28-07-2011, 09:40 AM
[attachment=14841]
Mobile Computing
Spectrum and bandwidth
Electromagnetic signals are made up of many frequencies
Shown in the next example
Spectrum and bandwidth
The 2nd frequency is an integer multiple of the first frequency
When all of the frequency components of a signal are integer multiples of one frequency, the latter frequency is called fundamental frequency (f)
period of the resultant signal is equal to the period of the fundamental frequency
Period of s(t) is T=1/f
Fourier Analysis
Any signal is made up of components at various frequencies, in which each component is a sinusoid.
Adding enough sinusoidal signals with appropriate amplitude, frequency and phase, any electromagnetic signal can be constructed
Spectrum and bandwidth
It is the range of frequencies that a signal contains (among its components)
In the example, spectrum is from f to 3f
absolute bandwidth is the width of the spectrum
3f-f = 2f
Data Rate and bandwidth
There is a direct relationship between data rate (or signal carrying capacity) and bandwidth
Suppose we let a positive pulse represent 1 and negative pulse represent 0
Then the waveform (next slide) represents 1010..
Duration of each pulse is tbit = (1/2) (1/f)
Thus data rate is 1/ tbit = 2f bits/sec
As we add more and more frequencies the wave looks more like a square wave
Example
Looking at FIG 2(a) the bandwidth = 5f-f = 4f
If f=1MHz = 106 cycles/sec, then bandwidth = 4MHz
The period of the fundamental frequency = T = 1/f = 1 μs
So each bit takes up 0.5 μs i.e. data rate is 1/0.5 Mbps = 2 Mbps
Example
Looking at FIG 1© the bandwidth = 3f-f = 2f
If f=2MHz = 2x106 cycles/sec, then bandwidth = 4MHz
The period of the fundamental frequency = T = 1/f = 0.5 μs
So each bit takes up 0.25 μs i.e. data rate is 1/0.25 Mbps = 4 Mbps
Example
Thus a given bandwidth can support different data rate, depending on the ability of the receiver to discern the difference between 0 and 1 in the presence of noise and interference
Gain and Loss
Ratio between power levels of two signals is referred to as Gain
gain (dB) = 10 log10 (Pout/Pin)
loss (dB) = -10 log10 (Pout/Pin) = 10 log10 (Pin/Pout)
Pout is output power level and Pin is input power level
Signal of power 10mw transmitted over wireless channel, and receiver receives the signal with 2mw power:
gain (db) = 10 log10 (2/10) = -10 (0.698) = -6.98 dB
loss (db) = 6.98 dB
dBW power
dB-Watt
power in dB transmitted with respect to a base power of 1 Watt
dBW = 10 log10 P
P is power transmitted in Watt
if power transmitted is 1 Watt
dBW = 10 log10 1 = 0 dBW
1000 watt transmission is 30 dBW
dBm power
dB-milliwatt
better metric in wireless network
power in dB transmitted with respect to a base power of 1 milliwatt
dBm = 10 log10 P
P is power transmitted in milliwatt
if power transmitted is 1 milliwatt
dBm = 10 log10 1 = 0 dBm
10 milliwatt transmission is 10 dBm
802.11b can transmit at a maximum power of 100mw = 20 dBm
Channel Capacity
Four concepts :
Data Rate : rate (in bps) at which data can be communicated
Bandwidth: bandwidth of the transmitted signal as constrained by the transmitter and the medium, expressed in Hz
Noise : interfering electromagnetic signal that tend to reduce the integrity of data signal
Error rate : rate at which receiver receives bits in error i.e. it receives a 0 when actually a 1 was sent and vice-versa
Nyquist Bandwidth
Given a bandwidth of B, the highest signal rate that can be carried is 2B (when signal transmitted is binary (two voltage levels))
When M voltage levels are used, then each signal level can represent log2M bits. Hence the Nyquist bandwidth (capacity) is given by
C = 2 B log2M
Shannon’s Capacity Formula
When there is noise in the medium, capacity is given by
C <= B log2 (1 + SNR)
SNR = signal power/noise power
SNRdB = 10 log10 SNR
Bandwidth Allocation
Necessary to avoid interference between different radio devices
Microwave woven should not interfere with TV transmission
Generally a radio transmitter is limited to a certain bandwidth
802.11channel has 30MHz bandwidth
Power and placement of transmitter are regulated by authority
Consumer devices are generally limited to less than 1W power
ISM and UNII Band
Industrial, Scientific and Medical (ISM) band
902-928 MHz in the USA
433 and 868 MHz in Europe
2400 MHz – 2483.5 MHz (license-free almost everywhere)
