Title: Fundamentals of Wireless LANs 1.2
1Fundamentals of Wireless LANs 1.2
- Module 3
- Wireless Radio Technology
2Module Overview
3Module Overview
- In this module, the student will learn about
wireless technology and radio waves. - This module will explore the technology and the
mathematics of radio, so that the reader can
understand how invisible radio waves work to make
so many things possible, including WLANs.
4Waves Sine Waves
- A waveform is a representation of how alternating
current (AC) varies with time. - The most familiar AC waveform is the sine wave,
which derives its name from the fact that the
current or voltage varies with the mathematical
sine function of the elapsed time - Frequency measured in cycles per second or Hertz
(Hz). - A million cycles per second is represented by
megahertz (MHz) - A billion cycles per second represented by
gigahertz (GHz)
5Sine Wave
There is an inverse relationship between time and
frequency t 1/f f 1/t
6Sine Wave Properties
- Amplitude The distance from zero to the maximum
value of each alternation is called the
amplitude. - Period The time it takes for a sine wave to
complete one cycle is defined as the period of
the waveform. - The distance traveled by the sine wave during
this period is referred to as its wavelength. - Wavelength Indicated by the Greek lambda symbol
?. It is the distance between one value to the
same value on the next cycle. - Frequency The number of repetitions or cycles
per unit time is the frequency, typically
expressed in cycles per second, or Hz.
7Watts
- One definition of energy is the ability to do
work. - There are many forms of energy, including
- electrical energy
- chemical energy
- thermal energy
- gravitational potential energy
- The metric unit for measuring energy is the
Joule. - Energy can be thought of as an amount.
- 1 Watt I Joule of energy / one second
- If one Joule of energy is transferred in one
second, this is one watt (W) of power.
8Watts
- The U.S. Federal Communications Commission allows
a maximum of 4 watts of power to be emitted in
point-to-multipoint WLAN transmissions in the
unlicensed 2.4-GHz band. - Typical WLAN NICS transmit at 100 mW.
- Typical Access Points can transmit between 30 to
100 mW (plus the gain from the Antenna).
9Watts
- Power levels on a single WLAN segment are rarely
higher than 100 mW, enough to communicate for up
to three-fourths of a kilometer or one-half of a
mile under optimum conditions. - Access points generally have the ability to
radiate from 30 to100 mW, depending on the
manufacturer. - Outdoor building-to-building applications
(bridges) are the only ones that use power levels
over 100 mW.
10Decibels
- The decibel (dB) is a unit that is used to
measure electrical power. - The dB is measured on a base 10 logarithmic scale
- The base increases ten-fold for every ten dB
measured - The formula for calculating dB is
- dB 10 log10 (Pfinal/Pref)
11Calculating dB
- dB The amount of decibels.
- This usually represents a loss in power such as
when the wave travels or interacts with matter,
but it can also represent a gain as when
traveling through an amplifier. - Pfinal The final power.
- This is the delivered power after some process
has occurred. - Pref The reference power.
- This is the original power.
- There are also some general rules for
approximating the dB and power relationship - An increase of 3 dB Double the power
- A decrease of 3 dB Half the power
- An increase of 10 dB Ten times the power
- A decrease of 10 dB One-tenth the power
12Decibel Reference
The power gain or loss in a signal is determined
by comparing it to this fixed reference point,
the milliwatt.
13dB milliWatt (dBm)
- dB milliWatt (dBm) This is the unit of
measurement for signal strength or power level. - If a person receives a signal at one milliwatt,
this is a loss of zero dBm. However, if a person
receives a signal that is 0.001 milliwatt, then a
loss of 30 dBm occurs. - This loss is represented as -30 dBm.
- To reduce interference with others, the 802.11b
WLAN power levels are limited to the following - 36 dBm EIRP by the FCC
- 20 dBm EIRP by ETSI
EIRP Effective Isotropic Radiated Power
14dB dipole (dBd)
- dB dipole (dBd) This refers to the gain an
antenna has, as compared to a dipole antenna at
the same frequency. - A dipole antenna is the smallest, least gain
practical antenna that can be made.
