HY539: Spring 2005 Wireless networks and mobile computing Lecture2: Radio Channel Issues Prof. Maria...
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HY539: Spring 2005 Wireless networks and mobile computing
Lecture2: Radio Channel Issues
Prof. Maria PapadopouliAssistant Professor
Department of Computer ScienceUniversity of North Carolina at Chapel Hill
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Review of Last Lecture
Heterogeneous networks of devices with different capabilities
Pervasive computing spaces
Mobile Computing Challenges Battery capacity, Energy and Bandwidth constraints Mobility
Intermittent connectivity Delays Packet losses
Wireless networks more vulnerable than the wired ones Wireless infrastructures cannot support QoS for applications with
real-time constraints
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Support Intelligent Mobile Clients
Efficient position sensing mechanisms Adaptive systems Monitor the environment and adapt based
on their resources (battery, application requirements, channel capacity, throughput) in an energy-efficient manner
Intelligent and robust wireless infrastructures
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Roadmap
High-level introduction to
Mobile data access Physical layer
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Mobile Data Access
Infrastructure Client-Server paradigm
Ad Hoc (without infrastructure) Peer-to-Peer paradigm
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Fundamentals
Wireless channel model Antenna Impairments Radio Propagation Digital modulation and detection
techniques Error control techniques
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Digital Radio Communications
Baseband Modulation
CarrierRadio
Channel
Transmitter
DataIn
Carrier Bit &FrameSync
Detection
Receiver
DecisionDataOut
Conversion of a stream of bits into signal
Conversion of the signal to a stream of bits
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Adds redundancy to protect the digital information from noise and interference
Bits mapped to signal (analog signal waveform)
e.g., GFSK e.g., TDMA, CDMA
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Transmitter & Radio Channel
TransmitterReceiver
Transmitter Multi-path Fading +
Noise
Receiver
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Antenna Made of conducting material Radio waves hitting an antenna cause electrons to
flow in the conductor and create current Likewise, applying a current to an antenna creates
an electric field around the antenna. As the current of the antenna changes, so does the
electric field. A changing electric field causes a magnetic field,
and the wave is off …
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Antenna (cont’d)
The gain is the extent to which it enhances the signal in its preferred direction
Measured in dBi, decibels relative to an isotropic radiator
Isotropic antenna: radiates power with unit gain uniformly in all directions
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Assignment (for your log)
Different types of antennas Multiple & directional antennas
State of art Cost
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Channel Coding
Often used to protect the digital information from noise and interference and reduce the number of bit errors
Accomplished by selectively introducing redundant bits into the transmitted information stream
These additional bits allow detection and correction of bit errors in the received data stream
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Types of Impairments Noise (thermal, human) Radio frequency signal path loss Fading at low rates Inter-Symbol interference (ISI) Shadow fading Co-channel interference Adjacent channel interference
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Impairments
Impacts radio system design Impact on indoor and outdoor
communications Difficult to control
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Adjacent Channel Interference
Interference from signals adjacent in frequency to the desired signal
Results from imperfect receiver filters which allow nearby frequencies to leak into the passband
Prevented by keeping the frequency separation between each channel in a given cell as large as possible
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Inter-Symbol Interference (ISI)
Overflowing symbols
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ISI (cont’d) Waves that take different paths from the transmitter to
the receiver will travel different distances and be delayed with respect to each other
Waves are combined by superposition, but the effect is that the total waveform is garbled
Delay spread: time between the arrival of the first wavefront and the last multipath echo
Longer delay spreads require more conservative coding 802.11b networks can handle delay spreads of up to
500 ns, but performance is much better when the delay spread is lower
When delay spread is large, many cards reduce transmission rate
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Limits of wireless channel How many bits of information can be transmitted
without error per sec over a channel with a bandwidth B, when the average signal power is limited to P watt, and the signal is exposed to an additive, white (uncorrelated) noise of power N with Gaussian probability distribution
Shannon (1916-2001) Norbert Wiener (1894-1964)
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Shannon’s limit For a channel without shadowing, fading, or
ISI, the maximum possible data rate on a given channel of bandwidth B is
R=Blog2(1+SNR) bps, where SNR is the received signal to noise ratio
Shannon’s is a theoretical limit that cannot be achieved in practice but design techniques improve data rates to approach this bound
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Signal-to-noise ratio (SNR) The ratio between the magnitude of
background noise and the magnitude of un-distorted signal (meaningful information) on a channel
Higher SNR is better (i.e., cleaner) It determines how much information each
symbol can represent
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Propagation models One of the most difficult part of the radio channel
design Done in statistical fashion based on measurements
made specifically for an intended communication system or spectrum allocation