Peak power 1W (30dBm)
but most devices operate at 100mW or less
802.11 uses the ISM band of 2.4GHz
Unlicensed National Information Infrastructure (UNII) bands
5.725 – 5.875 GHz
Antenna
An electrical conductor or system of conductors used for radiating electromagnetic energy into space or for collecting electromagnetic energy from the space
An integral part of a wireless system
Radiation Patterns
Antenna radiates power in all directions
but typically does not radiate equally in all directions
Ideal antenna is one that radiates equal power in all direction
called an isotropic antenna
all points with equal power are located on a sphere with the antenna as its center
Omnidirectional Antenna
Produces omnidirectional
radiation pattern of
equal strength in all
directions
Vector A and B are
of equal length
Directional Antenna
Radiates most power in one
axis (direction)
radiates less in other
direction
vector B is longer than
vector A : more power
radiated along B than A
directional along X
Dipole Antenna
Half-wave dipole or Hertz
antenna consists of two
straight collinear conductor
of equal length
Length of the antenna
is half the wavelength of
the signal.
Quarter-wave antenna
Quarter-wave or marconi antenna
has a veritcal conductor of
length quarter of the wavelength
of the signal
Sectorized Antenna
Several directional antenna
combined on a single pole
to provide sectorized antenna
each sector serves receivers
listening it its direction
Antenna Gain
A measure of the directionality of an antenna
Defined as the power output, in a particular direction, compared to that produced in any direction by a perfect isotropic antenna
Example: if an antenna has a gain of 3dB, the antenna is better (in that direction) than isotropic antenna by a factor of 2
Antenna Gain
Antenna gain is dependent on effective area of an antenna.
effective area is related to the physical size of the antenna and its shape
Antenna Gain is given by
where
G = antenna gain
Ae = effective area
f = carrier frequency
c = speed of light
λ = carrier wavelength
Signal Propagation
Transmission range:
receiver receives signal with an error rate low enough to be able to communicate
Detection range: transmitted power is high enough to detect the transmitter, but high error rate forbids communication
Interference range: sender interferes with other transmissions by adding to the noise
Signal Propagation
Radio waves exhibit three fundamental propagation behavior
Ground wave (< 2 MHz) : waves with low frequency follow earth’s surface
can propagate long distances
Used for submarine communication or AM radio
Sky wave (2-30 MHz) : waves reflect at the ionosphere and bounce back and forth between ionosphere and earth , travelling around the world
Used by international broadcast and amateur radio
Signal Propagation
Line of Sight (> 30 MHz) : emitted waves follow a straight line of sight
allows straight communication with satellites or microwave links on the ground
used by mobile phone system, satellite systems
Free Space loss
Transmitted signal attenuates over distance because it is spread over larger and larger area
This is known as free space loss and for isotropic antennas
Pt = power at the transmitting antenna
Pr = power at the receiving antenna
λ = carrier wavelength
d = propagation distance between the antennas
c = speed of light
Free Space loss
For other antennas
Gt = Gain of transmitting antenna
Gr = Gain of receiving antenna
At = effective area of transmitting antenna
Ar = effective area of receiving antenna
Thermal Noise
Thermal noise is introduced due to thermal agitation of electrons
Present in all transmission media and all electronic devices
a function of temperature
uniformly distributed across the frequency spectrum and hence is often referred to as white noise
amount of noise found in a bandwidth of 1 Hz is
N0 = k T
N0 = noise power density in watts per 1 Hz of bandwidth
k = Boltzman’s constant = 1.3803 x 10-23 J/K
T = temperature, in Kelvins
N = thermal noise in watts present in a bandwidth of B
= kTB where
Data rate and error rate
A parameter related to SNR that is more convenient for determining digital data rates and error rates
ratio of signal energy per bit to noise power density per Hertz, Eb/N0
R = bit rate of transmission, S= power of the signal,
Tb = time required to send 1 bit. Then R = 1/Tb
Eb = S Tb
so
Data rate and error rate
