a point plotted on the graph, the height at time 0 seconds, the time when it reached the bottom of the ramp, etc. *At this point, do not worry about engaging students in measuring specific heights and specific times; right now they are just looking for the general shape. Be sure to have students notice the horizontal “tail” of the graph and ask them to interpret its meaning. (The elevation of the ball does not change as it rolls across the floor.) Some students may draw a curved graph. Others will likely draw a straight line for the graph over the interval 0 to 1.7 seconds. Even though this is not correct, allow it at this stage. **After students have created graphs, have them compare their graphs with each other and share with the class. Ask the following questions: ~ Should the change in elevation be decreasing at a constant rate? That is, do you think this graph should be a straight line-graph, at least between 0 and about 1.7 seconds? Some specific questions (below) can help lead to the correct conclusion: ~ Where does the elevation change more slowly? Explain? ~ If it is changing more slowly at the top and more quickly at the bottom, should the graph look the same at those times?

Allow students to analyze the full video initially giving them as much control as possible (if not full control) in choosing when to pause a video, or play it half speed, and so on. Perhaps conduct this part of a class in a computer lab or display the video on an interactive Smart Board. Then direct students to investigate one of the two portions of the clip below, depending on the level of technology you have available: Portion 1: From time 32 seconds to time 33 seconds. Use this to get data for drawing the graph if they have access to a powerful movie editor that can show each frame. Portion 2: From time 48 seconds to time 53 seconds. Use this for a slow-motion version that can be analyzed easily via YouTube. *Students should start measuring from the top of the man’s jump, which is about 36 feet high. (He starts at 35.5 feet and jumps 12 a foot up before falling.)

What do values between the values given in the table represent? If time allows, revisit Example 2 and ask students to use symmetry to reflect across the y axis. Ask if the quadratic/curved nature of their drawing is appropriate. “Did he travel up to the platform at the same speed he fell?” What do values between the values given in the table represent?

Ticket Sketch a possible graph including labels and a title. If you were to jump in the air 3 times what might the elevation vs. time graph look like? Sketch a possible graph including labels and a title.