Introduction in Telecommunication 121009

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Introduction in Telecommunication(121009) Chris
Roeloffzen
Chair Telecommunication engineering (EWI) Floor
8 HOGEKAMP EL/TN building (north) Telephone 489
2804 E-mail c.g.h.roeloffzen_at_el.utwente.nl
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Today Lecture 6
Chapter 7 Angle Modulation Transmission
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Contents of the course
Lecture 1 - 3 Introduction Chapter 1
Introduction to Electronic Communications Chapter
2 Signal Analysis and Mixing Lecture 4 - 7
CW modulation Chapter 4 Amplitude modulation,
Transmission Chapter 5 Amplitude modulation,
Reception Chapter 6 Single-side banded
Communication Systems Chapter 7 Angle
Modulation Transmission Chapter 8 Angle
Modulation Receivers Lecture 8 - 11
Media Chapter 12 Metallic Transmission
Lines Chapter 14 Electromagnetic Wave
Propagation Chapter 15 Antennas Chapter 13
Optical Fibers Lecture 12 - 14 Digital
Communication Chapter 9 Digital
Modulation Chapter 10 Digital
Transmission Lecture 15 16 ????????????????? Fo
r specific information see www.el.utwente.nl/te/e
ducation/education.htm
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Chapter 7 Angle Modulation Transmission

• What is Angle modulation
• What is the difference between frequency and
  phase modulation
• What is direct and indirect modulation
• Deviation sensitivity, phase deviation,
  modulation index
• Bandwidth of angle-modulated wave
• Bandwidth requirements
• Phasor representation of angle-modulated wave
• Frequency up-conversion
• FM transmitters
• Angle modulation versus AM

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Angle modulation
?inst(t) instantaneous phase (radians) Questio
n What is the instantaneous frequency?
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Angle modulation
vanglemod (t) angle modulated wave (Volt) Vc
peak carrier amplitude (Volt) ?inst
instantaneous angular frequency (rad/sec) ?inst
instantaneous phase (radians)
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Phase modulation
The instantaneous phase of a harmonic carrier
signal is varied in such a way that the
instantaneous phase deviation i.e. the difference
between the instantaneous phase and that of the
carrier signal is linearly related to the size of
the modulating signal at a given instant of time.
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Phase modulation
The instantaneous phase of a harmonic carrier
signal is varied in such a way that the
instantaneous phase deviation i.e. the difference
between the instantaneous phase and that of the
carrier signal is linearly related to the size of
the modulating signal at a given instant of time.
Kp is the phase deviation sensitivity (rad/Volt)
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Frequency modulation
The frequency of a harmonic carrier signal is
varied in such a way that the instantaneous
frequency deviation i.e. the difference between
the instantaneous frequency and the carrier
frequency is linearly related to the size of the
modulating signal at a given instant of time.
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Frequency modulation
The frequency of a harmonic carrier signal is
varied in such a way that the instantaneous
frequency deviation i.e. the difference between
the instantaneous frequency and the carrier
frequency is linearly related to the size of the
modulating signal at a given instant of time.
Kf is the frequency deviation sensitivity
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PM
Kp is the deviation sensitivity
FM
Kf is the deviation sensitivity
TASK Make block diagrams of PM and FM modulators
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PM
Kp is the deviation sensitivity
Phase modulator
Modulating signal source
PM wave
Direct
Modulating signal source
Differentiator
Frequency modulator
PM wave
Indirect
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FM
Kf is the deviation sensitivity
Modulating signal source
Frequency modulator
Direct
FM wave
Integrator
Phase modulator
Modulating signal source
FM wave
Indirect
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Frequency modulation of single frequency signal
PM
FM
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PM and FM of sine-wave signal
Carrier
Modulating signal
?
?
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PM and FM of sine-wave signal
Carrier
Modulating signal
FM
PM
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Phase Deviation and Modulation Index
m is the peak phase deviation or modulation index
PM
(radians)
FM
(unitless)
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Frequency Deviation
FM
FM
PM
(peak) frequency deviation
dependent of the frequency
PM
(peak) frequency deviation
independent of the frequency
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PM and FM of sine-wave signal
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Bessel function of the first kind
m is the modulation index
FM
PM
is the Bessel function of the first kind
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Relation AM and angle mod
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Bessel function of the first kind
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Bandwidth requirements of Angle-mod waves
1 Low-index modulation (narrowband FM)
m lt 1 ( fm gtgtgt ?f )
(Hz)
2 High-index modulation (wideband FM)
m gt 10 (?f gtgtgt fm )
3 Actual bandwidth (look at Bessel table page 266)
where n is the number of significant sidebands
4 Carsons rule (approx 98 of power)
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Example
FM modulator ?f 10 kHz fm 10 kHz Vc 10
V fc 500 kHz
Draw the spectrum? What is the bandwidth using
Bessel table? What is the bandwidth using
Carsons rule?
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Example
?f 10 kHz fm 10 kHz Vc 10 V fc 500 kHz
m 1
Fig 7-7
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Phasor representation of Angle-mod wave
m lt 1 (narrowband FM)
Fig 7-9
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Phasor representation of Angle-mod wave
m gtgt 1 (Wideband FM)
Fig 7-10
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Average Power of Angle-mod wave
Instantaneous power in unmodulated carrier is
(W)
Pc carrier power (Watts) Vc peak unmodulated
carrier voltage (volts) R load resistance (ohms)
Instantaneous power in angle-mod carrier is
So the average power of the angle-mod carrier is
equal to the unmodulated carrier
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Frequency and Phase modulators Direct FM Modulator
Fig 7-16
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Linear integrated-circuit direct FM modulator
High-frequency deviations and high modulation
indices.
Fig 7-20
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Frequency up-conversion heterodyne method
With FM and PM modulators, the carrier at the
output is generally somewhat lower than the
desired frequency of transmission
Fig 7-24 a
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Frequency up-conversion multiplication
Fig 7-24
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Indirect FM Transmitter
Fig 7-27
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Indirect FM Transmitter
m lt 1
Fig 7-28
Problem !!!!!!
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Indirect FM Transmitter
m lt 1
Fig 7-28
?max m 1.67 miliradiance ? ?f14 Hz
Aim ?f 75 kHz and ft 90 MHz
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Armstrong Indirect FM Transmitter
Where are the frequency conversions ?
Fig 7-27
Aim ?f 75 kHz and ft 90 MHz
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Angle mod versus AM

• Advantages of Angle modulation
• Noise immunity
• Noise performance and signal-to-noise
  improvement
• Capture effect
• Power utilization and efficiency
• Disadvantages of Angle modulation
• Bandwidth
• Circuit complexity and costs

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End