Lect Vectors Assign.ppt PDF

Summary

This document provides teaching slides on basic vector concepts, including scalar and vector quantities, vector operations, 2 and 3 dimensional components, dot products, cross products, and mixed triple products.

Full Transcript

Teaching Slides
Chapter 2: Vectors

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 Chapter Outline
Scalars & Vectors
Rules for Manipulating Vectors
Components in 2 Dimensions
Components in 3 Dimensions
Dot Products
Cross Products
Mixed Triple Products

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 2.1 Scalars & Vectors

Scalar – a physical quantity that is
completely described by a real number
 E.g. Time, mass
Vector – both magnitude (nonnegative real
number) & direction
 E.g.Position of a point in space relative to
another point, forces
 Represented by boldfaced letters: U, V , W,...
 Magnitude of vector U  U

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30 METERS 30 METERS @ 45O
@ 90O

50 METERS @ 0O
VECTOR ARROWS MAY BE DRAWN
= 10 METERS ANYWHERE ON THE PAGE AS
LONG AS THE PROPER LENGTH AND
SCALE DIRECTION ARE MAINTAINED
 2.2 Rules for Manipulating Vectors
Definition of Vector Addition:
 Vector from tail of U to head of V
Triangle rule

 Sum is independent of the order in which the
vectors are placed head to tail
Parallelogram rule

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 ALL VECTORS MUST
BE DRAWN TO
SCALE & POINTED IN
THE PROPER
DIRECTION
A

R D
B
C
B

C
A

D
A+ B + C +D = R
 Vector A
30 METERS @ 45O To add the vectors
Place them head to tail

Vector B
50 METERS @ 0O C

Vector C
30 METERS B
@ 90O
A
Angle is measured at 40o
= 10 METERS
SCALE Resultant = 9 x 10 = 90 meters
 2.1 Scalars & Vectors
 Graphical representation of vectors: arrows
Direction of arrow = direction of vector

Length of arrow  magnitude of vector

Example:
 rAB = position of point B relative

(a)
to point A
 Direction of rAB = direction from
point A to point B
 |rAB| = distance between 2 points
(b)
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 2.2 Rules for Manipulating Vectors
Vector Addition:
 When an object undergoes a displacement
(moves from 1 location in space to another)

 Displacement vector: U
 Direction of U = direction of displacement
 |U| = distance the book moves

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 2.2 Rules for Manipulating Vectors
 2nd displacement V
 Final position of book is the same whether we
give it displacement U then V, or vice versa
U and V equivalent to a single displacement
W: U + V = W

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 2.2 Rules for Manipulating Vectors

 Vector addition is commutative:
U+V=V+U (2.1)
 Vector addition is associative:

(U + V) + W = U + (V + W) (2.2)
 If the sum of 2 or more vectors = 0,
they form a closed polygon
 Example:
Vector rAC from A to C is the sum
of rAB & rBC
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 2.2 Rules for Manipulating Vectors
Product of a Scalar & a Vector:
 Product of scalar (real number) a & vector
U = vector aU
 Magnitude = |a||U| , where |a| is the absolute
value of the scalar a
 Direction of aU is the same as direction of U
when a is positive
 Direction of aU is opposite to direction of U
when a is negative
 Division of a vector U by
a scalar a: U  1 
  U
a  a
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 2.2 Rules for Manipulating Vectors

 The product is associative with respect to
scalar multiplication:
a(bU) = (ab)U (2.3)
 The product is distributive with respect to
scalar addition:
(a + b)U = aU + bU (2.4)
 The product is distributive with respect to
vector addition:
a(U + V) = aU + aV (2.5)

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 2.2 Rules for Manipulating Vectors
Vector Subtraction:
U – V = U + (1)V (2.6)
Unit Vectors:
 Magnitude =1
 Specifies a direction
 If a unit vector e & a vector U have
the same direction: U = |U|e

Unit Vector
Vector Subtraction
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Resultant of Two Vectors
 The resultant is the sum or the combined
effect of two vector quantities

