Calculus: An Integrated Approach to Functions and their Rates of Change, Preliminary Edition Part 113 pptx

Then isolate the other radical and square both sides to eliminate the second radical.. Then isolate the other radical and square both sides to eliminate the second radical.. E.3 THE PRAC

F1and F2are called the foci of the ellipse.

To sketch an ellipse, you can tack one end of a string to each focus and, with the point of

a pen, hold the string taut by moving around the foci you'll trace out an ellipse.

d1 + d2 is constant

d1

d2

Pen

Figure E.5 Ellipse

The farther apart the two foci, the more elongated the ellipse The closer they are to one another, the more circular the ellipse looks If the two foci merge to one point, then the figure is a circle.

A hyperbola

A hyperbola is the set of points (x, y) the difference of whose distances from two distinct fixed points F1and F2is constant

F1and F2are called the foci of the hyperbola.

|d2 – d1| is constant

d1

d1

d2

d2

2

Figure E.6

E.2 DEFINING CONICS ALGEBRAICALLY

Next we relate geometric and algebraic representations of conics First the conclusions are presented Then a road map is given The actual trips from geometric to algebraic respresentations are left as problems at the end of the section Signposts are provided To find these problems, look under the appropriate conic section; they lead the section of problems for the particular conic

Relating the Geometric and Algebraic Representations of Conics

If a circle has center (0, 0) and the distance from the center is denoted by r, then the circle is given by the equation

x2+ y2= r2

y

y x x

r

Circle: center (0, 0)

radius r

Figure E.7

If a parabola has focus (0, c) and directrix y = −c, then it will have a vertex at (0, 0) and be given by the equation

y = 1 4cx

2

y

x

c

Focus

directrix

Parabola:

focus (0, c) directrix y = – c

y = – c

Figure E.8

If an ellipse has foci at (c, 0) and (−c, 0) and the sum of the distances from any point

on the ellipse to the foci is denoted by 2a, then the ellipse will have x-intercepts of (a, 0) and (−a, 0) and be given by the equation

x2

a2+y

2

b2 = 1, where b2= a2− c2 (See Figure E.9(a).)

If an ellipse has foci at (0, c) and (0, −c) and the sum of the distances from any point

on the ellipse to the foci is denoted by 2a, then the ellipse will have y-intercepts of (0, a) and (0, −a) and be given by the equation

y2

a2+x

2

b2 = 1, where b2

= a2− c2 (See Figure E.9(b).)

y y

a

a

c

c

–c

–c –a

–a –b

–b

b

b

Ellipse with foci (c, 0), (–c, 0)

(a)

Ellipse with foci (0, c), (0, –c)

(b)

Figure E.9

If a hyperbola has foci at (c, 0) and (−c, 0) and the magnitude of the difference of the distances from any point on the hyperbola to the foci is denoted by 2a, then the hyperbola will have x-intercepts of (a, 0) and (−a, 0) and be given by the equation

x2

a2 −y

2

b2= 1, where b2= c2− a2 (See Figure E.10(a).)

If a hyperbola has foci at (0, c) and (0, −c) and the magnitude of the difference of the distances from any point on the hyperbola to the foci is denoted by 2a, then the hyperbola will have y-intercepts of (0, a) and (0, −a) and be given by the equation

y2

a2 −x

2

b2= 1, where b2= c2− a2 (See Figure E.10(b).)

a

a b

b c

c

–a

–a –b

–b –c

–c

b

Hyperbola with foci (c, 0) (– c, 0)

(a)

Hyperbola with foci (0, c) (0, –c)

(b)

Figure E.10

Circle: Let (x, y) be a point on the circle with center (0, 0) Use the distance formula (or the Pythagorean Theorem) to conclude that if the distance from (x, y) to (0, 0) is

r, then x2+ y2= r2

Parabola: Let (x, y) be a point on the parabola with focus F at (0, c) and directrix L

at y = −c Using the distance formula, we know that the distance from (x, y) to F is

x2+ (y − c)2and the distance from (x, y) to L is
(y + c)2 Equate the distances, square both sides, and simplify

Ellipse: Let (x, y) be a point on the ellipse with foci at (c, 0) and (−c, 0) Denote the sum of the distances from any point on the ellipse to the foci by 2a (This distance is some positive number, and denoting it by 2a is convenient.) Using the distance formula

we have that

 (x + c)2+ y2+

 (x − c)2+ y2= 2a

Isolate one radical and square both sides to eliminate it Then isolate the other radical and square both sides to eliminate the second radical Simplifying and denoting the quantity a2− c2by b2gives the desired result

Hyperbola:Let (x, y) be a point on the hyperbola with foci at (0, c) and (0, −c) Denote the magnitude (absolute value) of the differences of the distances from any point on the hyperbola to the foci by 2a (Denoting this difference by 2a is convenient.) Using the distance formula we obtain

 (x + c)2+ y2−

 (x − c)2+ y2= ±2a

Isolate one radical and square both sides to eliminate it Then isolate the other radical and square both sides to eliminate the second radical Simplifying and denoting the quantity c2− a2by b2gives the desired result