Bit error rate is a decreasing function of Eb/N0
If bit rate R is to increase, then to keep bit error rate (or Eb/N0) same, the transmitted signal power must increase, relative to noise
Eb/N0 is related to SNR as follows
B = signal bandwidth
(since N = N0 B)
Doppler’s Shift
When a client is mobile, the frequency of received signal could be less or more than that of the transmitted signal due to Doppler’s effect
If the mobile is moving towards the direction of arrival of the wave, the Doppler’s shift is positive
If the mobile is moving away from the direction of arrival of the wave, the Doppler’s shift is negative
Doppler’s Shift
where
fd =change in frequency
due to Doppler’s shift
v = constant velocity of the
mobile receiver
λ = wavelength of the transmission
Doppler’s shift
f = fc + fd
where
f = the received carrier frequency
fc = carrier frequency being transmitted
fd = Doppler’s shift as per the formula in the prev slide
Multipath Propagation
Wireless signal can arrive at the receiver through different pahs
LOS
Reflections from objects
Diffraction
Occurs at the edge of an impenetrable body that is large compared to the wavelength of the signal
Effect of Multipath Propagation
Multiple copies of the signal may arrive with different phases. If the phases add destructively, the signal level reduces relative to noise.
Inter Symbol Interference (ISI)
Multiplexing
A fundamental mechanism in communication system and networks
Enables multiple users to share a medium
For wireless communication, multiplexing can be carried out in four dimensions: space, time, frequency and code
Space division multiplexing
Channels are assigned on the basis of “space” (but operate on same frequency)
The assignment makes sure that the transmission do not interfere with each (with a guard band in between)
Space division multiplexing
Frequency Division Multiplexing
Frequency domain is subdivided into several non-overlapping frequency bands
Each channel is assigned its own frequency band (with guard spaces in between)
Frequency Division Multiplexing
Time Division Multiplexing
A channel is given the whole bandwidth for a certain amount of time
All senders use the same frequency, but at different point of time
Time Division Multiplexing
Frequency and time division multiplexing
A channel use a certain frequency for a certain amount of time and then uses a different frequency at some other time
Used in GSM systems
Frequency and time division multiplexing
Code division multiplexing
separation of channels achieved by assigning each channel its own code
guard spaces are realized by having distance in code space (e.g. orthogonal codes)
transmitter can transmit in the same frequency band at the same time, but have to use different code
Provides good protection against interference and tapping
but the receivers have relatively high complexity
has to know the code and must separate the channel with user data from the noise composed of other transmission
has to be synchronized with the transmitter
Code division multiplexing
Modulation
Process of combining input signal and a carrier frequency at the transmitter
Digital to analog modulation
necessary if the medium only carries analog signal
Analog to analog modulation
needed to have effective transmission (otherwise the antenna needed to transmit original signal could be large)
permits frequency division multiplexing
Amplitude Shift Keying (ASK)
ASK is the most simple digital modulation scheme
Two binary values, 0 and 1, are represented by two different amplitude
In wireless, a constant amplitude cannot be guaranteed, so ASK is typically not used
Amplitude Shift Keying (ASK)
Frequency Shift Keying (FSK)
The simplest form of FSK is binary FSK
assigns one frequency f1 to binary 1 and another frequency f2 binary 0
Simple way to implement is to switch between two oscillators one with f1 and the other with f2
The receiver can demodulate by having two bandpass filter
Frequency Shift Keying (FSK)
Phase Shift Keying (PSK)
Uses shifts in the phase of a signal to represent data
Shifting the phase by 1800 each time data changes: called binary PSK
The receiver must synchronize in frequency and phase with the transmitter
Phase Shift Keying (PSK)
Quadrature Phase Shift Keying (Q-PSK)
Higher bit rate can be achieved for the same bandwidth by coding two bits into one phase shift.
