Title: Introduction to Mobile Communications
1Introduction to Mobile Communications
- TCOM 552, Lecture 3
- Hung Nguyen, Ph.D.
- 18 September, 2006
2Outline
- Channel Capacity
- Signal-to-Noise Ratio (SNR)
- Multiplexing
- Digital Modulation
- Analog Modulation
- Coding
- Simplex and Duplex Transission
3About Channel Capacity
- Impairments, such as noise, limit data rate that
can be achieved - Channel Capacity the maximum rate at which data
can be transmitted over a given communication
path, or channel, under given conditions
4Transmission Impairments
- Signal received may differ from signal
transmitted - Analog - degradation of signal quality
- Digital - bit errors
- Caused by
- Attenuation and attenuation distortion
- Delay distortion
- Noise
5Attenuation
- Signal strength falls off with distance
- Depends on medium
- Received signal strength
- must be enough to be detected
- must be sufficiently higher than noise to be
received without error - Attenuation is an increasing function of
frequency
6Noise (1)
- Additional EM energy and signals on the receiver
- Thermal -- usually inserted by receiver circuits
- Due to thermal agitation of electrons
- Uniformly distributed
- White noise
- Intermodulation
- Signals that are the sum and difference of
original frequencies sharing a medium, and
falling within the desired signals passband
7Noise (2)
- Crosstalk
- A signal from one line or channel is picked up by
another - Impulse
- Irregular pulses or spikes
- e.g. External electromagnetic interference
- Short duration
- High amplitude
- Multipath
- See in later Sessions, causes distortions
8Signal-to-Noise Ratio
- Ratio of the power in a signal to the power
contained in the noise thats present at a
particular point in the transmission - Typically measured at a receiver
- Signal-to-noise ratio (SNR, or S/N)
- A high SNR means a high-quality signal, low
number of required intermediate repeaters - SNR sets upper bound on achievable data rate
9Signals and Noise
High SNR
Lower SNR
10Concepts Related to Channel Capacity
- Data rate - rate at which data can be
communicated (bps) - Bandwidth - the bandwidth of the transmitted
signal as constrained by the transmitter and the
nature of the transmission medium (Hertz) - Noise - average level of noise over the
communications path - Error rate - rate at which errors occur
- Error transmit 1 and receive 0 transmit 0 and
receive 1
11Nyquist Bandwidth
- For binary signals (two voltage levels)
- C 2B
- With multilevel signaling
- C 2B log2 M
- M number of discrete signal or voltage levels
12Shannon Capacity Formula
- Equation
- Represents theoretical maximum that can be
achieved - In practice, somewhat lower rates achieved
- Formula assumes white noise (thermal noise)
- Worse when other forms of noise are included
- Impulse noise
- Attenuation distortion or delay distortion
- Interference
13Example of Nyquist and Shannon Formulations
- Spectrum of a channel between 3 MHz and 4 MHz
SNRdB 24 dB - Using Shannons formula
14Example of Nyquist and Shannon Formulations
- How many signaling levels are required?