Conics Given as Ax2+ Bxy + Cy2+ Dx + Ey + F = 0 Consider the equation

Ax2+ Cy2= P , where A, C, and P are constants This is

i the equation of a circle if A = C, and the signs of A, C, and P agree;

ii the equation of an ellipse if A, C, and P have the same signs;

iii the equation of a hyperbola if A and C have opposite signs (to find out which way the hyperbola opens, look for the x- and y-intercepts—you’ll find only one pair);

iv the equation of a parabola if either A = 0 or C = 0

Consider the graph of 4(x − 2)2+ 9(y − 3)2= 36 This is the ellipse 4x2+ 9y2= 36 shifted 2 units right and 3 units up This example can be generalized

The graph of A(x − h)2+ C(y − k)2= P is the graph of the conic section Ax2+

Cy2= P shifted right h units and up k units Multiplying out gives an equation of the form

Ax2+ Cy2+ Dx + Ey + F = 0,

where A, C, D, E, and F are constants.

Conversely, an equation of the form Ax2+ Cy2+ Dx + Ey + F = 0 can, by com-pleting the square twice, be put in the form A(x − h)2+ C(y − k)2= P By looking at the signs of A and C as described above, one can determine the nature of the conic section

EXAMPLE E.1 Put the conic section

2x2− y2+ 4x + 6y − 8 = 0 into the form A(x − h)2

+ C(y − k)2= P and determine what it looks like

SOLUTION

2x2− y2+ 4x + 6y − 8 = 0 2x2+ 4x − y2+ 6y = 8 2(x2+ 2x) − (y2− 6y) = 8 2

 (x + 1)2− 1



−

 (y − 3)2− 9



= 8 2(x + 1)2− 2 − (y − 3)2+ 9 = 8

2(x + 1)2− (y − 3)2= 1 Therefore, this conic is the hyperbola 2x2− y2= 1 (a hyperbola with x-intercepts at ±√1

2) shifted left 1 unit and up 3 units

In addition to shifting the conic Ax2+ Cy2= P horizontally and vertically, we can rotate the conic The resulting algebraic equation is of the form

Ax2+ Bxy + Cy2+ Dx + Ey + F = 0, where A, B, C, D, E, and F are constants

It can be shown1that this equation gives

a parabola when B2

− 4AC = 0,

an ellipse when B2− 4AC < 0 (a circle if, in addition, A = C),

a hyperbola when B2− 4AC > 0

Notice that the sign of the expression B2− 4AC discriminates between the three types of conics This is not coincidental

In addition to having fascinating geometric characteristics, conic sections have many practical applications

1 This can be shown most elegantly using linear algebra; therefore the more accessible but less appealing argument is not given

E.3 THE PRACTICAL IMPORTANCE OF CONIC SECTIONS

Reflection Properties

The reflective properties of parabolas, hyperbolas, and ellipses are most useful when considering surfaces formed by rotating the two-dimensional figures around the line through the two foci in the latter two cases and through the focus and perpendicular to the directrix

in the former

Reflecting properties of parabolas: A light source placed at the focus will be reflected parallel to the axis of symmetry of the parabola Conversely, sound or light waves coming in parallel to the axis of symmetry of the parabola are reflected through the focus, thereby concentrating them there

This property makes parabolas a useful shape in the design of headlights and search-lights, reflecting mirrors in telescopes, satellite dishes, radio antennas, and micro-phones designed to pick up a conversation far away.

of a parabola

Parabolic headlight with the bulb at the focus

Figure E.11

Reflecting property of ellipses: Sound or light emanating from one focus and reflecting off the ellipse will pass through the other focus

F1 F2 Reflection propertyof an ellipse

Figure E.12

There are what are known as “whispering galleries” under the elliptic dome in the Capitol building of the United States as well as in the Mormon Tabernacle in Salt Lake City, Utah A person standing at one focus and whispering to his neighbor can

be heard quite clearly by an individual located at the other focus As you can imagine, this can be a potential problem for those unaware of the reflection properties of the ellipse.

In 1980 an ingenious medical treatment for kidney stones, called lithotripsy (from the Greek word for “stone breaking”), was introduced The treatment is based on the reflective properties of the ellipse Intense sound waves generated outside the body are focused on the kidney stone, bombarding and thereby destroying it without invasive

surgery Over 80% of patients with kidney stones can be treated with lithotripsy; the recovery time is substantially less and the mortality rate much lower than with the traditional surgery 2

Reflecting property of hyperbolas: Light traveling along a line through one focus of a hyperbola will be reflected off the surface of the hyperbola along the line through the point of reflection and the other focus

of a hyperbola

Figure E.13

The reflective property of hyperbolas is used in the construction of camera and telescope lenses as well as radio navigation systems, such as the long-range navigation system (LORAN).

