3D Coordinate Geometry
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Transcript of 3D Coordinate Geometry
![Page 1: 3D Coordinate Geometry](https://reader034.fdocuments.us/reader034/viewer/2022042422/55a844fb1a28ab56358b48df/html5/thumbnails/1.jpg)
VECTORS AND VECTORS AND THE GEOMETRY OF SPACETHE GEOMETRY OF SPACE
12
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VECTORS AND THE GEOMETRY OF SPACE
In this chapter, we introduce
vectors and coordinate systems
for three-dimensional space.
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This will be the setting for our study of
the calculus of functions of two variables
in Chapter 14.
This is because the graph of such a function is a surface in space.
VECTORS AND THE GEOMETRY OF SPACE
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We will see that vectors provide
particularly simple descriptions of lines
and planes in space.
VECTORS AND THE GEOMETRY OF SPACE
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12.1Three-Dimensional
Coordinate Systems
In this section, we will learn about:
Aspects of three-dimensional coordinate systems.
VECTORS AND THE GEOMETRY OF SPACE
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TWO-DIMENSIONAL (2-D) COORDINATE SYSTEMS
To locate a point in a plane, two numbers
are necessary.
We know that any point in the plane can be represented as an ordered pair (a, b) of real numbers—where a is the x-coordinate and b is the y-coordinate.
For this reason, a plane is called two-dimensional.
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THREE-DIMENSIONAL (3-D) COORDINATE SYSTEMS
To locate a point in space, three
numbers are required.
We represent any point in space by
an ordered triple (a, b, c) of real numbers.
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In order to represent points in space,
we first choose:
A fixed point O (the origin)
Three directed lines through O that are perpendicular to each other
3-D COORDINATE SYSTEMS
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The three lines are called the coordinate
axes.
They are labeled:
x-axis y-axis z-axis
COORDINATE AXES
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Usually, we think of:
The x- and y-axes as being horizontal
The z-axis as being vertical
COORDINATE AXES
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We draw the orientation of the axes
as shown.
COORDINATE AXES
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The direction of the z-axis is
determined by the right-hand rule,
illustrated as follows.
COORDINATE AXES
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Curl the fingers of your right hand
around the z-axis in the direction of a 90°
counterclockwise rotation from the positive
x-axis to the positive y-axis.
Then, your thumb points in the positive direction of the z-axis.
COORDINATE AXES
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The three coordinate axes determine
the three coordinate planes.
The xy-plane contains the x- and y-axes.
The yz-plane contains the y- and z-axes.
The xz-plane contains the x- and z-axes.
COORDINATE PLANES
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These three coordinate planes divide
space into eight parts, called octants.
The first octant, in the foreground, is determined by the positive axes.
OCTANTS
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Many people have some difficulty
visualizing diagrams of 3-D figures.
Thus, you may find it helpful to do
the following.
3-D COORDINATE SYSTEMS
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Look at any bottom corner of a room
and call the corner the origin.
3-D COORDINATE SYSTEMS
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The wall on your left is in the xz-plane.
The wall on your right is in the yz-plane.
The floor is in the xy-plane.
3-D COORDINATE SYSTEMS
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The x-axis runs along the intersection
of the floor and the left wall.
The y-axis runs along that of the floor
and the right wall.
3-D COORDINATE SYSTEMS
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The z-axis runs up from the floor toward
the ceiling along the intersection of the two
walls.
3-D COORDINATE SYSTEMS
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You are situated in the first octant.
You can now imagine seven other rooms
situated in the other seven octants.
There are three on the same floor and four on the floor below.
They are all connected by the common corner point O.
3-D COORDINATE SYSTEMS
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Now, if P is any point in space,
let:
a be the (directed) distance from the yz-plane to P.
b be the distance from the xz-plane to P.
c be the distance from the xy-plane to P.
3-D COORDINATE SYSTEMS
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We represent the point P by the ordered
triple of real numbers (a, b, c).
We call a, b, and c the coordinates of P.
a is the x-coordinate. b is the y-coordinate. c is the z-coordinate.