Vectors in the same direction:
6N 4N = 10 N

6m
= 10 m
4m
Vectors in opposite directions:
6 m s-1 10 m s-1 = 4 m s-1

6N 10 N = 4N
Up = + Down = - Right = + Left = -

Rectangular Coordinates
90 o North
y
Quadrant II + Quadrant I

- + x 0 East
o
West 180 o

360 o
Quadrant III Quadrant IV
-
270 o South
 90O North
+y
120O

-240O

West 180O +x 0O East
-x
360O
30O West of North
30O Left of +y
MEASURING THE
SAME DIRECTION
60O North of West -y IN DIFFERENT WAYS
60O Above - x
270O South
 RADIANS = ARC LENGTH / RADIUS LENGTH
CIRCUMFERENCE OF A CIRCLE = 2  x RADIUS
RADIANS IN A CIRCLE = 2  R / R
1 CIRCLE = 2  RADIANS = 360O
1 RADIAN = 360O / 2  = 57.3O
/2 radians
y
Quadrant II + Quadrant I

- + x 0 radians
 radians
2 radians
Quadrant III Quadrant IV
-
3/2  radians
The Parallelogram Law
 When two vectors are joined
tail to tail
 Complete the parallelogram
 The resultant is found by
drawing the diagonal

 When two vectors are joined
head to tail
 Draw the resultant vector by
completing the triangle
Problem: Resultant of 2 Vectors
Two forces are applied to a body, as shown. What is the magnitude and
direction of the resultant force acting on the body?

Solution:
 Complete the parallelogram (rectangle)
 The diagonal of the parallelogram ac

represents the resultant force
 The magnitude of the resultant is found using
Pythagoras’ Theorem on the triangle abc 12 N
a d
2 2
Magnitude ac  12  5 θ 13

5N
N 5
ac 13 N
12 b
12
c
Direction of ac : tan  
5
12
  tan  1 67  Resultant displacement is 13 N
5
67º with the 5 N force
Problem: Resultant of 3 Vectors
Find the magnitude (correct to two decimal places) and direction of the
resultant of the three forces shown below.
Solution:
 Find the resultant of the two 5 N forces first (do right angles first)

ac  52  52  50 7.07 N
5 d 5 c
tan   1   45
5

N
5N
Now find the resultant of the 10 N and 5

07


7.
7.07 N forces
 The 2 forces are in a straight line (45º + 90º
45º
θ
a

N
b
135º = 180º) and in opposite directions 5N

93
135º

2.
N
 So, Resultant = 10 N – 7.07 N = 2.93
10
N in the direction of the 10 N force
Calculating the Magnitude of the
Perpendicular Components
If a vector of magnitude v and makes an angle θ with the
horizontal then the magnitude of the components are:
x = v Cos θ
v
y = v Sin θ y=v Sin
θ
y
θ
x=v
x Cos θ
 Proof:
x y
Cos  Sin 
v v
x vCos y vSin
 Problem: Calculating the magnitude of
perpendicular components
A force of 15 N acts on a box as shown. What is the horizontal
component of the force?

Solution:

Horizontal Component  x 15Cos 60 7.5 N

Component
12.99 N

N
Vertical

15
Vertical Component  y 15Sin 60 12.99 N
60º
Horizontal
7.5 N
Componen
t
 Example 2.1 Adding Vectors
Fig. 2.11 is an initial design sketch of part of the roof of
a sports stadium to be supported by the cables AB &
AC. The forces the cables exert on the pylon to which
they are attached are represented by the vectors FAB &
FAC. The magnitude of the forces are |FAB| = 100 kN & |
FAC| = 60 kN. Determine the magnitude & direction of the
sum of the forces exerted on the pylon by the cables (a)
graphically & (b) using trigonometry.

Figure 2.11
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 Example 2.1 Adding Vectors

Strategy
(a) By drawing the parallelogram rule for adding the
2 forces with the vectors drawn to scale, we can
measure the magnitude & direction of their sum.
(b) We will calculate the magnitude & direction of
the sum of the forces by applying the laws of
sines & cosines to the triangles formed by the
parallelogram rule.

