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Episode 1 Supports
Episode Description
Making Sense: Sasha and Keoni make sense of parameters that can change the vertex of a parabola on the coordinate grid. They also revisit what they already know about how the p-value changes the shape of the graph of the parabola.
Focus Questions
For use in a classroom, pause the video and ask these questions:
1. [Pause video at 3:54]. What is happening to the directrix as the value of k changes?
2. [Pause video at 3:54]. What are the coordinates of the focus of the parabola in red?
Supporting Dialogue
Focus students’ attention on precision of language by attending to Sasha’s justification:
- Sasha provides justification for why the directrix does not move when the vertex moves to (7,0) [6:18-6:24]. Can someone revoice her idea?
- Can someone revoice Sasha’s idea using mathematical vocabulary? What about someone else? Is there another way to revoice her idea?
- Sasha provides justification for why the directrix does not move when the vertex moves to (7,0) [6:18-6:24]. Can someone revoice her idea?
Math Extensions
1. Use the link to GeoGebra applet to explore how you can change the position of a parabola so that the p-value is still 3 and the vertex is at (–5, 0). What are the coordinates of the focus for this parabola? How do you know?
2. How can you adjust the p-value and the h-value to get a parabola with a vertex at (7,0) and a focus at (7, 2)? How do you know? Where is the p-value on the graph?
Mathematics in this Lesson
Lesson Description
Targeted Understanding
CC Math Standards
CC Math Practices
Lesson Description
Sasha and Keoni use a GeoGebra applet to move parabolas to the left, right, up, and down. Then they develop equations for several different parabolas where the vertex is not at the origin.
Targeted Understandings
This lesson can help students:
- Decompose the translation of a parabola on a coordinate grid into two directions: horizontal (left/right) and vertical (up/down).
- Understand that when a parabola is translated left or right, its directrix remains the same, as does the y-value of its focus. The x-value of the focus is adjusted by the direction and distance of the horizontal movement. The length of the horizontal side of the right triangle used to derive the equation will also reflect the horizontal translation (but the length of the vertical side and the hypotenuse remain the same as for the base parabola).
- Understand that when a parabola is translated up or down, its directrix also moves by the amount of the translation, as does the y-value of its focus. The x-value of the focus remains the same. The lengths of the vertical side and the hypotenuse of the right triangle used to derive the equation will also reflect the vertical translation (but the length of the horizontal side remains the same as for the base parabola).
Common Core Math Standards
• CCSS.M.HSF.BF.B.3: Identify the effect on the graph of replacing f(x) by f(x) + k, k f(x), f(kx), and f(x + k) for specific values of k (both positive and negative); find the value of k given the graphs. Experiment with cases and illustrate an explanation of the effects on the graph using technology.
In this lesson, Sasha and Keoni connect graphical translations of a base parabola (up, down, left, right, and a combination of these movements) with changes in the algebraic expression of the function. For example, shifting a base parabola with p = 3 and vertex at the origin to the right 7 units means that the term x – 7 will be in the numerator for the translated parabola (y = (x – 7)2/12)). When the same base parabola is translated up 2 units, the effect is the addition of 2 units to the equation (which is y = x2/12 for the base parabola and y = x2/12 + 2 for the translated parabola)
Common Core Math Practices
CCSS.Math.Practice.MP5. Use appropriate tools strategically.
According to the Common Core’s description of Math Practice 2, mathematically proficient students “know that technology can enable them to visualize the results of varying assumptions, explore consequences, and compare predictions with data.” In this lesson, Sasha and Keoni use the visual tool of a function-translation applet in GeoGebra to decompose the translation of a parabola into horizontal and vertical movements [Episode 1, 1:18 – 1:29 and 2:46 – 2:59]. This imagery is powerful for helping Keoni and Sasha conceive of the effect of translation on the lengths of the right triangle that they use to derive the equation of a parabola [see for example, 4:05 – 4:34 in Episode 2].
