This antenna reference guide is intended to provide information to assist in understanding the
issues and concerns ofantennasusedwithaCiscoAironet
Bridge system. It details deployment and design, limitations, and capabilities, and basic
theories of antennas. This document also contains information on the Cisco antennas and
accessories as well as installation scenarios, regulatory information, and technical
specifications and diagrams of the available antennas.
Overview of Antennas
Each Cisco Aironet radio product is designed to perform in a variety of environments.
Implementingtheantennasystemcan greatly improvecoverage and performance.Tooptimize
the overall performance of a Cisco wireless LAN, it is important to understand how to
maximize radio coverage with the appropriate antenna selection and placement. An
antenna system comprisesnumerous components,including theantenna, mountinghardware,
connectors,antenna cabling,and in some cases, alightning arrestor.For additionalconsultation,
please contact your authorized Cisco Aironet partner. Cisco Partners can provide onsite
engineering assistance for complex requirements.
In the mid 1980s, the FCC modified Part 15 of the radio spectrum regulation, which governs unlicensed devices. The
modification-authorized wireless network products to operate in the Industrial, Scientific, and Medical (ISM) bands using
spread spectrum modulation. This type of modulation had formerly been classified and permitted only in military products.
The ISM frequencies are in three different bands, located at 900 MHz, 2.4 GHz, and 5 GHz. This document covers only the
2.4GHz band.
The ISM bands typically allow users to operate wireless products without requiring specific licenses, but this will vary in some
countries. In the U.S., there is no requirement for FCC licenses. The products themselves must meet certain requirements to be
certified for sale, such as operation under 1 watt transmitter output power (in the U.S.) and maximum antenna gain or EIRP ratings.
Radio Frequency Fundamentals
Radio Frequency (RF) engineering is a very complex field of study and far too involved to explain in detail here.
2.4GHz Spectrum
The Cisco Aironet 350 Series uses RF spectrum in the 2.4 GHz unlicensed ISM band. In the U.S., three bands are defined as
unlicensed and known as the ISM bands (Industrial, Scientific, and Medical). The ISM bands are as follows:
• 900 MHz (902-928MHz)
• 2.4 GHz (2.4 - 2.4835 GHz)—IEEE 802.11b
• 5 GHz (5.15-5.35 and 5.725-5.825 GHz)—IEEE 802.11a, HIPERLAN/1 and HIPERLAN/2. This band is also known
as the UNII band.
Each range has different characteristics. The lower frequencies exhibit better range, but with limited bandwidth and hence lower
data rates. The higher frequencies have less range and subject to greater attenuation from solid objects.
Direct Sequence Spread Spectrum
The Direct Sequence (DS) Spread Spectrum approach involves encoding redundant information into the RF signal. Every data bit
is expanded to a string of chips called a chipping sequence or Barker sequence. The chipping rate as mandated by the U.S. FCC is
10 chips at the 1 and 2 Mbps rates and 8 chips at the 11 Mbps rate. So, at 11 Mbps, 8 bits are transmitted for every one bit of data.
The chipping sequence is transmitted in parallel across the spread spectrum frequency channel.
Frequency Hopping Spread Spectrum
Frequency Hopping (FH) Spread Spectrum uses a radio that moves or hops from one frequency to another at predetermined times
and channels. The regulations require that the maximum time spent on any one channel is 400mS. For the1- and 2-Mb FH systems,
the hopping pattern must include 75 different channels, and must use every channel before reusing any one. For the Wide Band
Frequency Hopping (WBFH) systems, that permit up to 10-Mb data rates, the rules require use of at least 15 channels, and they
cannot overlap. With only 83MHz of spectrum, it limits the systems to 15 channels, thereby causing scalability issues.
In every case, for the same transmitter power and antennas, a DS system will have greater range, scalability and throughput than
an FH system. For this reason Cisco has chosen to support only DS systems in the Spread Spectrum products.
An antenna gives the wireless system three fundamental properties—gain, direction, and polarization. Gain is a measure of increase
in power. Direction is the shape of the transmission pattern. The good analogy for an antenna is the reflector in a flashlight. The
reflector concentrates and intensifies the light beam in a particular direction similar to what a parabolic dish antenna would to a
RF source in a radio system.
Antennas are rated in comparison to isotropic or dipole antennas. An isotropic antenna is a theoretical antenna with a uniform
three-dimensional radiation pattern (similar to a light bulb with no reflector). dBi is used to compare the power level of a given
antenna to the theoretical isotropic antenna. The FCC in the U.S. uses dBi in its calculations. An isotropic antenna is said to have
a power rating of 0 dB, for example, zero gain/loss when compared to itself.
