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Parametric Equations. 3-Ext. Lesson Presentation. Holt Algebra 2. Objectives. Graph parametric equations, and use them to model real-world applications. Write the function represented by a pair of parametric equations. Vocabulary. parameter Parametric equations.
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Parametric Equations 3-Ext Lesson Presentation Holt Algebra 2
Objectives Graph parametric equations, and use them to model real-world applications. Write the function represented by a pair of parametric equations.
Vocabulary parameter Parametric equations
As an airplane ascends after takeoff, its altitude increases at a rate of 45 ft/s while its distance on the ground from the airport increases at 210 ft/s. Both of these rates can be expressed in terms of time. When two variables, such as x and y, are expressed in terms of a third variable, such as t, the third variable is called a parameter. The equations that define this relationship are parametric equations.
Example 1A: Writing and Graphing Parametric Equations As a cargo plane ascends after takeoff, its altitude increases at a rate of 40 ft/s. while its horizontal distance from the airport increases at a rate of 240 ft/s. Write parametric equations to model thelocation of the cargo plane described above. Then graph the equations on a coordinate grid.
x = 240t y = 40t Example 1A Continued Using the horizontal and vertical speeds given above, write equations for the ground distance x and altitude y in terms of t. Use the distance formula d = rt. Make a table of values to help you draw the graph. Use different t-values to find x- and y-values. The x and y rows give the points to plot.
Example 1A Continued Plot and connect (0, 0), (240, 40), (480, 80), (720, 120), and (960, 160).
Example 1B: Writing and Graphing Parametric Equations Find the location of the cargo plane 20 seconds after takeoff. Substitute t = 20. x = 240t = 240(20) = 4800 y = 40t = 40(20) = 800 At t = 20, the airplane has a ground distance of 4800 feet from the airport and an altitude of 800 feet.
x = 5t y = 20t Check It Out! Example 1a A helicopter takes off with a horizontal speed of 5 ft/s and a vertical speed of 20 ft/s. Write equations for and draw a graph of the motion of the helicopter. Using the horizontal and vertical speeds given above, write equations for the ground distance x and altitude y in terms of t. Use the distance formula d = rt.
Check It Out! Example 1a Continued Make a table of values to help you draw the graph. Use different t-values to find x- and y-values. The x and y rows give the points to plot.
Check It Out! Example 1b Describe the location of the helicopter at t = 10 seconds. Substitute t = 10. x = 5t =5(10) = 50 y = 20t =20(10) = 200 At t = 10, the helicopter has a ground distance of 50 feet from its takeoff point and an altitude of 200 feet.
You can use parametric equations to write a function that relates the two variables by using the substitution method.
Example 2: Writing Functions Based on Parametric Equations Use the data from Example 1 to write an equation from the cargo plane’s altitude y in terms of its horizontal distance x. Solve one of the two parametric equations for t. Then substitute to get one equation whose variables are x and y.
The equation for the airplane’s altitude in terms of ground distance is . Example 2 Continued Solve for t in the first equation. y = 40t Second equation Substitute and simply.
x = 5t, so y = 20 = 4x Check It Out! Example 2 Recall that the helicopter in Check It Out Problem 1 takes off with a horizontal speed of 5 ft/s and a vertical speed of 20 ft/s. Write an equation for the helicopter's motion in terms of only x and y. Solve for t in the first equation. y = 20t Second equation Substitute and simply. y = 4x The equation for the airplane’s altitude in terms of ground distance is y = 4x.