15dB isotropic (dBi)
- dB isotropic (dBi) This refers to the gain a
given antenna has, as compared to a theoretical
isotropic, or point source, antenna. - An isotropic antenna cannot exist in the real
world, but it is useful for calculating
theoretical coverage and fade areas. - A dipole antenna has 2.14 dB gain over a 0 dBi
isotropic antenna. - For example, a simple dipole antenna has a gain
of 2.14 dBi or 0 dBd.
16Effective Isotropic Radiated Power
- Effective Isotropic Radiated Power (EIRP) is
defined as the effective power found in the main
lobe of a transmitter antenna. - EIRP is equal to the sum of the antenna gain, in
dBi, plus the power level, in dBm, into that
antenna.
http//en.wikipedia.org/wiki/EIRP
17Gain
- Gain This refers to the amount of increase in
energy that an antenna adds to an RF signal. - There are different methods for measuring gain,
depending on the chosen reference point. - Cisco Aironet wireless is standardized on dBi to
specify gain measurements. - Some antennas are rated in dBd.
- To convert any number from dBd to dBi, simply add
2.14 to the dBd number.
18Electromagnetic Waves EM Waves
- The EM spectrum is simply a name that scientists
have given to the set of all types of radiation. - Radiation is energy that travels in waves and
spreads out over distance. - All EM waves travel at the speed of light in a
vacuum and have a characteristic wavelength (?)
and frequency (f) which can be determined by
using the following equation - c ? x f, where c the speed of light (3 x 108
m/s) - EM waves exhibit the following properties
- reflection or bouncing
- refraction or bending
- diffraction or spreading around obstacles
- scattering or being redirected by particles
19EM Radiation
EM waves can be classified by their frequency in
Hz or their wavelength in meters.
20Eight EM Sections
- Power waves These are the slowest of all EM
radiation and therefore also have the lowest
energy and the longest wavelength. - Radio waves This is the same kind of energy
that radio stations emit into the air for a radio
to capture and play. However, other things such
as stars and gases in space also emit radio
waves. Many communication functions use radio
waves. - Microwaves Microwaves will cook popcorn in just
a few minutes. In space, astronomers use
microwaves to learn about the structure of nearby
galaxies. - Infrared (IR) light Infrared is often thought
of as being the same thing as heat, because it
makes our skin feel warm. In space, IR light maps
the dust between stars. - Visible light This is the range that is visible
to the human eye. Visible radiation is emitted by
everything from fireflies to light bulbs to
stars. It is also emitted by fast-moving
particles hitting other particles. - Ultra-violet (UV) light It is well known that
the sun is a source of ultraviolet (UV)
radiation. It is the UV rays that cause our skin
to burn. Stars and other hot objects in space
emit UV radiation. - X-rays A doctor uses X-rays to look at bones
and a dentist uses them to look at teeth. Hot
gases in the universe also emit X-rays. - Gamma rays Natural and man-made radioactive
materials can emit gamma rays. Big particle
accelerators that scientists use to help them
understand what matter is made of can sometimes
generate gamma rays. However, the biggest
gamma-ray generator of all is the universe, which
makes gamma radiation in many ways.
Increasing frequency and energy / decreasing
wavelength
The EM spectrum has eight major sections, which
are presented in order of increasing frequency
and energy, and decreasing wavelength
21ISM Bands of Spectrum
In the US, it is the FCC that regulates spectrum
use. In Europe, the European Telecommunications
Standards Institute (ETSI) regulates the spectrum
usage.
22Noise
- A very important concept in communications
systems, including WLANs, is noise. - In the context of telecommunications, noise can
be defined as undesirable voltages from both
natural and technological sources. - Since noise is just another signal that produces
waves, the noise will be added to other signals
including wireless data! - Sources of noise in a WLAN include the
electronics in the WLAN system, plus radio
frequency interference (RFI), and electromagnetic
interference (EMI) found in the WLAN environment.
- Gaussian, or white noise affects all frequencies
equally. - Narrowband interference would only interfere with
some radio stations or channels of a WLAN.
23Modulation Techniques
- A carrier frequency is an electronic wave that is
combined with the information signal and carries
it across the communications channel. - For WLANs, the carrier frequency is 2.4 GHz or 5
GHz. - Using carrier frequencies in WLANs has added
complexity because the carrier frequency is
changed by frequency hopping or direct sequence
chipping, to make the signal more immune to
interference and noise.