15Multiplexing
- Capacity of transmission medium usually exceeds
capacity required for transmission of a single
signal - Multiplexing - carrying multiple signals on a
single medium - More efficient use of transmission medium
16Multiplexing
17Reasons for Widespread Use of Multiplexing
- Cost per kbps of transmission facility declines
with an increase in the data rate - Cost of transmission and receiving equipment
declines with increased data rate - Most individual data communicating devices
require relatively modest data rate support
18Multiplexing Techniques
- Frequency-division multiplexing (FDM)
- Takes advantage of the fact that the useful
bandwidth of the medium exceeds the required
bandwidth of a given signal --- different users
at different frequency bands or subbands - Time-division multiplexing (TDM)
- Takes advantage of the fact that the achievable
bit rate of the medium exceeds the required data
rate of a digital signal --- different users at
different time slots
19Frequency-division Multiplexing
20Time-division Multiplexing
21Multiplexing and Multiple Access
- Both refer to the sharing of a communications
resource, usually a channel - Multiplexing usually refers to sharing some
resource by doing something at one site --- e.g.,
at the multiplexer - Often a static or pseudo-static allocation of
fractions of the multiplexed channel, e.g., a T1
line. Often refers to sharing one resource. The
division of the resource can be made on
frequency, or time, or other physical feature - Multiple Access shares an asset in a distributed
domain - i.e., multiple users at different places sharing
an overall media, and using a scheme where it is
divided into channels based on frequency, or time
or another physical feature - Usually dynamic
22Factors Used to CompareModulation and Encoding
Schemes
- Signal spectrum
- With fewer higher frequency components, less
bandwidth required --- Spectrum Efficiency - For wired comms with no DC component, AC
coupling via transformer possible --- DC
components cause problems - Transfer function of a channel is worse near band
edges -- always better to constrain signal
spectrum well inside the spectrum available - Synchronization and Clocking
- Determining when 0 phase occurs -- carrier synch
- Determining beginning and end of each bit
position -- bit sync - Determining frame sync --- usually layer above
physical
23Signal Modulation/Encoding Criteria
Demodulating/Decoding Accurately
- What determines how successful a receiver will be
in interpreting an incoming signal? - Signal-to-noise ratio SNR
- Signal power/noise power
- Note power energy per unit time
- Data rate (R)
- Bandwidth (BW)
- An increase in data rate increases bit error rate
- An increase in SNR decreases bit error rate
- An increase in bandwidth allows an increase in
data rate
24Factors Used to CompareModulation/Encoding
Schemes
- Signal interference and noise immunity ---
- Performance in the presence of interference and
noise - For a given signal power level, the effect of
noise and interference is then labeled the Power
Efficiency - For digital modulation, Prob. Of Bit Error
function (SNR) where N includes the interference
terms - More exactly, Prob. Bit Error function (Energy
per bit/Noise power density, with noise including
interference and other noise like terms) --- see
next chart - Cost and complexity
- Usually the higher the signal and data rates
require a higher complexity and greater the cost
25A Figure of Merit in CommunicationsNoise
Immunity
- For digital modulation one bottom line Figure of
Merit (FOM) is Probability of Bit Error (Pe) --
Lowest for Most Accurate Decoding of Bit Stream - Prob. Bit Error function of (Eb/N0)
- Many functions for many different modulation and
coding types have been computed - usually
decreases with increasing Eb/N0 - Eb energy per bit
- N0 noise spectral density Noise Power N
(N0) BW - Note Includes Interference and Intermodulation
and Crosstalk - (Eb/N0) is a critically important number for
digital comms - Eb/N0 (SNR)(BW/R) ---- important formula --
derive it - SNR is signal to noise ratio, a ratio of power
levels - BW is signal bandwidth, R is data rate in
