1. Electromagnetism INEL 4152
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Electromagnetism INEL 4152
Sandra Cruz-Pol, Ph. D.
ECE UPRM
Mayagüez, PR
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2. Electricity => Magnetism
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Electricity => Magnetism
In 1820 Oersted discovered that a steady current produces a magnetic field while teaching a physics class.
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3. Would magnetism would produce electricity?
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Would magnetism would produce electricity?
Eleven years later, and at the same time, Mike Faraday in London and Joe Henry in New York discovered that a time-varying magnetic field would produce an electric current!
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4. Electromagnetics was born!
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Electromagnetics was born!
This is the principle of motors, hydro-electric generators and transformers operation.
This is what Oersted discovered accidentally:
*Mention some examples of em waves
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5. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
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6. Electromagnetic Spectrum
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Electromagnetic Spectrum
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7. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Some terms
E = electric field intensity [V/m]
D = electric field density
H = magnetic field intensity, [A/m]
B = magnetic field density, [Teslas]
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8. Maxwell Equations in General Form
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Maxwell Equations in General Form
Differential form
Integral Form
Gauss’s Law for E field.
Gauss’s Law for H field. Nonexistence of monopole
Faraday’s Law
Ampere’s Circuit Law
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9. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Maxwell’s Eqs.
Also the equation of continuity
Maxwell added the term to Ampere’s Law so that it not only works for static conditions but also for time-varying situations.
This added term is called the displacement current density, while J is the conduction current.
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10. Maxwell put them together
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Maxwell put them together
And added Jd, the displacement current I S1 L S2
At low frequencies J>>Jd, but at radio frequencies both terms are comparable in magnitude.
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11. Moving loop in static field
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Moving loop in static field
When a conducting loop is moving inside a magnet (static B field, in Teslas), the force on a charge is
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Encarta®
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12. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Who was NikolaTesla?
Find out what inventions he made
His relation to Thomas Edison
Why is he not well know?
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13. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Special case
Consider the case of a lossless medium
with no charges, i.e. .
The wave equation can be derived from Maxwell equations as
What is the solution for this differential equation?
The equation of a wave!
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14. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Phasors & complex #’s
Working with harmonic fields is easier, but requires knowledge of phasor, let’s review
complex numbers and
phasors
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15. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
COMPLEX NUMBERS:
Given a complex number z
where
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16. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Review:
Addition,
Subtraction,
Multiplication,
Division,
Square Root,
Complex Conjugate
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17. For a time varying phase
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
For a time varying phase
Real and imaginary parts are:
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18. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
PHASORS
For a sinusoidal current
equals the real part of
The complex term which results from dropping the time factor is called the phasor current, denoted by (s comes from sinusoidal)
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19. To change back to time domain
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
To change back to time domain
The phasor is multiplied by the time factor, ejwt, and taken the real part.
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20. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Advantages of phasors
Time derivative is equivalent to multiplying its phasor by jw
Time integral is equivalent to dividing by the same term.
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21. Time-Harmonic fields (sines and cosines)
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Time-Harmonic fields (sines and cosines)
The wave equation can be derived from Maxwell equations, indicating that the changes in the fields behave as a wave, called an electromagnetic field.
Since any periodic wave can be represented as a sum of sines and cosines (using Fourier), then we can deal only with harmonic fields to simplify the equations.
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22. Maxwell Equations for Harmonic fields
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Maxwell Equations for Harmonic fields
Differential form*
Gauss’s Law for E field.
Gauss’s Law for H field. No monopole
Faraday’s Law
Ampere’s Circuit Law
* (substituting and )
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23. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
A wave
Start taking the curl of Faraday’s law
Then apply the vectorial identity
And you’re left with
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24. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
A Wave
Let’s look at a special case for simplicity
without loosing generality:
The electric field has only an x-component
The field travels in z direction
Then we have
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25. To change back to time domain
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
To change back to time domain
From phasor
…to time domain
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26. Cruz-Pol, Electromagnetics UPRM
Ejemplo 9.23
In free space,
Find k, Jd and H using phasors and maxwells eqs.
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27. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Several Cases of Media
Free space
Lossless dielectric
Lossy dielectric
Good Conductor
Recall: Permittivity
eo=8.854 x 10-12[ F/m]
Permeability
mo= 4p x 10-7 [H/m]
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28. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
1. Free space
There are no losses, e.g.
Let’s define
The phase of the wave
The angular frequency
Phase constant
The phase velocity of the wave
The period and wavelength
How does it moves?
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29. 3. Lossy Dielectrics (General Case)
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
3. Lossy Dielectrics (General Case)
In general, we had
From this we obtain
So , for a known material and frequency, we can find g=a+jb
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30. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Intrinsic Impedance, h
If we divide E by H, we get units of ohms and the definition of the intrinsic impedance of a medium at a given frequency.
