Embed Size (px)
Citation preview
1
Topic 3 - Basic EM Theory and Plane Waves
EE 542Antennas & Propagation for Wireless Communications
O. Kilic EE542
2
Outline
• EM Theory Concepts
• Maxwell’s Equations– Notation
– Differential Form
– Integral Form
– Phasor Form
• Wave Equation and Solution (lossless, unbounded, homogeneous medium)
– Derivation of Wave Equation
– Solution to the Wave Equation – Separation of Variables
– Plane waves
O. Kilic EE542
3
EM Theory ConceptThe fundamental concept of em theory is that a
current at a point in space is capable of inducing potential and hence currents at another point far away.
J
E, H
O. Kilic EE542
4
Introduction to EM Theory
• The existence of propagating em waves can be predicted as a direct consequence of Maxwell’s equations.
• These equations satisfy the relationship between the vector electric field, E and vector magnetic field, H in time and space in a given medium.
• Both E and H are vector functions of space and time; i.e. E (x,y,z;t), H (x,y,z;t.)
O. Kilic EE542
5
What is an Electromagnetic Field?
• The electric and magnetic fields were originally introduced by means of the force equation.
• In Coulomb’s experiments forces acting between localized charges were observed.
• There, it is found useful to introduce E as the force per unit charge.
• Similarly, in Ampere’s experiments the mutual forces of current carrying loops were studied.
• B is defined as force per unit current.
O. Kilic EE542
6
Why not use just force?
• Although E and B appear as convenient replacements for forces produced by distributions of charge and current, they have other important aspects.
• First, their introduction decouples conceptually the sources from the test bodies experiencing em forces.
• If the fields E and B from two source distributions are the same at a given point in space, the force acting on a test charge will be the same regardless of how different the sources are.
• This gives E and B meaning in their own right.• Also, em fields can exist in regions of space where there
are no sources.
O. Kilic EE542
7
Maxwell’s Equations
• Maxwell's equations give expressions for electric and magnetic fields everywhere in space provided that all charge and current sources are defined.
• They represent one of the most elegant and concise ways to state the fundamentals of electricity and magnetism.
• These set of equations describe the relationship between the electric and magnetic fields and sources in the medium.
• Because of their concise statement, they embody a high level of mathematical sophistication.
O. Kilic EE542
8
Notation: (Time and Position Dependent Field Vectors)
E (x,y,z;t) Electric field intensity (Volts/m)
H (x,y,z;t) Magnetic field intensity (Amperes/m)
D (x,y,z;t) Electric flux density (Coulombs/m2)
B (x,y,z;t) Magnetic flux density (Webers/m2, Tesla)
O. Kilic EE542
9
Notation: Sources and Medium
J (x,y,z;t) Electric current density (Amperes/m2)
Jd (x,y,z;t) Displacement current density (Amperes/m2)
e Electric charge density (Coulombs/m3)
r
Permittivity of the medium (Farad/m)Relative permittivity (with respect to free space o)
r
Permeability of the medium (Henry/m)Relative permittivity (with respect to free space o)
Conductivity of the medium (Siemens/m)
O. Kilic EE542
10
Maxwell’s Equations – Physical Laws
• Faraday’s Law Changes in magnetic field induce voltage.
• Ampere’s Law Allows us to write all the possible ways that electric currents can make magnetic field. Magnetic field in space around an electric current is proportional to the current source.
• Gauss’ Law for Electricity The electric flux out of any closed surface is proportional to the total charge enclosed within the surface.
• Gauss’ Law for Magnetism The net magnetic flux out of any closed surface is zero.
O. Kilic EE542
11
Differential Form of Maxwell’s Equations
-t
BE =
; ;d s ct t
D DH = J J J = J J
vD=
0B=
Faraday’s Law:
Ampere’s Law:
Gauss’ Law:
(1)
(2)
(3)
(4)
O. Kilic EE542
12
Constitutive RelationsConstitutive relations provide information
about the environment in which electromagnetic fields occur; e.g. free space, water, etc.
D= E
B= H9
7
10
364 10
o
o
Free space values.