bits/sec - For analog modulation the FOM is SNR
- Signal quality given by subjective statistical
scores -- voice 1-5 (high) - FM requires a lower SNR than AM for the same
signal quality
26Basic Modulation/Encoding Techniques
- Digital data to analog signal --- Digital
Modulation - Amplitude-shift keying (ASK)
- Amplitude difference of carrier frequency
- Frequency-shift keying (FSK)
- Frequency difference near carrier frequency
- Phase-shift keying (PSK)
- Phase of carrier signal shifted
27Basic Encoding Techniques
28Amplitude-Shift Keying
- One binary digit represented by presence of
carrier, at constant amplitude - Other binary digit represented by absence of
carrier - where the carrier signal is Acos(2pfct)
29Amplitude-Shift Keying
- Susceptible to sudden gain changes
- Inefficient modulation technique
- On voice-grade lines, used up to 1200 bps
- Used to transmit digital data over optical fiber
30Binary Frequency-Shift Keying (BFSK)
- Two binary digits represented by two different
frequencies near the carrier frequency - where f1 and f2 are offset from carrier frequency
fc by equal but opposite amounts
31Binary Frequency-Shift Keying (BFSK)
- Less susceptible to error than ASK
- On voice-grade lines, used up to 1200bps
- Used for high-frequency (3 to 30 MHz) radio
transmission - Can be used at higher frequencies on LANs that
use coaxial cable
32Multiple Frequency-Shift Keying (MFSK)
- More than two frequencies are used
- More bandwidth efficient but more susceptible to
error - fi fc (2i 1 M)fd
- fc the carrier frequency
- fd the difference frequency
- M number of different signal elements 2 L
- L number of bits per signal element
33Multiple Frequency-Shift Keying (MFSK)
- To match data rate of input bit stream, each
output signal element is held for - Ts LT seconds
- where T is the bit period (data rate 1/T)
- So, one signal element encodes L bits
34Multiple Frequency-Shift Keying (MFSK)
- Total bandwidth required
- 2Mfd
- Minimum frequency separation required 2fd 1/Ts
- Therefore, modulator requires a bandwidth of
- Wd 2L/LT M/Ts
35Multiple Frequency-Shift Keying (MFSK)
36Phase Shift Keying (PSK)
- The signal carrier is shifted in phase according
to the input data stream - 2 level PSK, also called binary PSK or BPSK or
2-PSK, uses 2 phase possibilities over which the
phase can vary, typically 0 and 180 degrees --
each phase represents 1 bit - can also have n-PSK -- 4-PSK often is 0, 90, 180
and 270 degrees --- each phase then represents 2
bits - Each phase called a symbol
- Each bit or groups of bits can be represented by
a phase value (e.g., 0 degrees, or 180 degrees),
or bits can be based on whether or not phase
changes (differential keying, e.g., no phase
change is a 0, a phase change is a 1) --- DPSK
37Phase-Shift Keying (PSK)
- Two-level PSK (BPSK)
- Uses two phases to represent binary digits
38Phase-Shift Keying (PSK)
- Differential PSK (DPSK)
- Phase shift with reference to previous bit
- Binary 0 signal burst of same phase as previous
signal burst - Binary 1 signal burst of opposite phase to
previous signal burst
39Phase-Shift Keying (PSK)
- Four-level PSK (QPSK)
- Each element represents more than one bit
40Quadrature PSK
- More efficient use by each signal element (or
symbol) representing more than one bit - e.g. shifts of ?/2 (90o)
- In QPSK each element or symbol represents two
bits - Can use 8 phase angles and have more than one
amplitude -- then becomes QAM then (combining PSK
and ASK) - QPSK used in different forms in a many cellular
digital systems - Offset-QPSK OQPSK The I (0 and 180 degrees) and
Q (90 and 270 degrees) quadrature bits are offset
from each other by half a bit --- becomes a more
efficient modulation, with phase changes not so
abrupt so better spectrally, and more linear - p/4-QPSK is a similar approach to OQPSK, also used
41Multilevel Phase-Shift Keying (MPSK)
- Multilevel PSK
- Using multiple phase angles multiple signals
elements can be achieved - D modulation rate, baud
- R data rate, bps
- M number of different signal elements or
symbols 2L - L number of bits per signal element or symbol
- e.g., 4-PSK is QPSK, 8-PSK, etc
42Quadrature Amplitude Modulation