24Spread Spectrum (SS)
- Spread-spectrum technology makes data
transmission possible in the ISM bands - SS diffuses radio signals over a wide range of
frequencies - The FCC requires that devices using the ISM bands
use SS transmissions for data - By spreading data transmission over a wide range
of frequencies, the transmission will look like
noise to other non 802.11 devices - This also allows spread-spectrum devices to be
more resilient to noise
25Spread-Spectrum Technologies
- 802.11 uses three types of spread-spectrum
technologies - Frequency Hopping (FHSS) systems jump from one
frequency to another legacy - Direct Sequence (DSSS) spread the signal over a
wide range of frequencies 802.11b/g - Orthogonal Frequency Division Multiplexing (OFDM)
802.11a/g
26Frequency Hopping
- Frequency hopping (FH) systems are the least
costly to produce but allow for the lowest data
rates - FH rapidly changes from one frequency to another
during data transmission using a predetermined
pattern - This pattern is pseudorandom which means it is
practically, never the same - The receiver radio is synchronized to the hopping
sequence of the transmitting radio to enable the
receiver to be on the right frequency at the
right time. - The amount of time a sender stays at a particular
frequency is known as the dwell time
27FHSS
- FHSS is a spread spectrum technique that uses
frequency agility to spread data over more than
83 MHz of spectrum. - Frequency agility is the ability of a radio to
change transmission frequency quickly, within the
useable RF frequency band.
28FHSS (cont.)
- Frequency hopping avoids interference between two
stations using the same band by using different
hopping sequences - If any two stations do interfere with each other,
the interference is for such a short time that it
appears as transient noise
29Direct Sequence Spread Spectrum
- In the US, each channel operates from one of 11
defined center frequencies and extends 11 MHz in
each direction - For example, Channel 1 operates from 2.401 GHz to
2.423 GHz, which is 2.412 GHz plus or minus 11
MHz. Channel 2 uses 2.417 plus or minus 11 MHz,
and so on. - There is significant overlap between adjacent
channels. Center frequencies are only 5 MHz
apart, yet each channel uses 22 MHz of analog
bandwidth. - In fact, channels should be co-located only if
the channel numbers are at least five apart.
Channels 1 and 6 do not overlap, Channels 2 and 7
do not overlap, and so on. - In Europe, ETSI has defined a total of 14
channels, which allows for four different sets of
three non-overlapping channels.
30Direct Sequence Spread-Spectrum (DSSS)
- Whereas FHSS uses each frequency for a short
period of time in a repeating pattern, DSSS uses
a wide frequency range of 22 MHz all of the time. - Non-overlapping channels have 25 MHz of frequency
between them which gives them a 3MHz buffer - Each data bit becomes a chipping sequence, or a
string of chips that are transmitted in parallel,
across the frequency range. - This is also referred to as the chipping code
31Chipping Code Example
1 00110011011 0 11001100100 0
11001100100 1 00110011011
32802.11b ChannelsFCC
332.4 GHz Channel Sets
Regulatory Domain
Center Frequency
Channel Identifier
Americas
Europe, Middle East and Asia
Japan
Israel
X X X X X X X X X X X X X
X X X X X X X X X X X X X X
1 2 3 4 5 6 7 8 9 10 11 12 13 14
2412 MHz 2417 MHz 2422 MHz 2427 MHz 2432 MHz 2437
MHz 2442 MHz 2447 MHz 2452 MHz 2457 MHz 2462
MHz 2467 MHz 2472 MHz 2484 MHz
X X X X X X X X X X X
X X X X X X X
34Channels- 2.4 GHz DSSS
- 11 Channels each channel 22 MHz wide
- 1 set of 3 non-overlapping channels
-
- 14 Channels each channel 22 MHz wide
- 4 sets of 3 non-overlapping channels, only one
set used at a time
- 11 chips per bit means each bit sent
redundantly - 11 Mbps data rate
- 3 access points can occupy same area
35Non-overlapping Channels - again
36802.11b Throughput
- 802.11b uses three different types of modulation,
depending upon the data rate used - Binary phase shift keyed (BPSK) BPSK uses one
phase to represent a binary 1 and another to
represent a binary 0, for a total of one bit of
binary data. - BPSK is utilized to transmit data at 1 Mbps.