(5)
(6)
permittivity
permeability
O. Kilic EE542
13
Time Harmonic Representation - Phasor Form
• In a source free ( ) and lossless ( ) medium characterized by permeability and permittivity , Maxwell’s equations can be written as:
0sJ
0 0cJ
-
;
0
0
t
t
HE =
EH =
D=
B=
O. Kilic EE542
14
Examples of del Operations
• The following examples will show how to take divergence and curl of vector functions
O. Kilic EE542
15
Example 1
ˆ sin ; sin( ) sin(2 )
Find:
a) the curl of A
b) the divergence of A
c) the gradient of
Let A y x x y
A
A
O. Kilic EE542
16
Solution 1
ˆ ˆ ˆ ˆ sin
ˆ cos
ˆ ˆ ˆ ˆ sin 0
sin( ) sin(2 ) sin( ) sin(2 ) sin( ) sin(2 )ˆ ˆ ˆ
ˆ ˆcos( ) sin(2 ) 2sin( ) cos(2 )
A x y z y xx y z
z x
A x y z y xx y z
x y x y x yx y z
x y z
x x y y x y
O. Kilic EE542
17
Example 2
Calculate the magnetic field for the electric field given below. Is this electric field realizable?
ˆ ˆ, , ; ) 5 cos( )
ox y z t x xy yz wtE(
O. Kilic EE542
18
Solution
-
ˆ ˆ5 cos( )
ˆ ˆ ˆ ˆˆ 5 cos( )
5ˆ ˆ ˆ ˆcos( ){
5ˆ ˆ ˆ ˆ
5ˆ ˆˆ ˆ }
ˆ5 cos( ) -
o
o
o
o
t
x xy yz wt
x y z x xy yz wtx y z
xy zwt x x x y
x xxy z
y x y yy y
xy zz x z y
z y
x wt zt
HE =
H=
O. Kilic EE542
19
Solution continued
5ˆcos( )
5ˆ cos( )
5ˆsin( )
o
o
o
x wt zt
xz wt
xz wt
w
H
H =
O. Kilic EE542
20
Solution continued
t
? EH =
To be realizable, the fields must satisfy Maxwell’s equations!
O. Kilic EE542
21
Solution Continued
5ˆsin( )
5ˆ sin( )
ˆ ˆ5 cos( )
ˆ ˆsin( ) 5
5ˆ ˆ ˆsin( ) sin( ) 5
o
o
o
o
o o
xz wt
w
y wtw
x xy yz wt
t tw wt x xy yz
y wt w wt x xy yzw
H =
E
These fields are NOT realizable. They do not form em fields.
O. Kilic EE542
22
Time Harmonic Fields• We will now assume time harmonic fields; i.e.
fields at a single frequency. • We will assume that all field vectors vary
sinusoidally with time, at an angular frequency w; i.e.
ˆ, , ; ) ( , , )cos( )
o ox y z t e x y z wtE( E
O. Kilic EE542
23
Time Harmonics and Phasor Notation
( ) cos( ) sin( )j wte wt j wt
Using Euler’s identity
The time harmonic fields can be written as
ˆ, , ; ) Re ( , , )
ˆRe ( , , )
o
o
j wt
o
j jwt
o
x y z t e x y z e
e x y z e e
E( E
EPhasor notation
O. Kilic EE542
24
( , , ; ) Re ( , , )
( , , ; ) Re ( , , )
where
ˆ( , , ) ( , , )
ˆ( , , ) ( , , )
o
o
jwt
jwt
j
o
j
o
x y z t E x y z e
x y z t H x y z e
E x y z e x y z e
H x y z h x y z e
E
H
E
H
Note that the E and H vectors are now complex and are known as phasors
Phasor Form
Information on amplitude, direction and phase
O. Kilic EE542
25
Time Harmonic Fields in Maxwell’s Equations
With the phasor notation, the time derivative in Maxwell’s equations becomes a factor of jw:
( , , ; ) Re ( , , )
( , , ; )Re ( , , )
Re ( , , )
jwt
jwt
jwt
jw
x y z t E x y z e
x y z tE x y z e
t t
jwE x y z e
t
E
E
O. Kilic EE542
26
Maxwell’s Equations in Phasor Form (1)
( , , ; ) Re ( , , )
( , , ; ) Re ( , , )
Re ( , , )
Re ( , , )Re ( , , )
jwt
jwt
jwt
jwt
jwt
x y z t E x y z e
x y z t H x y z e
H x y z e
E x y z ejwE x y
t
z et t
E
H
H =
E
EH =
O. Kilic EE542
27
Maxwell’s Equations in Phasor Form (2)
Re ( , , )
Re ( , , )Re ( , , )
Re ( , , ) R
(
e ( , , )
, , ) ( , , )
jwt
jwt
jwt
jwt jwt
H x y z e
E x y z ejwE x y z e
t
t
H x y z
t
H x y z e jwE
jw E
x y
z
z
x y
e
EH =
H =
E
O. Kilic EE542
28
Phasor Form of Maxwell’s Equations (3)
Maxwell’s equations can thus be written in phasor form as:
-
0
0
E jw H
H jw E
D
B
=
=
=
=
Phasor form is dependent on position only. Time dependence is removed.
