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Lesson I: Definition and geometric construction of a parabola

Definition: The parabola is the locus of a set of points equidistant from a fixed point, and a fixed line. The fixed point is called the focus of the parabola and the given line is called the directrix.

Note: A locus is the set of points satisfying certain relations. Here, the locus, i.e. the set of points, consists of the points equidistant from a fixed point, and a fixed line

Figure 1. Construction of a parabola

Movie Clip GSP File


Student Work: At this point allow students to draw their own sketches on the computers and observe some properties of the parabola.

After students spend several minutes on observing and playing with the parabola, help students to notice (if they have not noticed) another special point for a parabola: vertex of a parabola.

Teacher's Action: Mark the vertex of the parabola as in the Figure 1. Ask students to determine properties have this special point may have, i.e. the vertex.

Challenge to Students: What happens if the focus point is under the directrix instead of above the directrix?


Click here to investigate parabolas on an interactive java applet (If you do not have GSP software on your computer, it's an perfect opportunity to take a look at.)

 

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Lesson II: Introduction to the algebraic representation of a parabola

Before introducing a general equation (i.e. the analytic, polar or parametric form) of a parabola, it is important for them to see the mechanism (or the relation) on the parabola. Simply, the relation between the points on the parabola, the directrix and the focus of the parabola follows from the definition and an application of Pythegorean Theorem.

So before giving a formal equation of a parabola, deal with the following problem:

For a parabola the following two cases (See Figure2a and 2b) are valid:

 

Figure 2a.

a is the distance between focus and the vertex or half the distance between focus and the directrix.

Figure 2b.

a is the distance between focus and the vertex or half the distance between focus and the directrix.

GSP File

Proof:

In the first case (FS < PR), since FP = PR and FV = VS =a (by the definition of parabola), PQ = FP - 2a. By Pythagorean Thm. applied to the right triangle FPQ,

 

The second case (FS > PR) is left for students' own investigations and constructions.

 

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Lesson III: Analytic Equation of a Parabola

Let's put a coordinate system so that the vertex of the parabola is the origin of the parabola and the parabola opens upward (See Figure 3).

Figure 3

GSP File

As we did above, since the distance between focus and the parabola is equal to the distance between the point and the directrix:

 

Thus the general equation of the parabola with vertex at the origin (0,0) and upwards has the general equation

The quantity 4a is known as the Latus Rectum. If the vertex is at instead of (0, 0), the equation of the parabola is


Generally the vertex of a parabola is represented by the point (h, k).



Similarly, for a parabola opening to the right with vertex at (0, 0) (See Figure 4), the equation in Cartesian Coordinates is

Figure 4

GSP File

If the vertex is at instead of (0, 0), the equation of the parabola is


If we expand the equations

&

We may write a very general equation of a parabola in cartesion coordinate system is

if the parabola opens upward (See Figure 3) or downward, and

if the parabola is opening to the left or right (See Figure 4).

 

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Lesson IV: Understanding the simplest parabolas of the form

The lesson is located at: http://jwilson.coe.uga.edu/EMT668/EMAT6680.F99/Erbas/write-ups/AKEwrite-up2/AKEwrite-up2.html

 

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Lesson V: Polar and Parametric Equations of a Parabola

In Polar Coordinates, the equation of a parabola with parameter a and center (0, 0) (See Figure 5) is:

 

Figure 5

GSP File

Using the definition of the parabola, since the distance between the center (0,0) and the point is equal to the distance between the point and the directrix,


Parametric Form: The parametric equations of a parabola are

 

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Lesson VI: In class worksheet

Students work in groups and each student makes his/her own electronic portfolio of the solutions and investigations.

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Lesson VII: Reflective (Optical) Property of Parabola

If a ray of light travels perpendicular to the directrix of a parabola (or in three dimensions, a paraboloid of revolution) and strikes the concave side of the parabola, then it will be reflected to the focus. Equivalently, if a ray of light leaves the focus and strikes the parabola, it will be reflected in a path perpendicular to the directrix (See Figure 6a & Figure 6b). This property is an essential feature of satellite dishes, car headlights, radio telescopes, and reflecting telescopes, including liquid mirror telescopes. In fact, if you throw a ball, it will follow a parabolic path.

 

Figure 6a

Movie Clip

 

Figure 6b

GSP File

Click here for a proof of the above property by vector calculus

To investigate the reflective property with java technology, here is an opportunity:

http://www.ies.co.jp/math/java/focus/focus.html

Students' Investigation: An interesting property can be observed when one looks at the locus of a point on the reflected ray that is a fixed distance from the Point P that moves along the parabola. In Figure 7, we see the locus (thick blue curve) of the point x on reflected ray as P moves along the parabola. GSP file allows one to examine the locus for various distances of the point x from P. Since the reflected ray passes through the focus, the locus for any X will be symmetric.

Figure 7b

GSP File

Here are some other similar curves for different X points on the reflected ray.

 

 

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Lesson VIII: Properties of tangents to a parabola

Let V be the vertex of a parabola. And let the line L be perpendicular to the directrix of the parabola at V. For a point A on L, if AC is constructed, where IAVI = IBVI, then AC is tangent to the parabola (See the figure below)

 

Click here for GSP sketch and a formal proof.

 

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Lesson IX: Area property of a parabola

This lesson investigates the ratio between the area of the parabolic section bounded by a parabola and a chord and the area of the triangle which has the vertex of the parabolic section and two points of intersection of the segment and the parabola as its vertices

 

 

Click Here for the lesson and related investigations

 

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Student Projects

Students' prepare and present a project dealing with parabolas. This could be individual or group work. The project subjects could be the applications of parabolas in daily life, more advanced properties of parabolas, or more detailed versions of the classroom investigations.

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A. Kursat ERBAS © 2000

mail: aerbas@coe.uga.edu

This page created March 5, 2000

This page last modified February 26, 2012