*Not in-phase for a lossy medium
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31. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Note…
E and H are perpendicular to one another
Travel is perpendicular to the direction of propagation
The amplitude is related to the impedance
And so is the phase
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32. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Loss Tangent
If we divide the conduction current by the displacement current
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33. Relation between tanq and ec
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Relation between tanq and ec
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34. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
2. Lossless dielectric
Substituting in the general equations:
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35. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Review: 1. Free Space
Substituting in the general equations:
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36. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
4. Good Conductors
Substituting in the general equations:
Is water a good conductor???
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37. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Summary
Any medium
Lossless medium (s=0)
Low-loss medium
(e”/e’<.01)
Good conductor
(e”/e’>100)
Units a
[Np/m] b
[rad/m] h
[ohm] uc l
w/b
2p/b=up/f
[m/s]
[m]
**In free space; eo =8.85 x F/m mo=4p x 10-7 H/m
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38. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Skin depth, d
We know that a wave attenuates in a lossy medium until it vanishes, but how deep does it go?
Is defined as the depth at which the electric amplitude is decreased to 37%
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39. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Short Cut …
You can use Maxwell’s or use
where k is the direction of propagation of the wave, i.e., the direction in which the EM wave is traveling (a unitary vector).
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40. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Waves
Static charges > static electric field, E
Steady current > static magnetic field, H
Static magnet > static magnetic field, H
Time-varying current > time varying E(t) & H(t) that are interdependent > electromagnetic wave
Time-varying magnet > time varying E(t) & H(t) that are interdependent > electromagnetic wave
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41. EM waves don’t need a medium to propagate
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
EM waves don’t need a medium to propagate
Sound waves need a medium like air or water to propagate
EM wave don’t. They can travel in free space in the complete absence of matter.
Look at a “wind wave”; the energy moves, the plants stay at the same place.
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42. Exercises: Wave Propagation in Lossless materials
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Exercises: Wave Propagation in Lossless materials
A wave in a nonmagnetic material is given by
Find:
direction of wave propagation,
wavelength in the material
phase velocity
Relative permittivity of material
Electric field phasor
Answer: +y, up= 2x108 m/s, 1.26m, 2.25,
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43. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Power in a wave
A wave carries power and transmits it wherever it goes
The power density per area carried by a wave is given by the Poynting vector.
See Applet by Daniel Roth at
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44. Poynting Vector Derivation
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Poynting Vector Derivation
Start with E dot Ampere’s
Apply vector identity
And end up with:
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45. Poynting Vector Derivation…
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Poynting Vector Derivation…
Substitute Faraday in 1rst term
Rearrange
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46. Poynting Vector Derivation…
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Poynting Vector Derivation…
Taking the integral wrt volume
Applying Theorem of Divergence
Which means that the total power coming out of a volume is either due to the electric or magnetic field energy variations or is lost in ohmic losses.
Total power across surface of volume
Rate of change of stored energy in E or H
Ohmic losses due to conduction current
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47. Power: Poynting Vector
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Power: Poynting Vector
Waves carry energy and information
Poynting says that the net power flowing out of a given volume is = to the decrease in time in energy stored minus the conduction losses.
Represents the instantaneous power density vector associated to the electromagnetic wave.
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48. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Time Average Power
The Poynting vector averaged in time is
For the general case wave:
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49. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Total Power in W
The total power through a surface S is
Note that the units now are in Watts
Note that power nomenclature, P is not cursive.
Note that the dot product indicates that the surface area needs to be perpendicular to the Poynting vector so that all the power will go thru. (give example of receiver antenna)
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50. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Exercises: Power
1. At microwave frequencies, the power density considered safe for human exposure is 1 mW/cm2. A radar radiates a wave with an electric field amplitude E that decays with distance as |E(R)|=3000/R [V/m], where R is the distance in meters. What is the radius of the unsafe region?
Answer: m
2. A 5GHz wave traveling In a nonmagnetic medium with er=9 is characterized by Determine the direction of wave travel and the average power density carried by the wave
Answer:
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51. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
TEM wave z x y
Transverse ElectroMagnetic = plane wave
There are no fields parallel to the direction of propagation,
only perpendicular (=transverse).
If have an electric field Ex(z)
…then must have a corresponding magnetic field Hx(z)
The direction of propagation is
aE x aH = ak
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52. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
PE 10.7
In free space, H=0.2 cos (wt-bx) z A/m. Find the total power passing through a
square plate of side 10cm on plane x+z=1
square plate at z=3 x
Answer; Ptot = 53mW Hz Ey
Answer; Ptot = 0mW!
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53. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Polarization:
Why do we care??
Antenna applications –
Antenna can only TX or RX a polarization it is designed to support. Straight wires, square waveguides, and similar rectangular systems support linear waves (polarized in one direction) Round waveguides, helical or flat spiral antennas produce circular or elliptical waves.
Remote Sensing and Radar Applications –
Many targets will reflect or absorb EM waves differently for different polarizations. Using multiple polarizations can give more information and improve results.
Absorption applications –
Human body, for instance, will absorb waves with E oriented from head to toe better than side-to-side, esp. in grounded cases. Also, the frequency at which maximum absorption occurs is different for these two polarizations. This has ramifications in safety guidelines and studies.