-
;
0
0
t
t
HE =
EH =
D=
B=
O. Kilic EE542
29
Examples on Phasor Form
Determine the phasor form of the following sinusoidal functions:
a) f(x,t)=(5x+3) cos(wt + 30)
b) g(x,z,t) = (3x+z) sin(wt)
c) h(y,z,t) = (2y+5)4z sin(wt + 45)
d) V(t) = 0.5 cos(kz-wt)
O. Kilic EE542
30
Solutions
30
30
30
( , ) Re ( )
5 3 cos( 30)
5 3 Re
Re 5 3
( ) 5 3 5 3 cos30 sin30
jwt
j wt
j jwt
j
f x t F x e
x wt
x e
x e e
F x x e x j
a)
O. Kilic EE542
31
Solutions
90
90
90
90
( , , ) (3 ) sin( )
(3 ) cos( 90)
(3 )Re
Re (3 )
Re (3 )
( , ) (3 ) (3 )
j wt
j wt
j jwt
j
g x z t x z wt
x z wt
x z e
x z e
x z e e
G x z x z e j x z
b)
O. Kilic EE542
32
Solution
( 45)
45 ( )
45
( , , ) (2 5)4 sin( 45)
(2 5)4 cos( 45 90)
(2 5)4 cos( 45)
(2 5)4 Re
Re (2 5)4
( , ) (2 5)4
(2 5)4 cos45 sin45
j wt
j j wt
j
h y z t y z wt
y z wt
y z wt
y z e
y ze e
H y z y ze
y z j
c)
O. Kilic EE542
33
Solution
( ) 0.5cos( )
0.5Re Re 0.5
0.5
jkz jwt jkz jwt
jkz
v t kz wt
e e e
V e
d)
O. Kilic EE542
34
Example
• Find the phasor notation of the following vector:
( ) ( )
where
ˆ ˆ( ) 3cos( ) 4sin( ) 8 cos sin
C t E tt
E t wt wt x wt wt z
O. Kilic EE542
35
Solution
ˆ( ) 3 sin 4 cos
ˆ8 sin( ) cos
Using
sin Re
cos Re
ˆ( ) Re 3 4
ˆRe 8 8
ˆ ˆ3 4 8 8
jwt
jwt
jwt jwt
jwt jwt
EC t w wt w wt x
tw wt w wt z
wt je
wt e
C t w je w e x
w je w e z
C wj w x wj w z
O. Kilic EE542
36
Example
• Show that the following electric field satisfies Maxwell’s equations.
ˆ jkzoE xE e
O. Kilic EE542
37
Solution
?
ˆ
1ˆ ˆ
ˆ
1ˆ ;
1 1ˆ
1ˆ( )
ˆ ˆ
jkzo
jkz jkzo o
jkzo
jkzo
jkzo
jkzo
jkz jkzo o
E xE e
wkB E yE e yE e
jw w w
yE e
EH B y e
EE H y e
jw jw
Ejk x e
jw
kxE e xE e
w
O. Kilic EE542
38
The Wave Equation (1) If we take the curl of Maxwell’s first equation:
E jw H
Using the vector identity:
2A A A
0eq J
0
0E
And assuming a source free, i.e. and lossless;
medium:
; ; 0
d d s ct
DH = J J J J = J J
i.e.