- QAM is a combination of ASK and PSK
- Two different signals sent simultaneously on the
same carrier frequency
43Quadrature Amplitude Modulation
44Quadrature Amplitude Modulation (QAM)
- The most common method for quad (4) bit transfer
- Combination of 8 different angles in phase
modulation and two amplitudes of signal - Provides 16 different signals (or symbols),
each of which can represent 4 bits (there are 16
possible 4 bit combinations)
45Quadrature Amplitude Modulation Illustration --
Example of Constellation Diagram
- Notice that there are 16 circles or nodes, each
represents a possible amplitude and phase, and
each represents 4 bits - Obviously there are many such constellation
diagrams possible --- the technical issue winds
up being that as the nodes get closer to each
other any noise can lead to the receiver
confusing them, and making a bit error
46Performance of Digital Modulation Schemes
- Bandwidth or Spectral Efficiency
- ASK and PSK bandwidth directly related to bit
rate - FSK bandwidth related to data rate for lower
frequencies, but to offset of modulated frequency
from carrier at high frequencies - Determined by C/BW i.e. bps/Hz
- Noise Immunity or Power Efficiency In the
presence of noise, bit error rate of PSK and QPSK
are about 3dB superior to ASK and FSK ---- i.e.,
x2 less power for same performance - Determined by BER as function of Eb/N0
47Spectral Performance
- Bandwidth of modulated signal (BT)
- ASK, PSK BT (1r)R
- FSK BT 2DF(1r)R
- R bit rate
- 0 lt r lt 1 related to how signal is filtered
- DF f2-fc fc-f1
48SPECTRAL Performance
- Bandwidth of modulated signal (BT)
- MPSK
- MFSK
- L number of bits encoded per signal element
- M number of different signal elements
49BER vs.. Eb/N0
In Stallings
50BER vs.. Eb/N0 (contd)
In Stallings
51Power-Bandwidth Efficiency Plane
From Bernard Sklar
52Analog Modulation Techniques
- Analog data to analog signal
- Also called analog modulation
- Amplitude modulation (AM)
- Angle modulation
- Frequency modulation (FM)
- Phase modulation (PM)
53AM Modulation Demodulation
- Top left source (baseband) signal to be
modulated - Bottom left modulated signal, carrier lines
inside white - Right demodulated after it is transmitted and
received (note after 1.e-3 similarity except for
attenuation)
54FM Modulation Demodulation
Input Voice and Received Voice after Transmission
and Reception, Using FM --- Only a Little Noise
-- Notice Similarity
55Input Voice and Received Voice after Transmission
and Reception, Using FM --- Lots More Noise in
Channel -- Notice that Received Signal is NOT
What Was Transmitted
56Amplitude Modulation
- Amplitude Modulation
- cos2?fct carrier
- x(t) input signal
- na modulation index
- Ratio of amplitude of input signal to carrier
- a.k.a double sideband transmitted carrier (DSBTC)
57Spectrum of AM signal
58Amplitude Modulation
- Transmitted power
- Pt total transmitted power in s(t)
- Pc transmitted power in carrier
59Single Sideband (SSB)
- Variant of AM is single sideband (SSB)
- Sends only one sideband
- Eliminates other sideband and carrier
- Advantages
- Only half the bandwidth is required
- Less power is required
- Disadvantages
- Suppressed carrier cant be used for
synchronization purposes
60Angle Modulation
- Angle modulation
- Phase modulation
- Phase is proportional to modulating signal
- np phase modulation index
61Angle Modulation
- Frequency modulation
- Derivative of the phase is proportional to
modulating signal - nf frequency modulation index
62Angle Modulation
- Compared to AM, FM and PM result in a signal
whose bandwidth - is also centered at fc
- but has a magnitude that is much different
- Angle modulation includes cos(f (t)) which
produces a wide range of frequencies - Thus, FM and PM require greater bandwidth than AM
63Angle Modulation
- Carsons rule
- where
- The formula for FM becomes
64Coding
- Encoding sometimes is used to refer to the way in
which analog data is converted to digital signals - e.g., A/Ds, PCM or DM
- Source Coding refers to the way in which basic
digitized analog data can be compressed to lower
data rates without loosing any or to much
information -- e.g., voice, video, fax, graphics,
etc.