3-D COORDINATE SYSTEMS
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Thus, to locate the point (a, b, c), we can start
at the origin O and proceed as follows:
First, move a units along the x-axis.
Then, move b units parallel to the y-axis.
Finally, move c units parallel to the z-axis.
3-D COORDINATE SYSTEMS
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The point P(a, b, c) determines a
rectangular box.
3-D COORDINATE SYSTEMS
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If we drop a perpendicular from P to
the xy-plane, we get a point Q with
coordinates (a, b, 0).
This is called the projection of P on the xy-plane.
PROJECTIONS
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Similarly, R(0, b, c) and S(a, 0, c) are
the projections of P on the yz-plane and
xz-plane, respectively.
PROJECTIONS
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As numerical illustrations, the points
(–4, 3, –5) and (3, –2, –6) are plotted here.
3-D COORDINATE SYSTEMS
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The Cartesian product
R x R x R = {(x, y, z) | x, y, z R}
is the set of all ordered triples of real numbers
and is denoted by R3.
∈
3-D COORDINATE SYSTEMS
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We have given a one-to-one correspondence
between points P in space and ordered triples
(a, b, c) in R3.
It is called a 3-D rectangular coordinate system.
3-D RECTANGULAR COORDINATE SYSTEM
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Notice that, in terms of coordinates,
the first octant can be described as
the set of points whose coordinates are
all positive.
3-D RECTANGULAR COORDINATE SYSTEM
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In 2-D analytic geometry, the graph of an
equation involving x and y is a curve in R2.
In 3-D analytic geometry, an equation in
x, y, and z represents a surface in R3.
2-D VS. 3-D ANALYTIC GEOMETRY
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What surfaces in R3 are represented by
the following equations?
a. z = 3
b. y = 5
Example 13-D COORDINATE SYSTEMS
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The equation z = 3 represents the set
{(x, y, z) | z = 3}.
This is the set of all points in R3 whose z-coordinate is 3.
Example 1 a3-D COORDINATE SYSTEMS
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This is the horizontal plane that is
parallel to the xy-plane and three units
above it.
Example 1 a3-D COORDINATE SYSTEMS
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The equation y = 5 represents
the set of all points in R3 whose
y-coordinate is 5.
Example 1 b3-D COORDINATE SYSTEMS
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This is the vertical plane that is
parallel to the xz-plane and five units
to the right of it.
Example 1 b3-D COORDINATE SYSTEMS
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When an equation is given, we must
understand from the context whether it
represents either:
A curve in R2
A surface in R3
NoteNOTE
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In Example 1, y = 5 represents
a plane in R3.
NOTE
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However, of course, y = 5 can also
represent a line in R2 if we are dealing with
two-dimensional analytic geometry.
NOTE
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In general, if k is a constant,
then
x = k represents a plane parallel to the yz-plane.
y = k is a plane parallel to the xz-plane.
z = k is a plane parallel to the xy-plane.
NOTE
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In this earlier figure, the faces of the box
are formed by:
The three coordinate planes x = 0 (yz-plane), y = 0 (xz-plane), and z = 0 (xy-plane)
The planes x = a, y = b, and z = c
NOTE
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Describe and sketch the surface in R3
represented by the equation
y = x
Example 23-D COORDINATE SYSTEMS
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The equation represents the set of all points
in R3 whose x- and y-coordinates are equal,
that is, {(x, x, z) | x R, z R}.
This is a vertical plane that intersects the xy-plane in the line y = x, z = 0.
Example 23-D COORDINATE SYSTEMS
∈ ∈
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The portion of this plane that lies in
the first octant is sketched here.
Example 23-D COORDINATE SYSTEMS
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The familiar formula for the distance
between two points in a plane is easily
extended to the following 3-D formula.
3-D COORDINATE SYSTEMS
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DISTANCE FORMULA IN THREE DIMENSIONS
The distance |P1P2| between the points
P1(x1,y1, z1) and P2(x2, y2, z2) is:
2 2 21 2 2 1 2 1 2 1( ) ( ) ( )PP x x y y z z= − + − + −
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To see why this formula is true, we
construct a rectangular box as shown,
where:
P1 and P2 are opposite vertices.