O. Kilic EE542
39
The Wave Equation (2)
2 2( ) ( )E r w E r
2 2k w
2 2( , , ) ( , , ) 0E x y z k E x y z
Define k, which will be known as wave number:
O. Kilic EE542
40
Wave Equation in Cartesian Coordinates
2 2 22
2 2 2
ˆ ˆ ˆ( , , ) ( , , ) ( , , ) ( , , )
andx y zE x y z x E x y z y E x y z z E x y z
x y z
2 2( , , ) ( , , ) 0 E x y z k E x y z
where
O. Kilic EE542
41
Laplacian2 2
2 2 2
2 2 2
2 2 2
2 2 2
2 2 2
2 2 2
2 2 2
ˆ ˆ ˆ( , , ) ( , , ) ( , , ) ( , , )
ˆ ˆ ˆ( , , ) ( , , ) ( , , )
ˆ
ˆ
ˆ
x y z
x y z
x x x
y y y
z z z
E x y z x E x y z y E x y z z E x y z
x E x y z y E x y z z E x y z
E E Ex
x y z
E E Ey
x y z
E E Ez
x y z
O. Kilic EE542
42
Scalar Form of Maxwell’s Equations
22
2
ˆ ˆ ˆ( ) ( ) ( )
Ek E
x
E x f x y g x z h x
Let the electric field vary with x only.
and consider only one component of the field; i.e. f(x).
22
2
x
fk f
x
O. Kilic EE542
43
Possible Solutions to the Scalar Wave Equation
1 2
1 1
( ) traveling wave
or
( ) cos( ) sin( ) standing wave
jkx jkxf x Ae A e
f x C kx D kx
Standing wave solutions are appropriate for bounded propagation such as wave guides.
When waves travel in unbounded medium, traveling wave solution is more appropriate.
Energy is transported from one point to the other
O. Kilic EE542
44
The Traveling Wave• The phasor form of the fields is a mathematical
representation.• The measurable fields are represented in the time domain.
1 1 1;
jkx jE Ae A A e
1 1
( , , ; ) Re ( , , )
ˆRe cos
jwt
jkx jwt
x y z t E x y z e
Ae e x A wt kx
EThen
Let the solution to the -component of the electric field be:
Traveling in +x direction
O. Kilic EE542
45
Traveling Wave
-1.5
-1
-0.5
0
0.5
1
1.5
-4 -3 -2 -1 0 1 2 3 4
kx
E(x
,y,z
;t)
wt = 0 wt = PI/2
As time increases, the wave moves along +x direction
( , , ; ) cos x y z t wt kxE
O. Kilic EE542
46
Standing Wave
1 1 1cos( ); jE C kx C C e
1 1
( , , ; ) Re ( , , )
ˆRe cos( ) cos cos( )
jwt
jwt
x y z t E x y z e
C kx e x C wt kx
E
Then, in time domain:
O. Kilic EE542
47
-1.5
-1
-0.5
0
0.5
1
1.5
-4 -3 -2 -1 0 1 2 3 4
kx
E(x
,y,z
;t)
wt = 0 wt = PI/2 wt = -PI/2 wt = PIwt = PI/4 wt = 3PI/4 wt = 5PI/8 wt = 3PI/8
Standing WaveStationary nulls and peaks in space as time passes.
O. Kilic EE542
48
To summarize
• We have shown that Maxwell’s equations describe how electromagnetic energy travels in a medium
• The E and H fields satisfy the “wave equation”.
• The solution to the wave equation can be in various forms, depending on the medium characteristics
O. Kilic EE542
49
The Plane Wave Concept
• Plane waves constitute a special set of E and H field components such that E and H are always perpendicular to each other and to the direction of propagation.
• A special case of plane waves is uniform plane waves where E and H have a constant magnitude in the plane that contains them.
O. Kilic EE542
50
Plane Wave Characteristics
1ˆ( , , ; ) cos
x y z t A wt kx eE
amplitudeFrequency (rad/sec)
Wave number, depends on the medium characteristics
phase
Direction of propagation
polarization
1ˆ( , , ; ) cos ;
x y z t A e wt kzE
amplitude phase
O. Kilic EE542
51
Plane Waves in Phasor Form
1
1
0
ˆ( , , ; ) cos
ˆ( , , )
ˆ
j jkx
jkx
x y z t A wt kx e
E x y z A e e e
E e e
E
Complex amplitude Position dependence
polarization
O. Kilic EE542
52
Example 1Assume that the E field lies along the x-axis (i.e. x-
polarized) and is traveling along the z-direction.