450 for data 11
1350 for data 10
2250 for data 00
3150 for data 01
Spread Spectrum
Spreading the bandwidth needed to transmit data
Spread signal has the same energy as the original signal, but is spread over a larger frequency range
provides resistance to narrowband interference
Spread Spectrum
Direct Sequence Spread Spectrum
Takes a user bit sequence and performs an XOR with, what is known as, chipping sequence
Each user bit duration tb
chipping sequence has smaller pulses tc
If chipping sequence is generated properly it may appear as random noise
sometimes called pseudo-noise (PN)
tb/tc is known as the spreading factor
determines the bandwidth of the resultant signal
Used by 802.11b
Direct Sequence Spread Spectrum
Frequency Hopping Spread Spectrum
Total available bandwidth is split into many channels of smaller bandwidth and guard spaces
Transmitter and receiver stay on one of these channels for a certain time and then hop to another channel
Implements FDM and TDM
Pattern of channel usage : hopping sequence
Time spent on a particular channel: dwell time
Frequency Hopping Spread Spectrum
Slow hopping
Transmitter uses one frequency for several bit period
systems are cheaper, but are prone to narrow band interference
Fast hopping
Transmitter changes frequency several times in one bit period
Transmitter and receivers have to stay synchronized within smaller tolerances
Better immuned to narrow band interference as they stick to one frequency for a very short period
Receiver must know the hopping sequence and stay synchronized with the transmitter
Used by bluetooth
Mobile Computing
Spectrum and bandwidth
Electromagnetic signals are made up of many frequencies
Shown in the next example
Spectrum and bandwidth
The 2nd frequency is an integer multiple of the first frequency
When all of the frequency components of a signal are integer multiples of one frequency, the latter frequency is called fundamental frequency (f)
period of the resultant signal is equal to the period of the fundamental frequency
Period of s(t) is T=1/f
Fourier Analysis
Any signal is made up of components at various frequencies, in which each component is a sinusoid.
Adding enough sinusoidal signals with appropriate amplitude, frequency and phase, any electromagnetic signal can be constructed
Spectrum and bandwidth
It is the range of frequencies that a signal contains (among its components)
In the example, spectrum is from f to 3f
absolute bandwidth is the width of the spectrum
3f-f = 2f
Data Rate and bandwidth
There is a direct relationship between data rate (or signal carrying capacity) and bandwidth
Suppose we let a positive pulse represent 1 and negative pulse represent 0
Then the waveform (next slide) represents 1010..