Unlike isotropic antennas, dipole antennas are real antennas (dipole antennas are standard on Aironet Access Points, Base Stations
and WorkgroupBridges). Dipole antennas have a different radiation pattern compared to isotropic antennas. The dipole radiation
patternis 360 degreesin the horizontalplane and 75degrees in the vertical plane (assuming the dipole antenna is standing vertically)
and resembles a donut in shape. Because the beam is “slightly” concentrated, dipole antennas have a gain over isotropic antennas
of 2.14 dB in the horizontal plane. Dipole antennas are said to have a gain of 2.14 dBi (in comparison to an isotropic antenna).
Some antennas are rated in comparison to dipole antennas. This is denoted by the suffix dBd. Hence, dipole antennas have a gain
of 0 dBd (= 2.14 dBi).
Note that the majority of documentation refers to dipole antennas as having a gain of 2.2 dBi. The actual figure is 2.14 dBi, but is
often rounded up.
Type of Antennas
Ciscooffers several different styles of antennas foruse in the 2.4GHz ranges. Every antenna offered for salehas been FCC approved.
Each type of antenna will offer different coverage capabilities. As the gain of an antenna increases, there is some tradeoff to its
coverage area. Usually gain antennas offer longer coverage distances, but only in a certain direction. The radiation patterns below
will help to show the coverage areas of the styles of antennas that Cisco offers, omni-directional, yagis and patch antennas.
Omni-Directional Antennas
An omni-directional antenna is designed to provide a 360 degree radiation pattern. This type of antenna is used when coverage in
all directions from the antenna is required. The standard 2.14 dBi “Rubber Duck” is one style of an omni-directional antenna.
Directionalantennas come in many differentstyles and shapes. An antennadoes not offerany added power to thesignal, and instead
simply redirects the energy it received from the transmitter. By redirecting this energy, it has the effect of providing more energy in
one direction, and less energy in all other directions. As the gain of a directional antenna increases, the angle of radiation usually
decreases, providing a greater coverage distance, but with a reduced coverage angle. Directional antennas include yagis, patch
antennas, and parabolic dishes. Parabolic dishes have a very narrow RF energy path and the installer must be accurate in aiming
these at each other.
Figure 2 Directional Patch Antenna
Figure 3 YAGI Antenna
28 – 80 degrees at 2.4 GHz
68 – 78 degrees at 900 MHz
Directional Yagi
Diversity Antenna Systems
Diversity antenna systems are used to overcome a phenomenon known as multipath distortion of multipath fading. It uses two
identical antennas, located a small distance apart, to provide coverage to the same physical area.
Multipath interference occurs when an RF signal has more than one path between a receiver and a transmitter. This occurs in sites
that have a large amount of metallic or other RF reflective surfaces.
Just as light and sound bounce off of objects, so does RF. This means there can be more than one path that RF takes when going
from a TX to and RX antenna. These multiple signals combine in the RX antenna and receiver to cause distortion of the signal.
Multipath interference can cause the RF energy of an antenna to be very high, but the data would be unrecoverable. Changing the
type of antenna, and location of the antenna can eliminate multipath interference.
Figure 4 Multipath Distortion
Ceiling
Received Signals
TXRX
Time
Combined Results
Obstruction
Floor
You can relate this to a common occurrence in your car. As you pull up to a stop, you may notice static on the radio. But as you
move forward a few inches or feet, the station starts to come in more clearly.By rolling forward, you move the antenna slightly, out
of the point where the multiple signals converge.
A diversity antenna system can be compared to a switch that selects one antenna or another,never both at the same time. The radio
in receive mode will continually switch between antennas listening for a valid radio packet. After the beginning sync of a valid
packet is heard, the radio will evaluate the sync signal of the packet, on one antenna, then switch to the other antenna and evaluate.
Then the radio will select the best antenna, and use only that antenna for the remaining portion of that packet.
On transmit, the radio will select the same antenna it used the last time it communicated to that given radio. If a packet fails, it will
switch to the other antenna and retry the packet.
One caution with diversity, it is not designed for using two antennas, covering two different coverage cells. The problem in using it
this way, is that if antenna #1 is communicating to device #1, while device #2 (which is in the antenna #2 cell) tries to communicate,
antenna #2 is not connected (due to the position of the switch), and the communication fails. Diversity antennas should cover the
same area, from only a slightly different location.