The faces of the box are parallel to the coordinate planes.
3-D COORDINATE SYSTEMS
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If A(x2, y1, z1) and B(x2, y2, z1) are the vertices
of the box, then
|P1A| = |x2 – x1|
|AB| = |y2 – y1|
|BP2| = |z2 – z1|
3-D COORDINATE SYSTEMS
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Triangles P1BP2 and P1AB are right-angled.
So, two applications of the Pythagorean
Theorem give:
|P1P2|2 = |P1B|2 + |BP2|2
|P1B|2 = |P1A|2 + |AB|2
3-D COORDINATE SYSTEMS
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Combining those equations,
we get:
|P1P2|2 = |P1A|2 + |AB|2 + |BP2|2
= |x2 – x1|2 + |y2 – y1|2 + |z2 – z1|2
= (x2 – x1)2 + (y2 – y1)2 + (z2 – z1)2
3-D COORDINATE SYSTEMS
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Therefore,
2 2 21 2 2 1 2 1 2 1( ) ( ) ( )PP x x y y z z= − + − + −
3-D COORDINATE SYSTEMS
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The distance from the point P(2, –1, 7)
to the point Q(1, –3, 5) is:
2 2 2(1 2) ( 3 1) (5 7)
1 4 4
3
PQ = − + − + + −
= + +=
Example 33-D COORDINATE SYSTEMS
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Find an equation of a sphere
with radius r and center C(h, k, l).
Example 43-D COORDINATE SYSTEMS
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By definition, a sphere is the set of
all points P(x, y ,z) whose distance from C
is r.
Example 43-D COORDINATE SYSTEMS
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Thus, P is on the sphere if and only
if |PC| = r
Squaring both sides, we have |PC|2 = r2
or (x – h)2 + (y – k)2 + (z – l)2 = r2
Example 43-D COORDINATE SYSTEMS
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The result of Example 4 is worth
remembering.
We write it as follows.
3-D COORDINATE SYSTEMS
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EQUATION OF A SPHERE
An equation of a sphere with center C(h, k, l)
and radius r is:
(x – h)2 + (y – k)2 + (z – l)2 = r2
In particular, if the center is the origin O, then an equation of the sphere is:
x2 + y2 + z2 = r2
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Show that
x2 + y2 + z2 + 4x – 6y + 2z + 6 = 0
is the equation of a sphere.
Also, find its center and radius.
Example 53-D COORDINATE SYSTEMS
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We can rewrite the equation in the form of an
equation of a sphere if we complete squares:
(x2 + 4x + 4) + (y2 – 6y + 9) + (z2 + 2z + 1)
= –6 + 4 + 9 + 1
(x + 2)2 + (y – 3)2 + (z + 1)2 = 8
Example 53-D COORDINATE SYSTEMS
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Comparing this equation with the standard
form, we see that it is the equation of a sphere
with center (–2, 3, –1) and radius 8 2 2=
Example 53-D COORDINATE SYSTEMS
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What region in R3 is represented by
the following inequalities?
1 ≤ x2 + y2 + z2 ≤ 4
z ≤ 0
Example 63-D COORDINATE SYSTEMS
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The inequalities
1 ≤ x2 + y2 + z2 ≤ 4
can be rewritten as:
So, they represent the points (x, y, z) whose distance from the origin is at least 1 and at most 2.
2 2 21 2x y z≤ + + ≤
Example 63-D COORDINATE SYSTEMS
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However, we are also given that
z ≤ 0.
So, the points lie on or below the xy-plane.
Example 63-D COORDINATE SYSTEMS
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Thus, the given inequalities represent
the region that lies:
Between (or on) the spheres x2 + y2 + z2 = 1 and x2 + y2 + z2 = 4
Beneath (or on) the xy-plane
Example 63-D COORDINATE SYSTEMS