Vector Calculus PDF

Summary

This document provides a lecture on vector calculus by Dr. Ehab Said covering various topics including scalars, vectors, vector diagrams, and problems, ideal for an undergraduate course in mathematics or engineering.

Full Transcript

Vector Calculus
By
Dr. Ehab Said
 Objectives:

1) Define scalars and vectors

2) Represent the vector symbolically

3) Introduce the notion of unit vectors

4) Understand Scalar product

5) Understand Vector product
 SCALARS AND VECTORS
I. Scalars
 A scalar quantity is a quantity that has magnitude only and has no direction in space

Examples of Scalar Quantities:
F
P=
A
 Distance
 Time
 Mass
 Pressure
 Temperature
 Density
 II. Vectors
 A vector quantity is a quantity that has both magnitude and a direction in space

Examples of Vector Quantities:
 Displacement
 Velocity
 Acceleration
 Force
 Vector Diagrams

 Vector diagrams are shown using an
arrow in 2D and 3D z
 The length of the arrow represents its k
magnitude y
 The direction of the arrow shows its j
i
direction x

a = a1 i + a2 j =  a1 , a2 , a = a12 + a2 2 r = x i + y j + z k =  x, y, z , r = x 2 + y 2 + z 2
 Example: Practical Applications

 Here we see a table being pulled by a
force of 50 N at a 30º angle to the
horizontal y=25 N
3 30º
Fx = 50 Cos 30 = 50 =43.3 N
2 x=43.3 N

50
Fy = 50Sin 30 = =25 N
2
 We can see that it would
 When resolved we see that this is the be more efficient to pull
the table with a horizontal
same as pulling the table up with a force force of 50 N
of 25 N and pulling it horizontally with a
force of 43.3 N F = 43.3 i + 25 j
 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
y=v Sin θ
 y = v Sin θ y
θ
x
x=v Cos θ
 Proof:
x y
Cos = Sin =
v v
x = vCos y = vSin
Example: 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:

N
Vertical 12.99
Horizontal Component = x = 15Cos 60 = 7.5 N

Component
Vertical Component = y = 15Sin60 = 12.99 N
60º
Then F = 7.5 i + 12.99 j Horizontal
7.5 N
Component
 Unit Vectors
 A unit vector is a vector of length 1.
 They are used to specify a direction.
 By convention, we usually use i, j and k to represent the unit vectors in the x, y
and z directions, respectively (in 3 dimensions).
 i= points along the positive x-axis
z
 j= points along the positive y-axis
k
 k= points along the positive z-axis
y
 Unit vectors for various coordinate systems: j
i
 Cartesian: i, j, and k x

 Cartesian: we may choose a different set of
 unit vectors, e.g. we can rotate i, j, and k
 Unit Vectors

To find a unit vector, â , in an arbitrary direction, for example, in the
direction of vector a, where a=, divide the vector by its
magnitude (this process is called normalization).

a a  a1 , a2 
aˆ = = =
a a +a
2
1
2
2 a12 + a22

Example: If a=, then is a unit vector in the same
direction as a.
Position Vectors
1) Find the magnitude of v = i + 4j.

2) Find the magnitude of the vector A = 2i – 5j + 4k, using vector algebra.

3) A ball is thrown with an initial velocity of 70 feet per second, at an angle of 35° with
the horizontal. Find the vertical and horizontal components of the velocity.
 Scalar Product of Two Vectors in 3D
 If A & B are vectors, their Scalar Product is defined as:

A B ≡ AB cosθ

 In terms of vector components & unit vectors i, j, k are along the x, y ,z axes:

A = Axi + Ayj + Azk B = Bxi + Byj + Bzk

 Using i i = j j = k k = 1, i j= i k = j k = 0 gives

A B = AxBx + AyBy + AzBz

 Dot Product clearly a SCALAR.
 The condition of perpendicularity
 Given two nonzero vectors

a = a1, a2, a3 and b = b1, b2, b3,

we can say that the vector a perpendicular to b if and only if

A B ≡ AB cos(π/2)=AB (0) b

ab=0 a

a1b1 + a2b2 + a3b3 = 0
ˆi  ˆj = ˆi  kˆ = ˆj  kˆ = 0
 Note that: ˆi  ˆi = ˆj  ˆj = kˆ  kˆ = 1
1) Find the scalar product of vector A= 2i + 5j +3k and vector B= 3i + j +2k.