- Quadrature phase shift keying (QPSK) With QPSK,
the carrier undergoes four changes in phase and
can thus represent two binary bits of data. - QPSK is utilized to transmit data at 2 Mbps.
- Complementary Code Keying (CCK) CCK uses a
complex set of functions known as complementary
codes to send more data by representing 4 or 8
binary bits. - CCK is can transmit data at 5.5 Mbps (4 bits) and
11 Mbps (8bits).
37Complementary Code Keying (CCK)
- CCK is an alternative encoding method to PSK
which can encode 4 to 8 bits into a code word - The benefit of CCK is that it uses an 8-bit
encoding scheme instead of an 11-bit encoding
scheme to produce 1.375 times as much data
transmission as PSK - When CCK encodes 4 binary bits at a time it
produces 5.5Mbps of throughput and when CCK
encodes 8 bits at a time it produces 11Mbps of
throughput
38DSSS Modulation and Data Rates
The D in the beginning stands for Differential
http//en.wikipedia.org/wiki/Phase-shift_keying
39Orthogonal Frequency Division Multiplexing
- The 802.11a and 802.11g standards both use
orthogonal frequency division multiplexing
(OFDM), to achieve data rates of up to 54 Mbps. - OFDM works by breaking one high-speed data
carrier into several lower-speed subcarriers,
which are then transmitted in parallel. - Each high-speed carrier is 20 MHz wide and is
broken up into 52 subchannels, each approximately
300 KHz wide - OFDM uses 48 of these subchannels for data, while
the remaining four are used for error correction.
http//www.wave-report.com/tutorials/OFDM.htm
http//en.wikipedia.org/wiki/COFDM
40OFDM Subcarriers
41802.11a Modulation
- The 802.11a standard specifies that all
802.11a-compliant products must support three
basic data rates which include - Binary Phase Shift Keying (BPSK) encodes 125
Kbps of data per channel, resulting in a
6,000-Kbps, or 6 Mbps Quadrature Phase Shift
Keying (QPSK) encodes to 250 Kbps per channel,
yielding a 12 Mbps data rate. - 16-level Quadrature Amplitude Modulation
(16-QAM) encodes 4 bits per hertz, achieving a
data rate of 24 Mbps. - In addition, the standard also lets the vendor
extend the modulation scheme beyond 24 Mbps. - 64-level Quadrature Amplitude Modulation
(64-QAM), which yields 8 bits per cycle or 10
bits per cycle, for a total of up to 1.125 Mbps
per 300-KHz channel. With 48 channels, this
results in a 54 Mbps data rate.
42Refraction
- A surface is considered smooth if the size of
irregularities is small relative to the
wavelength. Otherwise, it is considered to be
rough. - Electromagnetic waves are diffracted around
intervening objects. - If the object is small relative to the
wavelength, it has very little effect and the
wave will pass around the object undisturbed. - However, if the object is large a shadow will
appear behind the object and a significant amount
of energy is reflected back toward the source.
43Refraction
Sub-Refraction
Refraction (straight line)
Normal Refraction
Earth
- Refraction (or bending) of signals is due to
temperature, pressure, and water vapor content in
the atmosphere. - Amount of refractivity depends on the height
above ground. - Refractivity is usually largest at low
elevations. - The refractivity gradient (k-factor) usually
causes microwave signals to curve slightly
downward toward the earth, making the radio
horizon father away than the visual horizon. - This can increase the microwave path by about 15,
44Refraction
- Radio waves also bend when entering different
materials. - This can be very important when analyzing
propagation in the atmosphere. - It is not very significant in WLANs, but it is
included here, as part of a general background
for the behavior of electromagnetic waves.
45Reflection
- Reflection is the light bouncing back in the
general direction from which it came. - When waves travel from one medium to another, a
certain percentage of the light is reflected. - This is called a Fresnel reflection.
46Reflected Waves
- When a wireless signal encounters an obstruction,
normally two things happen - Attenuation The shorter the wavelength of the
signal relative to the size of the obstruction,
the more the signal is attenuated. - Reflection The shorter the wavelength of the
signal relative to the size of the obstruction,
the more likely it is that some of the signal
will be reflected off the obstruction.