Conic Sections and Astronomy

The path of any projectile under the force of gravity is a parabolic arc Around 1600 Kepler found that planets have elliptical orbits around the sun This discovery involved painstaking calculations using measurements collected by Tycho Brahe in the late 1500s over a period of more than two decades Kepler’s conclusions (and the accuracy of Tycho Brahe’s measurements) are rather astounding, given that the foci of most of the planets are very close together, making their paths very nearly circular.3Newton later put Kepler’s observations on solid theoretical grounds

Comets can travel in elliptical orbits (like Halley’s comet) or in parabolic orbits The moon has an elliptical orbit with the earth at one focus

P R O B L E M S F O R A P P E N D I X E

Parabolas

1 Begin with the geometric characterization of a parabola Suppose that the focus F is at (0, c) and the directrix L is at y = −c You will show that the set of points equidistant from F and L is the parabola y =4c1x2

(a) Use the fact that the axis of symmetry is perpendicular to the directrix and passes through the focus to deduce that the vertex of the parabola is at (0, 0)

2 The story of the development of this treatment is fascinating It came out of scientists looking at aircraft You can get more in-formation on the scientific aspects at http://www.hvlitho.com/lithotripsy and on the mathematics of it at http://www.math.iupui.edu: edu:80/m261vis/litho.

3For more information on Kepler, consult a history of mathematics book, such as A History of Mathematics An Introduction

2

y

x

(2.5, 2)

(b) Let (x, y) be a point on the parabola described above Equating the distance between the point (x, y) and F with the distance between the point (x, y) and

Lgives the equation



x2

+ (y − c)2=

 (y + c)2 Explain

(c) Square both sides of the equation in part (b) to solve for y

2 In Problem 1 you showed that a parabola with focus F at (0, c) and the directrix L at

y = −c can be written in the form

y = 1 4cx

2

(a) Find the equation of the parabola with vertex (0, 0) and focus (0, 1) Sketch its graph In the sketch show the location of the focus and directrix

(b) Find the equation of the parabola with vertex (0, 0) and directrix y = 2 Sketch its graph In the sketch show the location of the focus and directrix

3 In Problem 1 you showed that a parabola with focus F at (0, c) and the directrix L at

y = −c can be written in the form

y = 1 4cx

2

Find the focus and directrix of the parabola y = 2x2

4 If the focus and directrix of a parabola are moved farther apart, does the parabola get narrower or does it get wider? Explain

5 Find the equation of a parabola with its vertex at the origin and its focus at (0, 6)

6 Find the equation of a parabola with vertex at (0, 0) and directrix y = 5

7 A headlight is made of reflective material in the shape of a parabolic dish In order to take advantage of the fact that light emanating from the focus will be reflected by the parabolic bowl in the direction of the axis of symmetry, where should the light source

be placed if the dish is 5 inches in diameter and 2 inches in depth?

(Hint: Look at a cross section of the reflector and introduce a coordinate system Let the y-axis lie along the axis of symmetry of the reflector and let the origin lie at the vertex of the reflector.)

8 The light filament in the bulb of a floodlight is 1.5 inches from the vertex of the paraboloid reflector (The cross sections of the reflector taken through the vertex are all identical parabolas.)

(a) Find the equation of the parabolic cross section

(b) If the reflector dish is 10 inches in diameter, how deep is it?

9 Let (x, y) be a point on the ellipse with foci at (0, c) and (0, −c) You will arrive at the formula

x2

a2 +y

2

b2= 1, where a2− C2= b2

(a) Denote the sum of the distances from any point (x, y) on the ellipse to the foci

by 2a (This distance is some positive number; denoting it by 2a is convenient.) Using the distance formula we know that

 (x + c)2+ y2+

 (x − c)2+ y2= 2a

Isolate
(x + c)2+ y2and square both sides of the equation to eliminate it After multiplying out you should be able to simplify the result to

a

 (x + c)2+ y2= a2+ cx

(b) Square both sides of the equation a
(x + c)2+ y2= a2+ cx to eliminate the radical Show that the result can be expressed in the form

(a2− c2)x2+ a2y2= a2(a2− c2) (E.1) (c) The distance between the two foci is 2c This must be less than the sum of the distance between (x, y) and the foci Thus 2a > 2c, or a > c Consequently, (a2− c2) >0 and we can divide both sides of Equation E.1 by a2(a2− c2)to get

x2

a2+ y

2

a2

− c2= 1.

Denote a2− c2by b2to get the desired result

10 (a) In Problem 9 you showed that the ellipse with foci at (0, c) and (0, −c) is given algebraically by

x2

a2+y

2

b2 = 1

Explain from an algebraic point of view how you know that b < a

(b) What is the geometric significance of the constants a and b?

Hyperbolas

11 Let (x, y) be a point on the hyperbola with foci at (0, c) and (0, −c) Denote the magnitude (absolute value) of the differences of the distances from any point on the hyperbola to the foci by 2a

(a) Using the distance formula show that

 (x + c)2+ y2−

 (x − c)2+ y2= ±2a

(b) Carry on as in Problem 9 Isolate one radical and square both sides to eliminate it Then isolate the other radical and square both sides to eliminate the second radical Show that you obtain

(c2− a2)x2− a2y2= a2(c2− a2)

(c) Argue that c2− a2>0 Once this is done, we can set b2= c2− a2 Simplify to obtain

x2

a2−y

2

b2= 1