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 Example 2.1 Adding Vectors

Solution
(a) Graphically construct the parallelogram rule with
FAB & FAC proportional to their magnitudes:

By measuring the figure, we estimate the
magnitude of the vector FAB + FAC to be 155 kN
& its direction to be 19° above the horizontal.
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 Example 2.1 Adding Vectors

Solution
(b) Consider the parallelogram rule:
Since  + 30° = 180°,  = 150°
Applying law of cosines to shaded triangle:

2 2 2
FAB  FAC  FAB  FAC  2 FAB FAC cos α
2 2
100   60   2100 60 cos150
Magnitude |FAB + FAC| = 155 kN

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 Example 2.1 Adding Vectors

Solution
(b) To determine the angle  between FAB + FAC
& the horizontal, apply law of sines to shaded
triangle: sin  sin α

FAB FAB  FAC

The solution is
 FAB sin α   100 sin 150 
β arcsin   arcsin   18.8
 FAB  FAC   155 

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 A person in a wheelchair is moving up a ramp at constant speed. Their
total weight is 900 N. The ramp makes an angle of 10º with the horizontal.
Calculate the force required to keep the wheelchair moving at constant
speed up the ramp. (You may ignore the effects of friction).

Solution:
If the wheelchair is moving at constant speed (no acceleration), then the force that moves it up
the ramp must be the same as the component of it’s weight parallel to the ramp.

Complete the parallelogram.
Component of weight 28 N
156. 10º
parallel to ramp:
900Sin10 156.28 N 80º 10º

Component of weight
perpendicular to ramp: 886.33 N
900 N
900Cos10 886.33 N
 2.4 Components in 3 Dimensions
Review of drawing objects in 3 dimensions:
(a) A cube viewed with the line of sight
perpendicular to a face
(b) An oblique view of the cube
(c) A cartesian coordinate system aligned with
the edges of the cube
(d) 3-D representation of the coordinate system

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 2.4 Components in 3 Dimensions
Right-handed coordinate system:

 Express vector U in terms of vector
components Ux, Uy & Uz parallel to the x, y & z
axes respectively:
U = Ux + Uy + Uz (2.11)
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 2.4 Components in 3 Dimensions
 Introducing unit vectors i, j & k that point in the
positive x, y & z directions, U can be expressed
in terms of scalar components:

U = Uxi + Uyj + Uz k (2.12)

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 2.4 Components in 3 Dimensions
Direction Cosines:

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 2.4 Components in 3 Dimensions
Direction Cosines:
 Direction cosines: cos x, cos y & cos z
 Direction cosines satisfy the relation:
cos2 x + cos2 y + cos2 z = 1 (2.16)
 Suppose that e is a unit vector with the same
direction as U:
U = |U| e
 In terms of components:

Uxi + Uyj + Uzk = |U| (exi + eyj + ezk)

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 2.4 Components in 3 Dimensions
Position Vectors in Terms of Components:
 Consider point A with
coordinates (xA, yA, zA) &
point B with coordinates
(xB, yB, zB)

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 2.4 Components in 3 Dimensions
Position Vectors in Terms of Components:
 The position vector rAB from A
to B:
rAB = (xB  xA)i + (yB  yA)j + (zB  zA)k (2.17)

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 Example 2.6 Magnitude & Direction Cosines
of a Vector
The coordinates of point C of the truss in Fig. 2.26
are xC = 4 m, yC = 0, zC = 0 & the coordinates of
point D are xD = 2 m, yD = 3 m, zD = 1 m. Let rCD be
the position vector from C to D.

(a) What is the magnitude of rCD?