Duration of each pulse is tbit = (1/2) (1/f)
Thus data rate is 1/ tbit = 2f bits/sec
As we add more and more frequencies the wave looks more like a square wave
Example
Looking at FIG 2(a) the bandwidth = 5f-f = 4f
If f=1MHz = 106 cycles/sec, then bandwidth = 4MHz
The period of the fundamental frequency = T = 1/f = 1 μs
So each bit takes up 0.5 μs i.e. data rate is 1/0.5 Mbps = 2 Mbps
Example
Looking at FIG 1© the bandwidth = 3f-f = 2f
If f=2MHz = 2x106 cycles/sec, then bandwidth = 4MHz
The period of the fundamental frequency = T = 1/f = 0.5 μs
So each bit takes up 0.25 μs i.e. data rate is 1/0.25 Mbps = 4 Mbps
Example
Thus a given bandwidth can support different data rate, depending on the ability of the receiver to discern the difference between 0 and 1 in the presence of noise and interference
Gain and Loss
Ratio between power levels of two signals is referred to as Gain
gain (dB) = 10 log10 (Pout/Pin)
loss (dB) = -10 log10 (Pout/Pin) = 10 log10 (Pin/Pout)
Pout is output power level and Pin is input power level
Signal of power 10mw transmitted over wireless channel, and receiver receives the signal with 2mw power:
gain (db) = 10 log10 (2/10) = -10 (0.698) = -6.98 dB
loss (db) = 6.98 dB
dBW power
dB-Watt
power in dB transmitted with respect to a base power of 1 Watt
dBW = 10 log10 P
P is power transmitted in Watt
if power transmitted is 1 Watt
dBW = 10 log10 1 = 0 dBW
1000 watt transmission is 30 dBW
dBm power
dB-milliwatt
better metric in wireless network
power in dB transmitted with respect to a base power of 1 milliwatt
dBm = 10 log10 P
P is power transmitted in milliwatt
if power transmitted is 1 milliwatt
dBm = 10 log10 1 = 0 dBm
10 milliwatt transmission is 10 dBm
802.11b can transmit at a maximum power of 100mw = 20 dBm
Channel Capacity
Four concepts :
Data Rate : rate (in bps) at which data can be communicated
Bandwidth: bandwidth of the transmitted signal as constrained by the transmitter and the medium, expressed in Hz
Noise : interfering electromagnetic signal that tend to reduce the integrity of data signal
Error rate : rate at which receiver receives bits in error i.e. it receives a 0 when actually a 1 was sent and vice-versa
Nyquist Bandwidth
Given a bandwidth of B, the highest signal rate that can be carried is 2B (when signal transmitted is binary (two voltage levels))
When M voltage levels are used, then each signal level can represent log2M bits. Hence the Nyquist bandwidth (capacity) is given by
C = 2 B log2M
Shannon’s Capacity Formula
When there is noise in the medium, capacity is given by
C <= B log2 (1 + SNR)
SNR = signal power/noise power
SNRdB = 10 log10 SNR
Bandwidth Allocation
Necessary to avoid interference between different radio devices
Microwave woven should not interfere with TV transmission
Generally a radio transmitter is limited to a certain bandwidth
802.11channel has 30MHz bandwidth
Power and placement of transmitter are regulated by authority
Consumer devices are generally limited to less than 1W power
ISM and UNII Band
Industrial, Scientific and Medical (ISM) band
902-928 MHz in the USA
433 and 868 MHz in Europe
2400 MHz – 2483.5 MHz (license-free almost everywhere)
Peak power 1W (30dBm)
but most devices operate at 100mW or less
802.11 uses the ISM band of 2.4GHz
Unlicensed National Information Infrastructure (UNII) bands
5.725 – 5.875 GHz
Antenna
An electrical conductor or system of conductors used for radiating electromagnetic energy into space or for collecting electromagnetic energy from the space
An integral part of a wireless system
Radiation Patterns
Antenna radiates power in all directions
but typically does not radiate equally in all directions
Ideal antenna is one that radiates equal power in all direction
called an isotropic antenna
all points with equal power are located on a sphere with the antenna as its center
Omnidirectional Antenna
Produces omnidirectional
radiation pattern of
equal strength in all
directions
Vector A and B are
of equal length
Directional Antenna
Radiates most power in one
axis (direction)
radiates less in other
direction
vector B is longer than
vector A : more power
radiated along B than A
directional along X
Dipole Antenna
Half-wave dipole or Hertz
antenna consists of two
straight collinear conductor
of equal length
Length of the antenna
is half the wavelength of
the signal.