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54. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Polarization of a wave
IEEE Definition:
The trace of the tip of the E-field vector as a function of time seen from behind.
Simple cases
Vertical, Ex
Horizontal, Ey x y z x y x y
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55. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Polarization
In general, plane wave has 2 components; in x & y
And y-component might be out of phase wrt to x-component, d is the phase difference between x and y. x y Ey Ex y x
Front View
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56. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Several Cases
Linear polarization: d=dy-dx =0o or ±180on
Circular polarization: dy-dx =±90o & Eox=Eoy
Elliptical polarization: dy-dx=±90o & Eox≠Eoy, or d=≠0o or ≠180on even if Eox=Eoy
Unpolarized- natural radiation
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57. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Linear polarization
Front View
d =0
@z=0 in time domain x y Ey Ex
Back View: y x
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58. Circular polarization
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Circular polarization
Both components have same amplitude Eox=Eoy,
d =d y-d x= -90o = Right circular polarized (RCP)
d =+90o = LCP
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59. Elliptical polarization
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Elliptical polarization
X and Y components have different amplitudes Eox≠Eoy, and d =±90o or d ≠±90o and Eox=Eoy
Or d ≠0,180o,
Or any other phase difference, for example d =56o
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60. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Polarization example
Polarizing glasses
Unpolarized
radiation enters
Nothing comes out this time.
All light comes out
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61. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Example
Determine the polarization state of a plane wave with electric field: a. b. c. d.
d=105, Elliptic
d=0, linear a 30o
+180, LP a 45o
-90, RHCP
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62. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Cell phone & brain
Computer model for Cell phone Radiation inside the Human Brain
SAR Specific Absorption Rate [W/Kg] FCC limit 1.6W/kg, ~.2mW/cm2 for 30mins
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63. Cruz-Pol, Electromagnetics UPRM
Human absorption
* The FCC limit in the US for public exposure from cellular telephones at the ear level is a SAR level of 1.6 watts per kilogram (1.6 W/kg) as averaged over one gram of tissue.
 **The ICNIRP limit in Europe for public exposure from cellular telephones at the ear level is a SAR level of 2.0 watts per kilogram (2.0 W/kg) as averaged over ten grams of tissue.
MHz is where the human body absorbs RF energy most efficiently
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64. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Radar bands
Band Name
Nominal Freq Range
Specific Bands
Application
HF, VHF, UHF
3-30 MHz0, MHz, MHz
MHz , MHz
TV, Radio, L
1-2 GHz (15-30 cm)
GHz
Clear air, soil moist S
2-4 GHz (8-15 cm)
GHz >
Weather observations
Cellular phones C
4-8 GHz (4-8 cm)
GHz
TV stations, short range Weather X
8-12 GHz (2.5–4 cm)
GHz
Cloud, light rain, airplane weather. Police radar. Ku
12-18 GHz
GHz,
Weather studies K
18-27 GHz
GHz
Water vapor content Ka
27-40 GHz
GHz
Cloud, rain V
40-75 GHz
59-64 GHz
Intra-building comm. W
GHz
76-81 GH, GHz
Rain, tornadoes
millimeter
GHz
Tornado chasers
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65. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Microwave Oven
Most food is lossy media at microwave frequencies, therefore EM power is lost in the food as heat.
Find depth of penetration if meat which at 2.45 GHz has the complex permittivity given.
The power reaches the inside as soon as the oven in turned on!
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66. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Decibel Scale
In many applications need comparison of two powers, a power ratio, e.g. reflected power, attenuated power, gain,…
The decibel (dB) scale is logarithmic
Note that for voltages, fields, and electric currents, the log is multiplied by 20 instead of 10.
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67. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Attenuation rate, A
Represents the rate of decrease of the magnitude of Pave(z) as a function of propagation distance
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68. Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Submarine antenna
A submarine at a depth of 200m uses a wire antenna to receive signal transmissions at 1kHz.
Determine the power density incident upon the submarine antenna due to the EM wave with |Eo|= 10V/m.
[At 1kHz, sea water has er=81, s=4].
At what depth the amplitude of E has decreased to 1% its initial value at z=0 (sea surface)?
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69. Exercise: Lossy media propagation
Dr. S. Cruz-Pol, INEL 4152-Electromagnetics
Exercise: Lossy media propagation
For each of the following determine if the material is low-loss dielectric, good conductor, etc.
Glass with mr=1, er=5 and s=10-12 S/m at 10 GHZ
Animal tissue with mr=1, er=12 and s=0.3 S/m at 100 MHZ
Wood with mr=1, er=3 and s=10-4 S/m at 1 kHZ
Answer:
low-loss, a= 8.4x10-11 Np/m, b= 468 r/m, l= 1.34 cm, up=1.34x108, hc=168 W
general, a= 9.75, b=12, l=52 cm, up=0.5x108 m/s, hc=39.5+j31.7 W
Good conductor, a= 6.3x10-4, b= 6.3x10-4, l= 10km, up=0.1x108, hc=6.28(1+j) W
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