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EN 253 205 (2/2562)Mobile Communication
Modulation Techniques
Asst. Prof. Nararat RuangchaijatuponElectrical EngineeringKhon
Kaen University
Office: EN04325A, Email: [email protected]
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Wired Transmission Techniques• Baseband transmission
– LANs: TP cable, coaxial cable, optical fiber– Line coding:
e.g. Manchester
• Voice-band transmission– Analog: carrier modulation (e.g. AM,
FM, PM)– Digital: digital modulation (e.g. ASK, FSK,
PSK, QAM)– To eliminate DC component, more bandwidth
efficiency over telephone channel
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Consideration in the Design of Wireless Modem Techniques
• Fading, system type, service requirement, users’ equipment
1. Bandwidth efficiency2. Power efficiency3. Out-of-band
radiation4. Resistance to multipath5. Constant envelope
modulation
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Bandwidth Efficiency
• Analog -> Digital, TDMA - > CDMA• Increase system
capacity -> increase
revenues• Need modulation schemes that provide
efficient utilization of available bandwidth• Cellular industry
vs. WLANs industry
(circuit-switched service vs. burst-mode traffic)
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Power Efficiency
• Battery-oriented application: battery size, size and weight of
portable terminals, recharging interval
• Power need to operate electronics in the terminal vs. receiver
design complexity
• Power to radiate the signal at the antenna• Higher data rates
require higher operating
levels of SNR
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Out-of-band Radiation
• Signal energy lying outside the main lobe
• Adjacent-channel interference (ACI)
• Serious interference for mobile terminals in a farther
distance
• Need to be kept under a specified level
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Constant Envelope Modulation
• Signal to be amplified should have a constant envelope vs.
nonlinearity of amplifier
• Frequency modulation (FM)– Large side lobes
• Gaussian minimum shift keying (GMSK)• π/4 - Quadrature Phase
Shift Keying
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3 Categories of Modulation Techniques
• Pulse transmission techniques -> Infrared-based
applications
• Basic modulation techniques for TDMA cellular
• Spread spectrum techniques in CDMA, WLANs– Variation of spread
spectrum techniques ->
OFDM in WLANs
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Carrier Modulated Transmission
• Mixed with a carrier signal at higher frequency– For FDM–
Applications: TV, AM/FM radio, cellular, etc.– Size of antenna is
on the order of
transmission wavelength• Higher frequency, better coverage,
reduced
antenna size, higher data rate, complex RF circuit, reduced
penetration
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Digital Cellular Transmission
• AM, FM, PM• Fading causes amplitude fluctuation• GMSK ->
GSM, CDPD• π/4 - QPSK -> North American TDMA
cellular
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Digital Frequency Modulation and GMSK
• Digital frequency modulation = FSK
• For multi-level input (PAM), the output still has constant
envelope with multiple frequency levels
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Frequency Spacing• For optimal detection -> ensure
orthogonality of transmitted symbols• In FSK, minimum distance =
1/T
– Non-coherent detection (receiver is not locked to the phase of
the transmitted carrier)
– T = duration of the transmitted data symbols• In MSK (minimum
shift keying), minimum
distance = 1/2T– For coherent detection
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Gaussian MSK• Filtered to reduce side
lobes• Gaussian filter
smoothes transition from one frequency tone to another, and
hence, reduces side lobes
• Constant-envelope continuous phase modulation
• GMSK Modulator
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GMSK (cont.)• Time-bandwidth
produce BbT– Bb: 3-dB bandwidth of the
Gaussian filter– T: symbol duration
• BW of filter is narrower small side lobes power in side lobes,
ACI– In GSM (voice), BbT is
0.3– In CDPD, BbT is 0.5
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Digital Phase Modulation andπ/4 -QPSK
• BPSK• Signal
constellation• Error rate
– Distance between 2 points in the constellation
– Level of noise
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BPSK – Non-Coherent Detection
• Use carrier in the current bit as the reference carrier of the
following bit
• Advantage - The receiver doesn’t need to recover phase of the
transmitted carrier
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BPSK – Non-Coherent Detection (cont.)
• The value of the XOR of the consequent bits are transmitted
instead of sending the actual bits
• The two phases that are transmitted represent the change in
the polarity of the current bit with respect to the previous
bit
• The value of the delay is equal to the duration of a
transmitted bit
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Quadrature Phase Shift Keying
• Four-phase PSK• Represents a block of 2 information bits• 0°,
90°, 180°, 270°• 00, 01, 10, 11• Implementation: using the same
bandwidth
and orthogonal carriers
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QPSK (cont.)
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Comparison: BPSK, MSK, QPSK
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Comparison: BPSK, MSK, QPSK (cont.)
• Width of main lobe– Occupied bandwidth– Data rate
• Peak of side lobes– Adjacent-channel interference
• Filtering technique can be used to further reduce the side
lobes– If the baseband data stream is kept in rectangular
form, the side lobes are very high
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Basic Implementation of PSFs for BPSK
• Pulse-Shape filtering to control side lobes• Pulses with
smoother transition
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Further Improvements to QPSK
• Offset or staggered QPSK (OQPSK or SQPSK)– The two branches
are offset by T/2 sec– Envelopes of the in-phase and
quadrature-
phase signals overlap one another– The peaks of one branch
occurs in between
the peaks of the other branch– Fewer fluctuation in amplitude–
Increase constancy in amplitude
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Further Improvements to QPSK (cont.)