Quarter-wave antenna
Quarter-wave or marconi antenna
has a veritcal conductor of
length quarter of the wavelength
of the signal
Sectorized Antenna
Several directional antenna
combined on a single pole
to provide sectorized antenna
each sector serves receivers
listening it its direction
Antenna Gain
A measure of the directionality of an antenna
Defined as the power output, in a particular direction, compared to that produced in any direction by a perfect isotropic antenna
Example: if an antenna has a gain of 3dB, the antenna is better (in that direction) than isotropic antenna by a factor of 2
Antenna Gain
Antenna gain is dependent on effective area of an antenna.
effective area is related to the physical size of the antenna and its shape
Antenna Gain is given by
where
G = antenna gain
Ae = effective area
f = carrier frequency
c = speed of light
λ = carrier wavelength
Signal Propagation
Transmission range:
receiver receives signal with an error rate low enough to be able to communicate
Detection range: transmitted power is high enough to detect the transmitter, but high error rate forbids communication
Interference range: sender interferes with other transmissions by adding to the noise
Signal Propagation
Radio waves exhibit three fundamental propagation behavior
Ground wave (< 2 MHz) : waves with low frequency follow earth’s surface
can propagate long distances
Used for submarine communication or AM radio
Sky wave (2-30 MHz) : waves reflect at the ionosphere and bounce back and forth between ionosphere and earth , travelling around the world
Used by international broadcast and amateur radio
Signal Propagation
Line of Sight (> 30 MHz) : emitted waves follow a straight line of sight
allows straight communication with satellites or microwave links on the ground
used by mobile phone system, satellite systems
Free Space loss
Transmitted signal attenuates over distance because it is spread over larger and larger area
This is known as free space loss and for isotropic antennas
Pt = power at the transmitting antenna
Pr = power at the receiving antenna
λ = carrier wavelength
d = propagation distance between the antennas
c = speed of light
Free Space loss
For other antennas
Gt = Gain of transmitting antenna
Gr = Gain of receiving antenna
At = effective area of transmitting antenna
Ar = effective area of receiving antenna
Thermal Noise
Thermal noise is introduced due to thermal agitation of electrons
Present in all transmission media and all electronic devices
a function of temperature
uniformly distributed across the frequency spectrum and hence is often referred to as white noise
amount of noise found in a bandwidth of 1 Hz is
N0 = k T
N0 = noise power density in watts per 1 Hz of bandwidth
k = Boltzman’s constant = 1.3803 x 10-23 J/K
T = temperature, in Kelvins
N = thermal noise in watts present in a bandwidth of B
= kTB where
Data rate and error rate
A parameter related to SNR that is more convenient for determining digital data rates and error rates
ratio of signal energy per bit to noise power density per Hertz, Eb/N0
R = bit rate of transmission, S= power of the signal,
Tb = time required to send 1 bit. Then R = 1/Tb
Eb = S Tb
so
Data rate and error rate
Bit error rate is a decreasing function of Eb/N0
If bit rate R is to increase, then to keep bit error rate (or Eb/N0) same, the transmitted signal power must increase, relative to noise
Eb/N0 is related to SNR as follows
B = signal bandwidth
(since N = N0 B)
Doppler’s Shift
When a client is mobile, the frequency of received signal could be less or more than that of the transmitted signal due to Doppler’s effect
If the mobile is moving towards the direction of arrival of the wave, the Doppler’s shift is positive
If the mobile is moving away from the direction of arrival of the wave, the Doppler’s shift is negative
Doppler’s Shift
where
fd =change in frequency
due to Doppler’s shift
v = constant velocity of the
mobile receiver
λ = wavelength of the transmission
Doppler’s shift
f = fc + fd
where
f = the received carrier frequency
fc = carrier frequency being transmitted
fd = Doppler’s shift as per the formula in the prev slide
Multipath Propagation
Wireless signal can arrive at the receiver through different pahs
LOS
Reflections from objects
Diffraction
Occurs at the edge of an impenetrable body that is large compared to the wavelength of the signal
Effect of Multipath Propagation
Multiple copies of the signal may arrive with different phases. If the phases add destructively, the signal level reduces relative to noise.