1
ˆ-
jkzo
o
EH E y e
jw
We derive the solution for the H field from the E field using Maxwell’s equation #1:
ˆ jkzoE xE e
Intrinsic impedance; 377 for free space
wave number
Note the I = V/R analogy in circuit theory.
EH
2 2k w
O. Kilic EE542
53
Example 1 (2 of 4)
( , , ) ( )
( , , ) ( )
E x y z E z
H x y z H z
direction of propagation
x
y
z
E, H plane
E and H fields are not functions of x and y, because they lie on x-y plane
O. Kilic EE542
54
Example 1 (3 of 4)
ˆ cos( )
ˆ cos( )
o
o
o
x E wt kz
Ey wt kz
E
H
phase term
*** The constant phase term is the angle of the complex number Eo
In time domain:
O. Kilic EE542
55
Wavelength: period in spacek = 2
Example 1 (4 of 4)
w
O. Kilic EE542
56
Velocity of Propagation (1/3)
• We observe that the fields progress with time.
• Imagine that we ride along with the wave.
• At what velocity shall we move in order to keep
up with the wave???
O. Kilic EE542
57
Velocity of Propagation (2/3)
-1
-0.8
-0.6
-0.4
-0.2
0
0.2
0.4
0.6
0.8
1
-4 -3 -2 -1 0 1 2 3 4
z
Ex
wt = 0 wt = PI/2 wt = PI
constantwt kz a
dz d wt av
dt dt k
wv
k
Constant phase points
E field as a function of different times
ˆ cos( )ox E wt kz
E
kz
O. Kilic EE542
58
Velocity of Propagation (3/3)
1
dz wv
dt k
k w
wv
k
In free space:
9
7
8
1
10 F/m
364 10 H/m
c 3 10 m/s
fs
o o
o
o
v c
Note that the velocity is independent of the frequency of the wave, but a function of the medium properties.
O. Kilic EE542
59
Example 2
A uniform em wave is traveling at an angle with respect to the z-axis as shown below. The E field is in the y-direction. What is the direction of the H field?
x
zy
k
E
O. Kilic EE542
60
Solution: Example 2
ˆ ˆ ˆcos sink z x
x
zy
k
The E field is along y
The direction of propagation is the unit vector
Because E, H and the direction of propagation are perpendicular to each other, H lies on x-z plane. It should be in the direction parallel to:
ˆ ˆ ˆ ˆ ˆ/ / sin cosh k y z x
E
O. Kilic EE542
61
Example 3
Write the expression for an x-polarized electric field that propagates in +z direction at a frequency of 3 GHz in free space with unit amplitude and 60o phase.
1ˆ( , , ; ) cos
x y z t A wt kz eE
=1W = 2f =
2*3*109
o ow 60o
x
+ z-direction
O. Kilic EE542
62
Solution 3
1ˆ( , , ; ) cos
x y z t A wt kz eE
=1W = 2f =
2*3*109
o ow 60o
x
+ z-direction
O. Kilic EE542
63
Example 4If the electric field intensity of a uniform plane wave
in a dielectric medium where = or and = o is given by:
Determine:• The direction of propagation and
frequency• The velocity• The dielectric constant (i.e. permittivity)• The wavelength
9 ˆ377cos(10 5 )t y z
E
O. Kilic EE542
64
Solution: Example 4 (1/2)
1. +y direction; w = 2f = 109
2. Velocity:
3. Permittivity:
9810
2 10 m/s5
wv
k
81 1 3 10
o r o r r
cv
88 3 10 9
2 10 2.254r
r
v
O. Kilic EE542
65
Solution: Example 4 (2/2)
4. Wavelength:
2 25k
m
O. Kilic EE542
66
Example 5Assume that a plane wave propagates along +z-
direction in a boundless and a source free, dielectric medium. If the electric field is given by:
Calculate the magnetic field, H.
ˆ ˆ( ) jkzx oE E z x E e x
O. Kilic EE542
67
Example 5 - observations
• Note that the phasor form is being used in the notation; i.e. time dependence is suppressed.
• We observe that the direction of propagation is along +z-axis.