47Microwave Reflections
- Microwave signals
- Frequencies between 1 GHz 30 GHz (this can vary
among experts). - Wavelength between 12 inches down to less than 1
inch. - Microwave signals reflect off objects that are
larger than their wavelength, such as buildings,
cars, flat stretches of ground, and bodes of
water. - Each time the signal is reflected, the amplitude
is reduced.
48Reflection
- Reflection is the light bouncing back in the
general direction from which it came. - Consider a smooth metallic surface as an
interface. - As waves hit this surface, much of their energy
will be bounced or reflected. - Think of common experiences, such as looking at a
mirror or watching sunlight reflect off a
metallic surface or water. - When waves travel from one medium to another, a
certain percentage of the light is reflected. - This is called a Fresnel reflection (Fresnel
coming later).
49Reflection
- Radio waves can bounce off of different layers of
the atmosphere. - The reflecting properties of the area where the
WLAN is to be installed are extremely important
and can determine whether a WLAN works or fails. - Furthermore, the connectors at both ends of the
transmission line going to the antenna should be
properly designed and installed, so that no
reflection of radio waves takes place.
50Reflections
51Microwave Reflections
Multipath Reflection
- Advantage Can use reflection to go around
obstruction. - Disadvantage Multipath reflection occurs when
reflections cause more than one copy of the same
transmission to arrive at the receiver at
slightly different times.
52Diffraction
- The spreading out of a wave around an obstacle is
called diffraction - This spreading is sometimes referred to as
bending around an obstacle. - Radio waves undergo both small-scale and
large-scale diffraction. - An example of small-scale diffraction is radio
waves in a WLAN spreading around indoors. - An example of large-scale diffraction is radio
waves spreading around a mountain peak, to an
inaccessible area.
53Diffraction
Diffracted Signal
- Diffraction of a wireless signal occurs when the
signal is partially blocked or obstructed by a
large object in the signals path. - A diffracted signal is usually attenuated so much
it is too weak to provide a reliable microwave
connection. - Do not plan to use a diffracted signal, and
always try to obtain an unobstructed path between
microwave antennas.
54Multipath
- In many common WLAN installations, the radio
waves emitted from a transmitter are traveling at
different angles. - They can reflect off of different surfaces and
end up arriving at the receiver at slightly
different times. - Multipath interference can cause high RF signal
strength, but poor signal quality levels. - If this interference is destructive enough, the
messages will not get through.
55Multipath Reflection
- Reflected signals 1 and 2 take slightly longer
paths than direct signal, arriving slightly
later. - These reflected signals sometimes cause problems
at the receiver by partially canceling the direct
signal, effectively reducing the amplitude. - The link throughput slows down because the
receiver needs more time to either separate the
real signal from the reflected echoes or to wait
for missed frames to be retransmitted. - Solution discussed later.
56Path-Loss
- A crucial factor of any communications system is
how much power from the transmitter actually
reaches the receiver. - All of the previous different effects discussed
earlier can be combined and described by what are
known as path loss calculations. - Path loss calculations determine how much power
is lost along the communications path. - Free-space loss (FSL) is the signal attenuation
that would result if all absorbing, diffracting,
obstructing, refracting, scattering, and
reflecting influences were sufficiently removed
so as to have no effect on propagation. - - The formula is as follows
- FSL (in dB) 20 log10(f) 20 log10(d) 36.6
57Path-Loss (cont.)
- Every time the distance from the transmitter to
the receiver is doubled, the signal level is
lowered (or increased) by 6 dB. - Also, for each frequency, there is a series of
wavelengths, where energy will escape out of the
transmission line and enter the surrounding
space. This is called the launch effect. - The launch effect typically occurs at multiples
of half-wavelengths of the signal.
58Summary
- This module covered the mathematics and physics
necessary for understanding how WLANs operate.
Although it is not usually necessary to perform
complex calculations to install a WLAN, an
understanding of the underlying principles makes
it easier to account for the many factors that
can interfere with the proper operation of the
WLAN. - When performing a site survey for a new or
existing WLAN, be sure to take into account
factors such as refraction, reflection, and
multipath distortion that were discussed in this
module.