Fig. 2.26
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 Example 2.6 Magnitude & Direction
Cosines of a Vector
Strategy
(a) We can obtain the components of rCD by
subtracting the coodinates of C from the
coordinates of D

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 Example 2.6 Magnitude & Direction
Cosines of a Vector
Solution
(a) The components of rCD are given by:
rCD = (xD  xC)i + (yD  yC)j + (zD  zC)k
= (2  4) i + (3  0)j + (1  0)k
= 2i + 3j + k

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 Example 2.6 Magnitude & Direction
Cosines of a Vector
Solution
(a) The magnitude of rCD is:

rCD  rCD 2x  rCD 2y  rCD 2z
2 2 2
    
  2 m  3 m  1m 
3.74 m

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 2.5 Dot Products
Definition:
 Consider 2 vectors U & V:
 Denoted by U∙V
 Defined to be the product of the
magnitude of U, the magnitude
of V & the cosine of the angle 
between U & V when they are
placed tail to tail
U∙V = |U||V| cos  (2.18)

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 2.5 Dot Products
Definition:
 Result is a scalar
 sometimes called
scalar product
 Unit = product of the
units of the 2 vectors

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 2.5 Dot Products
 Notice that the dot product of two nonzero
vectors = 0 if & only if the vectors are
perpendicular
 The dot product is commutative:

U∙V = V∙U (2.19)

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 2.5 Dot Products
 The dot product is associative with respect to
scalar multiplication:
a(U∙V) = (aU)∙V = U∙ (aV) (2.20)

 The dot product is associative with respect to
vector addition:
U∙ (V + W) = U∙V + U∙W (2.21)

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 2.5 Dot Products
Dot Products in Terms of Components:
 Determine the dot products formed from the
unit vectors i, j & k:
i∙i = |i||i| cos (0) = (1)(1)(1) = 1
i∙j = |i||j| cos (90°) = (1)(1)(0) = 0
 Continuing this way:

i∙i = 1, i∙j = 0, i∙k = 0,
j∙i = 0, j∙j = 1, j∙k = 0,
k∙i = 0, k∙j = 0, k∙k = 1. (2.22)
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 2.5 Dot Products
 Dot product of U & V expressed in terms of
their components:
U∙V = (Uxi + Uyj + Uzk) ∙ (Vxi + Vyj + Vzk)
= UxVx(i∙i) + UxVy(i∙j) + UxVz(i∙k)
+ UyVx(j∙i) + UyVy(j∙j) + UyVz(j∙k)
+ UzVx(k∙i) + UzVy(k∙j) + UzVz(k∙k)
 Substituting Eqs. (2.22):
U∙V = UxVx + UyVy + UzVz (2.23)

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 2.5 Dot Products
 Equate the expression for dor product given by
Eq. (2.23) to the definition of dot product, Eq.
(2.18) to solve for cos  :
U V U xVx  U yV y  U zVz
cos θ  
UV UV (2.24)

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 Example 2.12 Using the Dot Product to
Determine an Angle
What is the angle  between the lines AB & AC
in Fig. 2.35?

Fig. 2.35

Strategy
Coordinates of A, B & C  components of
vector rAB & rAC
Use Eq. (2.24) to determine 
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 Example 2.12 Using the Dot Product to
Determine an Angle
Solution
Vectors rAB & rAC :
rAB = (6  4) i + (1  3)j + (2  2)k
= 2i  2j  4k (m)
rAC = (8  4) i + (8  3)j + (4  2)k
= 4i + 5j + 2k (m)
Magnitudes: 2
rAB  2 m    2 m 2   4 m 2 4.90 m
rAC  4 m 2  5 m 2  2 m 2 6.71 m
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 Example 2.12 Using the Dot Product to
Determine an Angle
Solution
Dot product of rAB & rAC :
rAB∙rAC = (2 m) (4 m) + (2 m) (5 m) + (4 m) (2 m)
= 10 m2
Therefore, 2
rAB rAB  10 m
cos    0.304
rAB rAC 4.90 m 6.71 m 
 arccos 0.304 107.7

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 2.6 Cross Products
Definition:
 Consider 2 vectors U & V:
 Denoted by U V
 Defined by:

U  V = |U||V| sin  e (2.28)

where  = angle between U & V
e = unit vector defined to be
perpendicular to both U & V

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 2.6 Cross Products
Definition:
 U,V & e are defined to be a right-
handed system
Right-hand rule

 Result is a vector  sometimes called
vector product

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 2.6 Cross Products
 Unit = product of the units of the 2 vectors
 Notice that the cross product
of 2 nonzero vectors = 0 if &
only if the vectors are parallel
 The dot product is not
commutative:
U  V = V  U (2.29)

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 2.6 Cross Products
The dot product is associative
with respect to scalar multiplication:

a(U  V) = (aU)  V = U  (aV) (2.30)

The dot product is distributive
with respect to vector addition:

U  (V + W) = (U  V) + (U  W) (2.31)

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 2.6 Cross Products
Cross Products in Terms of Components:
 Determine the cross products formed from the
unit vectors i, j & k:
i  i = |i||i| sin (0) e = 0
i  j = |i||j| sin (90°) e = e
e = unit vector perpendicular to i & j

e = k or e = k

Applying right-hand rule, e = k

ij=k

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 2.6 Cross Products
 Continuing this way:
i  i = 0, i  j = k, i  k = j,
j  i = k, j  j = 0, j  k = i,
k  i = j, k  j = i, k  k = 0. (2.32)
These results can be easily remembered

by arranging the unit vectors in a circle:

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 2.6 Cross Products
 Cross product of U & V expressed in terms of
their components:
U  V = (Uxi + Uyj + Uzk)  (Vxi + Vyj + Vzk)
= UxVx(i  i) + UxVy(i  j) + UxVz(i  k)
+ UyVx(j  i) + UyVy(j  j) + UyVz(j  k)
+ UzVx(k  i) + UzVy(k  j) + UzVz(k  k)

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 2.6 Cross Products
 Substituting Eqs. (2.32):
U  V = (UyVz  UzVy)i (UxVz UzVx)j
+ (UxVy UyVx)k
(2.33)
 This result can be compactly written as the
determinant:
Ux Uy Uz
U V  V x Vy Vz
Wx Wy Wz
(2.34)

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 2.6 Cross Products
Evaluating a 3  3 Determinant:
 Repeat its first 2 columns & evaluate the
products of the terms along the 6 diagonal
lines
i j k i j
Ux Uy UzUx Uy
Vx Vy Vz Vx Vy
() () () (+) (+) (+)

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 2.6 Cross Products
 Value of the determinant:

i j k
U yV zi  U zV xj  U xV yk
Ux Uy Uz 
 U yV xk  U zV yi  U xV zj
Vx Vy Vz

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 2.6 Cross Products
 Alternatively:

i j k
Uy Uz Ux Uz Ux Uy
U x U y U z i  j k
Vy Vz Vx Vz Vx Vy
Vx Vy Vz

U yV z U zV y i  U xV z U zV x j
 U xV y U yV x k

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 2.7 Mixed Triple Products
Definition: U∙ (V  W)
(2.35)
 In terms of scalar components: i j k
U V W  U x i  U y j  U z k V x Vy Vz
Wx Wy Wz
U x i  U y j  U z k [V yWz  VzWy i
 VxWz  VzWx j  VxWy  V yWx k ]
U x V yWz  VzWy  U y VxWz  VzWx 
 U z VxWy  V yWx 
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 2.7 Mixed Triple Products
 This result can be expressed as the
determinant:
Ux Uy Uz
U V W   V x V y V z
(2.36)
Wx Wy Wz
 Interchanging any 2 vectors in the mixed
triple product changes the sign but not the
absolute value of the result
E.g. U∙ (V  W) = W∙ (V  U)

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 (submission as an Assignment)

Physics for Scientist and Engineers.
Fundamental problems
Chapter 01
Do Problem 25-35
Chapter 03
Pb 18-21
Pb 33-37,53
All problem done so far in lect.)
Due date 7x days.

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