O. Kilic EE542
68
Solution: Example 5 (1/2)
ˆ ˆo oE EH y y
Intrinsic impedance, I = V/R
E
k
O. Kilic EE542
69
Solution: Example 5 (2/2)
• E, H and the direction of propagation are orthogonal to each other.
• Amplitudes of E and H are related to each other through the intrinsic impedance of the medium.
• Note that the free space intrinsic impedance is 377
O. Kilic EE542
70
Example 6
Sketch the motion of the tip of the vector A(t) as a function of time.
ˆ ˆA x jy
O. Kilic EE542
71
Solution: Example 6 (1/2)
2
( ) Re
ˆ ˆ ˆ ˆRe Re
ˆ ˆcos( ) cos( )2
ˆ ˆcos( ) sin( )
jwt
j wtjwt jwt jwt
A t Ae
xe jye xe ye
x wt y wt
x wt y wt
O. Kilic EE542
72
Solution: Example 6 (2/2)
wt = 0x
y
wt = 90o
wt = 180o
wt = 270o
The vector A(t) rotates clockwise wrt z-axis. The tip traces a circle of radius equal to unity with angular frequency w.
O. Kilic EE542
73
Polarization• The alignment of the electric field vector of
a plane wave relative to the direction of propagation defines the polarization.
• Three types:– Linear– Circular– Elliptical (most general form)
Polarization is the locus of the tip of the electric field at a given point as a function of time.
O. Kilic EE542
74
Linear Polarization• Electric field oscillates
along a straight line as a function of time
• Example: wire antennas
y
x
x
y
E
E
O. Kilic EE542
75
Example 7
ˆ( ; ) cos( )oz t xE wt kz
E
For z = 0 (any position value is fine)
ˆ(0; ) cos( )ot xE wt
E
x
t = 0t =
- Eo Eo
y
Linear Polarization: The tip of the E field always stays on x-axis. It oscillates between ±Eo
O. Kilic EE542
76
Example 8
ˆ ˆ( , ) cos( ) 2 cos( )z t x wt kz y wt kz
E
Let z = 0 (any position is fine)
ˆ ˆ(0, ) cos( ) 2 cos( )t x wt y wt
E
x
y
t = /2
t = 0
1
2
Linear Polarization
Exo=1 Eyo=2
O. Kilic EE542
77
Circular Polarization
• Electric field traces a circle as a function of time.
• Generated by two linear components that are 90o out of phase.
• Most satellite antennas are circularly polarized.
y
x
y
x
RHCP
LHCP
O. Kilic EE542
78
Example 7ˆ ˆ( ; ) cos( ) sin( )z t x wt kz y wt kz
E
2cos( )wt kz Exo=1 Eyo=1
Let z= 0
ˆ ˆ(0; ) cos( ) sin( )t x wt y wt
E
x
RHCPy
t=0
t=/2w
t=
t=3/2w
O. Kilic EE542
79
Elliptical Polarization
• This is the most general form
• Linear and circular cases are special forms of elliptical polarization
• Example: log spiral antennas
y
x
LH
y
x
RH
O. Kilic EE542
80
Example 8ˆ ˆ( ; ) cos( ) cos( )a bz t xa wt kz yb wt kz
E
or a b a b
y x
bE E
a
ExEy
Linear when
Circular when
Elliptical if no special condition is met.
2 2 2
and 2a b
y x
a b
E E a
O. Kilic EE542
81
Example 9
0.5ˆ ˆ3 4 V/mj zE x j y e
Determine the polarization of this wave.
O. Kilic EE542
82
Solution: Example 9 (1/2)Note that the field is given in phasor form. We would like to see the trace of the tip of the E field as a function of time. Therefore we need to convert the phasor form to time domain.