• OQPSK or SQPSK– Changes in phase of carrier occurs every
T/2
sec (rather than T sec)– Phase shift by +- 90 degrees– Avoid
+-180 degrees phase shift– Increase constancy in phase
• Improve power requirement and reduce side lobe
• But difficult to develop non-coherent receiver, sensitive to
multipath fading
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π/4-QPSK
• QPSK signal constellation is shifted by 45°each symbol
interval T– Phase transition from one symbol to the next
is +- 45 degrees and +- 135 degrees– Reduce amplitude
variation
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π/4-QPSK (cont.)Signal constellation and phase transitions
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π/4-QPSK (cont.)
• Can be implemented with– Coherent detection– Differential
coherent detection– Discriminator detection
• Used in– North American Digital Cellular TDMA– IS-136–
Japanese Digital Cellular standard
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Broadband Modems for Higher Speed
• Voice-oriented networks– Low-speed modulation technique–
Concern: Coverage & mobility
• Data-oriented networks– WLANs, Point-to-point fixed wireless
networks– Concern: Achievable data rate– In order to increase
speed
• OFDM IEEE 802.11a & HIPERLAN-2
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Orthogonal Frequency Division Multiplexing
• Multirate, multisymbol, multicarrier modulation (MCM)
• Using orthogonality of the adjacent carriers
• OFDM = an FDM system a single user uses all FDM channels
together
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Multicarrier Modulation
• Instead of using 1 carrier, Rs symbols/sec• OFDM uses N
carriers, Rs/N symbols/sec• Carriers are spaced by about Rs/N Hz•
Each of carriers is modulated with the rate
of Rs/N symbols/sec• Multipath is reduced by about 1/N• Less
distortion in each demodulated
symbol
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Multicarrier Modulation (cont.)• The symbols are made sufficient
long
relative to the multipath spread– No need for anti-multipath
signal processing
• Frequency selective fading– Error control coding across
symbols in
different subchannels• Increase data rate by increasing the
number of subcarriers– Complexity and limited transmitted
power
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Multicarrier Modulation (cont.)
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Multisymbol Modulation
• Multiamplitude and multiphase• To increase data rate• Recall
QPSK vs. BPBK
– Same symbol transmission rate (occupied bandwidth), double bit
transmission rate
• Increasing the number of symbols in the constellation allowing
more encoding of the number of bits per symbol
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Multisymbol Modulation (cont.)• 16-QAM (4 bits/symbol) vs.
64-QAM (6 bits/symbol)• The number of bits per symbol of a
signal
constellation represents the increase of the data rate
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Multirate Transmission
• To increase reliability under degraded channel condition
• “Fallback” mode of operation• Users move away from BS
– SNR reduces– Modems fall to lower rate– Reasonable error rates
at lower SNR
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Spread Spectrum Transmissions
• FHSS, DSSS• Advantages
– Overlay onto other systems’ bands with minimal performance
impact
– Wide band vs. frequency selective fading multipath channel
– Urban & indoor have heavy multipath– Anti-interference and
interception– Unlicensed spread spectrum
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Frequency Hopping Spread Spectrum
• Invented by a movie star Hedy Lamarr• To protect guided
torpedoes from jamming• Shift the center frequency of the
transmitted signal• Frequency hops occur in a random pattern
– The pattern known only to transmitter and receiver• The
required transmission bandwidth spans
equal to the number of hopped frequencies
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FHSS (cont.)
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FHSS (cont.)
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FHSS (cont.)• Random number generator• The occurrence of
frequencies is statistically
independent of one another• Pseudorandom pattern• Slow frequency
hopping long packet• Fast frequency hopping very short packet• In
military, fast FHSS, sometimes the same bits
are transmitted using several frequencies
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FHSS (cont.)• GSM supports an optional frequency-hopping
pattern of 217.6 hops/sec– Frequency selective fading &
Co-channel interference
• CDMA with FHSS– Assigning a different hopping pattern to each
terminal– The code are random and independent from one
another– Patterns are selected so that 2 users never hop to
the
same frequency– The number of frequency slots limits the number
of
users
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IEEE 802.11 using FHSS
• 78 hopping channels separated by 1 MHz• Divided into 3
patterns of 26 hops• Allows 3 different systems to coexist
without any hop collision• Allows 3 APs in the same area
– 3 folds increase in capacity
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Direct Sequence Spread Spectrum
• Each transmitted information bit is spread (mapped) into N
smaller pulses (chips)
• N - Processing gain/Bandwidth expansion factor• Despreader
correlates the received signal with
the duplicated transmitted spreading signal• The autocorrelation
function of a good random
code has a very high peak-to-sidelobe ratio– Multiply the pulse
with the delayed version of itself
and then integrate over the duration of the pulse
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DSSS (cont.)
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DSSS (cont.)
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DSSS (cont.)
• Compared with FHSS, the bandwidth of DSSS is always wide
• DSSS provides a robust signal with better coverage area than
FHSS
• FHSS can be implemented with much slower sampling rates–
Saving implementation costs– Saving power consumption of the mobile
units
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High-speed Modem for Spread Spectrum Technology
• From the receiver’s point of view, it is very similar to a
pulse transmission technique that sends a narrow pulse every N
slots
• It is used to measure the multipath characteristic and impulse
response of the channel
• PPM-DSSS can be used in case of no serious multipath
Question & Discussion
Assignment