65Coding (contd)
- Channel coding refers to signal transformations
used to improve the signals ability to withstand
the channel propagation impairments --- two types - Waveform coding --- transforms signals
(waveforms) into better ones --- able to
withstand propagation errors better --- this
refers to different modulation schemes, M-ary
signaling, spread spectrum - Forward Error coding (FEC), also called Sequence
coding, transforms data bits sequences into those
that are less error prone, by inserting redundant
bits in a smart way -- e.g., block and
convolutional codes
66Basic Encoding Techniques
- Analog data to digital signal
- Used for digitization of analog sources
- Pulse code modulation (PCM)
- Delta modulation (DM)
- After the above, usually additional processing
done to compress signal to achieve similar signal
quality with fewer bits --- called source coding
67Analog to Digital Conversion
- Once analog data have been converted to digital
signals, the digital data - can be transmitted using NRZ-L
- can be encoded as a digital signal using a code
other than NRZ-L - can be modulated to an analog signal for wireless
transmission, using previously discussed
techniques
68Pulse Code Modulation
- Based on the sampling theorem
- Each analog sample is assigned a binary code
- Analog samples are referred to as pulse amplitude
modulation (PAM) samples - The digital signal consists of block of n bits,
where each n-bit number is the amplitude of a PCM
pulse
69Pulse Code Modulation
70Pulse Code Modulation
- By quantizing the PAM pulse, original signal is
only approximated - Leads to quantizing noise
- Signal-to-noise ratio for quantizing noise
- Thus, each additional bit increases SNR by 6 dB,
or a factor of 4
71Delta Modulation
- Analog input is approximated by staircase
function - Moves up or down by one quantization level (?) at
each sampling interval - The bit stream approximates derivative of analog
signal (rather than amplitude) - 1 is generated if function goes up
- 0 otherwise
72Delta Modulation
73Delta Modulation
- Two important parameters
- Size of step assigned to each binary digit (?)
- Sampling rate
- Accuracy improved by increasing sampling rate
- However, this increases the data rate
- Advantage of DM over PCM is the simplicity of its
implementation
74Source Coding
- Voice or Speech or Audio
- Basic PCM yields 4 KHz2 samples/Hz8
bits/sample64 Kbps -- music/etc up to 768 Kbps - Coding can exploit redundancies in the speech
waveform -- one way is LPC, linear predictive
coding --- predicts whats next, sends only the
changes expected - RPE and CELP (Code Excited LPC) used in cell
phones, using LPC, at rates of 4 to 9.6 to 13
kbps - Graphics and Video e.g., JPEG or GIF, MPEG
75Reasons for Growth of Digital Modulation and
Transmission
- Cheaper components used in creating the
modulations and doing the encoding, and similarly
on the receivers - Best performance in terms of immunity to noise
and in terms of spectral efficiency --- improved
digital modulation and channel coding techniques
- Great improvements in digital voice and video
compression - Voice to about 8 Kbps at good quality, video
varies to below 1 Mbps provide increased capacity
in terms of numbers of users in given BW - Dynamic and efficient multiple access and
multiplexing techniques using TDM, TDMA and CDMA,
even when some larger scale Frequency Allocations
(FDMA) -- labeled as combinations - Easier and simpler implementation interfaces to
the digital landline networks and IP
76Duplex Modes
- Duplex modes refer to the ways in which two way
traffic is arranged - One way vs. two way
- Simplex (one way only),
- Half duplex (both ways, but only one way at a
time), - Duplex (two ways at the same time)
- If duplex, question is then how one separates the
two ways - In wired systems, it could be in different wires
(or cables, fibers, etc)
77Duplex Modes (contd)
- FDD, frequency division duplex. Both wired and
wireless one way is to separate the two paths in
frequency. If two frequencies, or frequency
bands, are separate enough, no cross interference - Cellular systems are all FDD
- Its clean and easy to do, good performance, but
it limits channel assignments and is not best for
asymmetric traffic - TDD is time division duplex, same frequencies are
used both ways, but time slots are assigned one
way or the other - Good for asymmetrical traffic, allows more
control through time slot reassignments - But strong transmissions one way could interfere
with other users - Mostly not used in cellular, but 3G has one such
protocol, and low tier portables also