20.5
2
( ; ) Re
ˆ ˆRe 3 4 ;
ˆ ˆ3 cos( 0.5 ) 4 cos( 0.5 )
ˆ ˆ3 cos( 0.5 ) 4 sin( 0.5 )
( ; ) 3cos( 0.5 )
( ; ) 4sin( 0.5 )
jwt
jj z jwt
x
y
z t Ee
x j y e e j e
x wt z y wt z
x wt z y wt z
z t wt z
z t wt z
E
E =
E =
O. Kilic EE542
83
Solution: Example 9 (2/2)
22
(0; ) 3cos(0.5 )
(0; ) 4sin(0.5 )
(0; )(0; )1
9 16
x
y
yx
t z
t z
tt
E =
E =
EE
Let z=0
Elliptical polarization
x yE E
O. Kilic EE542
84
Example 10
Find the polarization of the following fields:
ˆ ˆ( ) jkzE r jx y e
ˆ ˆ( ) (1 ) (1 ) jkxE r j y j z e
ˆ ˆ( ) (2 ) (3 ) jkyE r j x j z e
a)
b)
c)
O. Kilic EE542
85
Solution: Example 10 (1/4) 2ˆ ˆ ˆ ˆ( )
ˆ ˆ( ; ) sin( ) cos( )
j kzjkz jkzE r jx y e xe ye
r t x wt kz y wt kz
E
a)
x
y
zLet kz=0
t=0
t=/2w
t=
t=3/2w
RHCP
Observe that orthogonal components have same amplitude but 90o phase difference.
Circular Polarization
O. Kilic EE542
86
Solution: Example 10 (2/4)
4 4
4 4
ˆ ˆ( ) (1 ) (1 )
1 2 ; 1 2
ˆ ˆ( ; ) 2 cos( ) 2 cos( )
jkx
j j
E r j y j z e
j e j e
r t y wt kx z wt kx
E
b)
Observe that orthogonal components have same amplitude but 90o phase difference.
y
z
Let kx=0
t=-/4w
t=+/4w
t=3
t=5/4w RHCP
x
Circular Polarization
O. Kilic EE542
87
Solution: Example 10 (3/4)
c)
1 1
ˆ ˆ( ) (2 ) (3 )
2 5 ; 3 10
1 1tan ; tan
2 3
ˆ ˆ( ; ) 5 cos( ) 10 cos( )
jky
j j
E r j x j z e
j e j e
r t x wt ky z wt ky
E
Observe that orthogonal components have different amplitudes and are out of phase.
Elliptical Polarization
zLet ky=0
t=-/w
t=+/w
x
y
Left Hand
O. Kilic EE542
88
Solution: Example 10 (4/4)
2
ˆ ˆ( ) 2
ˆ ˆ( ; ) sin( ) 2sin( )
ˆ ˆ2 sin( )
jkz
j
E r jx j y e
j e
r t x wt kz y wt kz
x y wt kz
E
d)
Observe that orthogonal components are in phase. Linear Polarization
x
y
z
O. Kilic EE542
89
Coherence and Polarization
• In the definition of linear, circular and elliptical polarization, we considered only completely polarized plane waves.
• Natural radiation received by an anatenna operating at a frequency w, with a narrow bandwidth, w would be quasi-monochromatic plane wave.
• The received signal can be treated as a single frequency plane wave whose amplitude and phase are slowly varying functions of time.
O. Kilic EE542
90
Quasi-Monochromatic Waves
( )( )ˆ ˆ( ; ) ( ) ( ) yx
o o
jkz j tjkz j t
x yz t x t e y t e
E E E
amplitude and phase are slowly varying functions of time
O. Kilic EE542
91
Degree of Coherence
1
2
*
22
yx
xy
x y
E E
E E
where <….> denotes the time average.
0
1lim
T
Tdt
T
O. Kilic EE542
92
Degree of Coherence – Plane Waves
are constant. Thus:,
1
x
o
y
o
jjkzx x
jjkzy y
x y
xy
E E e e
E E e e
O. Kilic EE542
93
Unpolarized Waves
• An em wave can be unpolarized. For example sunlight or lamp light. Other terminology: randomly polarized, incoherent. A wave containing many linearly polarized waves with the polarization randomly oriented in space.
• A wave can also be partially polarized; such as sky light or light reflected from the surface of an object; i.e. glare.
O. Kilic EE542
94
Poynting Vector
• As we have seen, a uniform plane wave carries em power.
• The power density is obtained from the Poynting vector.
• The direction of the Poynting vector is in the direction of wave propagation.
