Definition: Conic Sections The conic sections are all the curves that can be made from slicing two cones stacked tip to tip with a plane.

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1 . The Parabola The main topic of this chapter is something we call conic sections. Definition: Conic Sections The conic sections are all the curves that can be made from slicing two cones stacked tip to tip with a plane. Some types of conic sections (or conics we have already seen. For example, if we slice the cones through the tips we get a single point. If we slice the cones in such a way as we simply touch one side of one cone and the opposite side of the other, we get a line. Lastly, if we slice them vertically though the tips, we get two intersecting lines. These types of conics we have already dealt with. We are more interested four conic sections demonstrated below. We will start with the parabola since we have already had some contact with parabolas in chapter 0. Standard Form of a Parabola The equation of a parabola with vertex at ( k y = a( x h + k x = a( y k + h h, is for a vertical axis of symmetry of for a horizontal axis of symmetry of x = h or, y = k. This gives us the following four possibilities for parabolas, the first two we have seen before.

2 a positive ( x h k y = a + a negative Axis of symmetry vertex a positive ( y k h x = a + a negative vertex vertex Axis of symmetry We can see that graphing these parabolas will be very similar to how we graphed them in chapter 0. Its just that now its possible for the graph to be sideways. Example : Graph the following. State the vertex and all intercepts. a. y = x + 4x b. x = y y Solution: a. First we need to get the parabola into standard form so we can find the vertex. We do this by completing the square (recall there is an alternate method of using x = -b/a, however, for the purpose of this chapter its best to do use the completing the square method. This way, all conics can be treated similarly. We proceed as follows

3 y = x = = =, So our vertex is at ( + 4x ( x + x ( x + x + ( ( ( x + Next we need our intercepts. Recall, to find the x-intercepts, we set the bottom equation from above to equal 0 and to find the y-intercepts we set x in the top equation to zero. This gives us x-intercepts: y-intercept: ( x + = 0 y = ( 0 + 4( 0 ( x + = x ± x., 0. Now we simply plot all of our values and use the fact that the graph opens up (since a = which means a > 0 to complete the graph. b. Similarly we need to start by getting the equation into standard form. So we complete the square on the y terms this time to get the following x = y = = y ( y y + ( 6 5 ( 6 + ( y + 4 Notice, though, the order here for the vertex is reversed. This time we have the vertex is ( 4,. We can always remember this by simply remembering that the value inside the parenthesis always goes with the variable inside the parenthesis and that its sign is always opposite. The value on the outside always goes with the other variable. So here, the goes with the y as a and so thus 4 goes with the x. Now again we need the intercepts this time the way we do it is again switched. This time to find the y-intercepts, we set the bottom equation from above to equal 0 and to find the x-intercepts we set y in the top equation to zero.

4 This gives us x-intercept: y-intercepts: y + 4 = 0 x = ( 0 ( 0 ( = 5 ( y + = 4 y ± y 5, Now we simply plot all of our values and use the fact that the graph opens right (since a = which means a > 0 to complete the graph. Example : Graph the following. State the vertex and all intercepts. a. y x + x b. x y + y Solution: a. Proceeding like in example we complete the square to find the vertex. We get y x + x (, 8 ( x 4x ( x 4x + ( 4 ( 4 ( x + 8 So the vertex is at. Next we find the intercepts. x-intercepts: y-intercept: + 8 = 0 Graphing we get ( ( x y ( 0 ( + 0 ( x = 6 = 6 x = ± 4 x, 6

5 b. Similarly we find the vertex. So the vertex is at x-intercept: x y (, + y ( y y ( y y + ( ( ( y. Next we find the intercepts. y-intercepts: ( x ( 0 + ( 0 ( y ( y = 0 y = ± i Since the y intercepts are complex numbers there must be no y-intercepts. So putting it all together and using the fact that the graph opens left (since a < 0 we get. Exercises Graph the following. State the vertex and all intercepts.. y = x 5. = ( x + 9 ( y. x = ( y + 4 x = ( y 6 x = ( y x = ( y 5 y = ( x + y = ( x 4 9. y ( x y ( x + + x ( y + 4. x ( y + 7 x = ( y + + ( x y 5. y = x y = x + 7. y = x + 4x 8. y = x + x 5 6. ( x = y 6y + x = y 4y x = y + 8y x = y 0y + y = x x + y = x 6x.. 4. x y y + 7 x y + y x = y 4y x = 4y + 8y y = x + 7x y = x 5x y x 4x 6 y x x + x = y y... x = 4y + y x y y x y 7y y = x + 4 x + 8. y = x x + 9. x y 5y +

6 x y y = + x 4. x = + y x x y + 8 = 0 y x + = x y + 4y x y + 7 = x + y x y = x + y ( ( y + = x + y 47. y x y + x 48. Find the equation of the parabola in standard form which satisfies the following. 49. vertex (,, vertical axis of symmetry, a =, 4 a,, 50. vertex (,, vertical axis of symmetry 5 (,, horizontal axis of symmetry 5 (, 6 (, ( 9, 8, runs through the point (, 8 5. vertex (, runs through the point 5. vertex (, runs through the point, horizontal axis of symmetry 5. vertex is at the midpoint of and 9, horizontal axis of symmetry 54. vertex is at the midpoint of ( 4, 0 and (, ( 4, 0 axis of symmetry 55. axis of symmetry x =, vertex is at the intersection of the axis of symmetry and the line x + y = 6, runs through the point (, axis of symmetry y, vertex is at the intersection of the axis of symmetry and the line x y = 5, runs through the point (, 5, runs through the point, horizontal 4

Pre Calculus Math 40S: Explained!

Pre Calculus Math 40S: Explained! www.math0s.com 97 Conics Lesson Part I The Double Napped Cone Conic Sections: There are main conic sections: circle, ellipse, parabola, and hyperbola. It is possible to create each of these shapes by passing