Predicting the average signal strength at a given distance from the transmitter
Large-scale propagation model: signal strength over large T-R separation distances
Small-scale or fading model: rapid fluctuations of the received signal strength over very short travel distances or short time durations (order of seconds)
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Our measurements at UNC
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Free-space propagation model
Used to predict received signal strength when the transmitter and receiver have a clear, unobstructed line-of-sight path between them
Examples: satellite, and microwave line-of-sight radio links
Derived from first principles - power flux density computation Any radiating structure produces electric and magnetic fields:
its current flows through such antenna and launches electric and magnetic fields
The electrostatic and inductive fields decay much faster with distance than the radiation field
At regions far way from the transmitter, the electrostatic and inductive fields become negligible and only the radiated field components need be considered
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Free Space Model Pr(d)=PtGtGr2/[(4)2d2L]
Pt,Pr: transmitter/receiver power
Gt, Gr: transmitter/receiver antenna gain
G = 4Ae/2
L: system loss factor (L=1 no loss) Ae: related to the physical size of the antenna: wavelength in meters, f carrier frequency,
c :speed of light = c/f
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Path Loss
Difference (in dB) between the effective transmitted power and the received power
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Radio wave propagation
Electromagnetic wave propagation mechanisms are diverse
Due to reflection, diffraction, scattering
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Propagation Mechanisms (cont’d)
Reflection: when a propagating electromagnetic wave impinges upon an object which has very large dimensions when compared to the wavelength of the propagating wave
Reflections occur from the surface of the earth, buildings, and walls
Diffraction: when the radio path between transmitter and receiver is obstructed by a surface that has sharp irregularities (edges)
Secondary wavelets into a shadowed region Scattering: when the medium through which the wave travels
consists of objects with dimensions that are small compared to the wavelength and where the number of obstacles per unit volume is large (e.g., street signs, lamp posts)
Reflected energy is spread out/diffused in all directions
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Multipath Propagation
Wall
Wall
Transmitter Cabinet
Reflection
Diffraction (Shadow Fading)
Scattering
Receiver
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Mobile radio channel A single direct path between the base station and the
mobile is seldom the only physical means for propagation Hence, the free space propagation model is inaccurate
when used alone
Two-ray ground reflection model considers both the direct path and a ground reflected propagation path between transmitter and receiver
Reasonably accurate for predicting the large-scale signal strength over distances of several km for mobile radio systems that use tall tower (heights which exceed 40m) or for line-of-sight micro-cell channels in urban environment
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Two-ray ground reflection model
d
T (transmitter)
R (receiver)ht
hr
Pr(d)=PtGtGrhr2ht2/d4
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Wave combination by superposition
When multiple waves converge on a point, the total wave is simply the sum of any component waves
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Modulation
The process of taking information from a message source (baseband) in a suitable manner for transmission
It involves translating the baseband signal onto a radio carrier at frequencies that are very high compared to the baseband frequency
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Demodulation
The process of extracting the baseband from the carrier so that it may be processed and interpreted by the receiver (e.g., symbols detected and extracted)
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Why not modulate the baseband
We must consider the fact that for effective signal radiation the length of the antenna must be proportional to the transmitted wave length For example, voice range 300-3300Hz At 3kHz at 3kbps would imply an antenna of 100Km! By modulating the baseband on a 3GHz carrier the
antenna would be 10cm
To ensure the orderly coexistence of multiple signals in a given spectral band
To help reduce interference among users For regulatory reasons
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Modulations Techniques
Carrier wave s : s(t)=A(t)*cos[(t)] A(t) time varying amplitude Time varying angle (t)(t)= + (t) phase (t), : radian frequency
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Ideal Digital Modulation Provides low bit error rates at low received
signal-to-noise ratio Performs well in multi-path and fading
conditions Occupies a minimum of bandwidth Is easy and cost-effective to implement
Existing modulation schemes do not simultaneously satisfy all of these requirements
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Performance of Modulation Schemes
Tradeoff between fidelity and signal power To increase noise immunity, it is necessary to
increase the signal power
Power efficiency: the amount by which the signal power should be increased to obtain a certain level of fidelity (ie acceptable bit error probability) depends on the particular type of modulation
Bandwidth efficiency: the ability to accommodate data within a limited bandwidth
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Modulation Examples: Frequency Hopping
Time slot
Frequencyslot
Timing the hops accurately is the challenge
0
1
2
3
4
5User A
User B
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Reading material on 802.11 802.11 Wireless Networks, The definitive guide.
Matthew S. Gast, O'Reilly, 2002, ISBN 0-596-00183-5. http://www.csd.uoc.gr/~maria/802.11.book.pdf
Papers: http://sss-mag.com/pdf/802_11tut.pdf
http://sss-mag.com/pdf/80211p.pdf Theoretical paper on its performance:
http://www.ece.utexas.edu/~jandrews/ee381k/EE381KTA/802.11_throughput.pdf