O. Kilic EE542
95
Poynting Vector
* 2
*
W/m
1Re
2where denotes time average
S E H
S E H
O. Kilic EE542
96
Example 11
Calculate the time average power density for the em wave if the electric field is given by:
ˆ jkzoE xE e
O. Kilic EE542
97
Solution: Example 11 (1/2)
1ˆ ;
1ˆ ˆ
ˆ
jkzo
jkzo
H z E
z x E e
Eye
O. Kilic EE542
98
Solution: Example 11 (2/2)
*
2
2
1Re
2
1ˆ ˆRe
2
1ˆ
2
o
o
S E H
Ex y
z E
O. Kilic EE542
99
Plane Waves in Lossy Media
• Finite conductivity, results in loss
• Ohm’s Law applies:
cJ E
Conductivity, Siemens/mConduction current
O. Kilic EE542
100
Complex Permittivity
; where s c
s
s
s
H J jw E J J J
J E jw E
J jw j Ew
J jw E
jw
From Ampere’s Law in phasor form:
O. Kilic EE542
101
Wave Equation for Lossy Media
2 2 0E w E
Attenuation constantPhase constant
12
1
k w
w
k j
jw
Wave number:Loss tangent,
O. Kilic EE542
102
Example 12 (1/2)
ˆ ;
ˆ ;
ˆ
ˆ ˆ
jkzo
jkz jo
z j zo
j zz j z zo o
E xE e k w j
EH y e e
E xE e e
E EH y e e y e e
Plane wave propagation in lossy media:complex number
O. Kilic EE542
103
Example 12 (2/2)
ˆ( ; ) cos( )
ˆ( ; ) cos( )zo
zoz t xE wt z
Ez t y w z
e
e t
E
H
Plane wave is traveling along +z-direction and dissipating as it moves.
attenuation propagation
O. Kilic EE542
104
Field Attenuation in Lossy Medium
O. Kilic EE542
105
Attenuation and Skin Depth
Attenuation coefficient, , depends on the conductivity, permittivity and frequency.
12
1
k j
k w jw
Skin depth, is a measure of how far em wave can penetrate a lossy medium
1
O. Kilic EE542
106
Lossy Media
O. Kilic EE542
107
Example 13
• Calculate the attenuation rate and skin depth of earth for a uniform plane wave of 10 MHz. Assume the following properties for earth: = o
= 4o
= 10-4
O. Kilic EE542
108
Solution: Example 13
4 92
7
4
10 36 104.5 10 1
2 10 4
120 30 10 0.00942 2 4 4
1106.1 m
o
o
w
First we check if we can use approximate relations.
Slightly conducting
O. Kilic EE542
109
References
• http://www.glenbrook.k12.il.us/GBSSCI/PHYS/Class/waves/u10l1b.html
• Applied Electromagnetism, Liang Chi Shen, Jin Au Kong, PWS
O. Kilic EE542
110
Homework Assignments
• Due 9/25/08
O. Kilic EE542
111
Homework 3.1The magnetic field of a uniform plane wave traveling in free space is given by
1. What is the direction of propagation?2. What is the wave number, k in terms of permittivity, o
and permeability, o?
3. Determine the electric field, E.
ˆ jkzoH xH e
O. Kilic EE542
112
Homework 3.2
• Find the polarization state of the following plane wave:
ˆ ˆ( ) 2 jkzE r jx j y e
O. Kilic EE542
113
Homework 3.3
How far must a plane wave of frequency 60 GHz propagate in order for the phase of the wave to be retarded by 180o in a lossless medium with r =1 and r = 3.5?
O. Kilic EE542
114
1. What is the direction of propagation? Ans: -z2. What is the wave number, k in terms of permittivity, o
and permeability, o?
Ans: free space
3. Determine the electric field, E.
Solution Homework 3.1
o ok w
ˆ jkzoH xH e
k
H
E
ˆ ;jkz oo o o
o
E y H e
O. Kilic EE542
115
Solution: Homework 3.2
2
ˆ ˆ( ) 2
ˆ ˆ( ; ) sin( ) 2sin( )
ˆ ˆ2 sin( )
jkz
j
E r jx j y e
j e
r t x wt kz y wt kz
x y wt kz
E
Observe that orthogonal components are in phase. Linear Polarization
x
y
z
O. Kilic EE542
116
Solution 3.3 (1/2)Wavelength: period in spacek = 2
w
O. Kilic EE542
117
Solution 3.3 (2/2)
8
9
2 3.5
1 3 * 10
2 3.5 2 * 60 * 10 3.5
1
400 3.5
o o
o o
kz
zk w f
f
m