Inter Symbol Interference (ISI)
Multiplexing
A fundamental mechanism in communication system and networks
Enables multiple users to share a medium
For wireless communication, multiplexing can be carried out in four dimensions: space, time, frequency and code
Space division multiplexing
Channels are assigned on the basis of “space” (but operate on same frequency)
The assignment makes sure that the transmission do not interfere with each (with a guard band in between)
Space division multiplexing
Frequency Division Multiplexing
Frequency domain is subdivided into several non-overlapping frequency bands
Each channel is assigned its own frequency band (with guard spaces in between)
Frequency Division Multiplexing
Time Division Multiplexing
A channel is given the whole bandwidth for a certain amount of time
All senders use the same frequency, but at different point of time
Time Division Multiplexing
Frequency and time division multiplexing
A channel use a certain frequency for a certain amount of time and then uses a different frequency at some other time
Used in GSM systems
Frequency and time division multiplexing
Code division multiplexing
separation of channels achieved by assigning each channel its own code
guard spaces are realized by having distance in code space (e.g. orthogonal codes)
transmitter can transmit in the same frequency band at the same time, but have to use different code
Provides good protection against interference and tapping
but the receivers have relatively high complexity
has to know the code and must separate the channel with user data from the noise composed of other transmission
has to be synchronized with the transmitter
Code division multiplexing
Modulation
Process of combining input signal and a carrier frequency at the transmitter
Digital to analog modulation
necessary if the medium only carries analog signal
Analog to analog modulation
needed to have effective transmission (otherwise the antenna needed to transmit original signal could be large)
permits frequency division multiplexing
Amplitude Shift Keying (ASK)
ASK is the most simple digital modulation scheme
Two binary values, 0 and 1, are represented by two different amplitude
In wireless, a constant amplitude cannot be guaranteed, so ASK is typically not used
Amplitude Shift Keying (ASK)
Frequency Shift Keying (FSK)
The simplest form of FSK is binary FSK
assigns one frequency f1 to binary 1 and another frequency f2 binary 0
Simple way to implement is to switch between two oscillators one with f1 and the other with f2
The receiver can demodulate by having two bandpass filter
Frequency Shift Keying (FSK)
Phase Shift Keying (PSK)
Uses shifts in the phase of a signal to represent data
Shifting the phase by 1800 each time data changes: called binary PSK
The receiver must synchronize in frequency and phase with the transmitter
Phase Shift Keying (PSK)
Quadrature Phase Shift Keying (Q-PSK)
Higher bit rate can be achieved for the same bandwidth by coding two bits into one phase shift.
450 for data 11
1350 for data 10
2250 for data 00
3150 for data 01
Spread Spectrum
Spreading the bandwidth needed to transmit data
Spread signal has the same energy as the original signal, but is spread over a larger frequency range
provides resistance to narrowband interference
Spread Spectrum
Direct Sequence Spread Spectrum
Takes a user bit sequence and performs an XOR with, what is known as, chipping sequence
Each user bit duration tb
chipping sequence has smaller pulses tc
If chipping sequence is generated properly it may appear as random noise
sometimes called pseudo-noise (PN)
tb/tc is known as the spreading factor
determines the bandwidth of the resultant signal
Used by 802.11b
Direct Sequence Spread Spectrum
Frequency Hopping Spread Spectrum
Total available bandwidth is split into many channels of smaller bandwidth and guard spaces
Transmitter and receiver stay on one of these channels for a certain time and then hop to another channel
Implements FDM and TDM
Pattern of channel usage : hopping sequence
Time spent on a particular channel: dwell time
Frequency Hopping Spread Spectrum
Slow hopping
Transmitter uses one frequency for several bit period
systems are cheaper, but are prone to narrow band interference
Fast hopping
Transmitter changes frequency several times in one bit period
Transmitter and receivers have to stay synchronized within smaller tolerances
Better immuned to narrow band interference as they stick to one frequency for a very short period
Receiver must know the hopping sequence and stay synchronized with the transmitter
Used by bluetooth