2) A particle covers a displacement from position 2i + j + 2k to 3i + 2j +5k due to uniform
force of ( 7i + 5j +2k) N. If the displacement is in mitres calculate the work done.

3) Find the value of m such that vectors A = 2 i + 3j + k and B = 3 i + 2 j + mk may be
perpendicular.
 Cross or Vector Product
+ − + A  B = A B sin  nˆ
ˆi ˆj kˆ
→ Ay Az A Ay
C = A  B = Ax Ay Az == ˆi − Ax Az ˆj + x kˆ
By Bz Bx Bz Bx By
Bx By Bz

= ( Ay Bz − Az By ) ˆi − ( Ax Bz − Az Bx ) ˆj + ( Ax By − Ay Bx ) kˆ
y
 The cross product of two vectors says something about how i
perpendicular they are: j i
  x
 Magnitude: →
C = A  B = AB sin  j k z k

  is smaller angle between the vectors
 Cross product of any parallel vectors = zero
 Cross products of Cartesian unit vectors: n̂

iˆ  ˆj = kˆ; iˆ  kˆ = − ˆj; ˆj  kˆ = iˆ
iˆ  iˆ = 0; ˆj  ˆj = 0; kˆ  kˆ = 0
 The condition of parallelism

 Since a vector is completely determined by its magnitude and direction, we can
now say that a  b is the vector that is perpendicular to both a and b, whose
orientation is determined by the right-hand rule, and whose length is
| a | | b |sin (θ)= | a | | b |sin (0)= | a | | b |(0)
 The two nonzero vectors a and b are parallel if and only if
ab=0
Note that:
ˆi  ˆi = ˆj  ˆj = kˆ  kˆ = 0
ˆi  ˆj = kˆ , ˆj  kˆ = ˆi , kˆ  ˆi = ˆj
 Example

 Given A = 2ˆi + 3ˆj; B = − ˆi + 2ˆj

 Find A B

 Solution:
ˆi ˆj kˆ
A B = 2 3 0 = ˆi(0 − 0) − ˆj(0 − 0) + kˆ (4 − ( −3))
−1 2 0

= 7 kˆ
Example

 If a = 1, 3, 4 and b = 2, 7, –5, then

= (–15 – 28)i – (–5 – 8)j + (7 – 6)k

= –43i + 13j + k
Problems
1) Prove that vectors U = 2i + 3j + k and V = 4i – 2j + 2k are perpendicular to each other.

2) Two vectors are given by, a = 2i + j + k and b = i + j + k. Find the dot product of these
two vectors.

3) Two vectors are given by, a = 2i + j + k and b = i + j + k. Find the cross product of these
two vectors.
1) Two vectors are given by, a = i + j + k and b = i – 2j + 3k. Find the dot product of these
two vectors.

2) Two vectors are given by, a = 4i +2 j +2 k and b = 2i + 2j + 2k. Find the cross product of
these two vectors.
1) Two vectors are given by, a = 2i + j + k and b = i + j + k. Find the cross product of these
two vectors.

2) A and B are two perpendicular vectors given by A =5i+10j−3k and B =2i+4j−ck. The
value of c is:
1) The angle between two vectors P =3i+2j​+3k and Q ​=2i−j​+3k is:

2) Let’s say A = 4i + 3j and B = 5i + 4j. Find the resultant vector from the addition of these
two vectors.

3) Let’s say A = 5i + 5j and B = 3i + 3j. Find the resultant vector from the addition of these
two vectors.