Time
With the introduction of the latest DS physical layer chips, and the use of diversity antenna systems, DS systems have equaled or
surpassed FH in areas of how Multipath interference is handled. While the introduction of WBFH does increase the bandwidth of
theFH systems, it drastically effects the ability tohandle multipath issues,further reducing its range compared to present DSsystems
in high RF reflective sites.
Before the physical environment is examined, it is critical to identify the mobility of the application, the means for coverage and
system redundancy. An application such as point-to-point which connects two or more stationary users may be best served by a
directional antenna, while mobile users will generally require a number of omni-directional micro cells. These individual micro cells
can be linked together seamlessly via the wired LAN infrastructure or by using the wireless repeater functionality built into every
Cisco Aironet Access Point. All Cisco Aironet Wireless LAN products are designed to support complex multicell environments
transparently through the Cisco patented MicroCellular Architecture.
The Physical Environment
Once mobility issues are resolved, the physical environment must be examined. While the area of coverage is the most important
determining factor for antenna selection, it is not the sole decision criteria. Building construction, ceiling height, and internal
obstructions, available mounting locations and customers aesthetic desires must be considered. Cement and steel construction have
different radio propagation characteristics. Internal obstructions such as product inventory and racking in warehousing
environments are factors. In outdoor environments, many objects can affect antenna patterns, such as trees, vehicles, buildings, and
trains, to name just a few.
The Network Connections
The access points use a 10/100 Mb Ethernet connection. Typically the access point is in the same location as the antenna. While it
may seem that the best place to put the access point is in a wiring closet with the other networks components such as switches, hubs
and routers, this is not the case. Placement of the antenna in an area that provides the best coverage (determined by a site survey)
is required. Therefore many people new to wireless LANs want to locate the access points in the wiring closet and connect the
antenna via RF coax. Antenna cable introduces losses in the antenna system on both the transmitter and the receiver. As the length
of cable increases, so does the amount of loss introduced. To operate at optimum efficiency, cable runs should be kept as short as
possible. (See the section on cabling later in this document).
Building Construction
The density of the materials used in a building’s construction determines the number of walls the RF signal can pass through and
still maintain adequate coverage. Here are just a few examples. Actual effect on the RF must be tested at the site, and therefore a
site survey is suggested.
Paper and vinyl walls have very little affect on signal penetration. Solid walls and floors and pre-cast concrete walls can limit signal
penetration to one or two walls without degrading coverage. This may vary widely based any steel reinforcing within the concrete.
Concreteand concrete block walls may limit signal penetration to three or four walls. Wood or drywall typically allows for adequate
penetrationof five or six walls. A thick metal wall causes signalsto reflect off,resulting in poorpenetration. Steel reinforced concrete
flooring will restrict coverage between floors to perhaps one or two floors.
Recommendations for some common installation environments are outlined below:
• Warehousing/Manufacturing—In most cases, these installations require a large coverage area. Experience has shown that an
omni-directional antenna mounted at about 20 to 25 feet, typically provides the best overall coverage. Of course this will also
depend upon the height of the racking, material on the rack and ability to locate the antenna at this height. Mounting the
antenna higher will sometimes actually reduce coverage as the angle of radiation from the antenna is more outward than down.
The antenna should be placed in the center of the desired coverage cell and in an open area for best performance. In cases where
the radio unit will be located against a wall, a directional antenna such as a patch or yagi can be used for better penetration of
the area. The coverage angle of the antenna will affect the coverage area.
• Small Office/Small Retail—The standard dipole may provide adequate coverage in these areas depending upon the location of
the radio device. However, in a back corner office a patch antenna may provide better coverage. It can be mounted to the wall
above most obstructions for best performance. Coverage of this type antenna depends upon the surrounding environment.
• Enterprise/ Large Retail—In most cases, these installations require a large coverage area. Experience has shown that
omni-directional antennas mounted just below the ceiling girders or just below the drop ceiling typically provide the best
coverage (this will vary with stocking, type of material and building construction). The antenna should be placed in the center
of the desired coverage cell and in an open area for best performance. In cases where the radio unit will be located in a corner,
or off to one end of the building a directional antenna such as a patch or yagi can be used for better penetration of the area.
Also for areas that are long and narrow, such as long rows of racking, a directional antenna, used at one end may provide better
coverage. The radiation angle of the antennas will also affect the coverage area.
• Point-to-Point—When connecting two points together (such as an Ethernet bridge), the distance, obstructions, and antenna
location must be considered. If the antennas can be mounted indoors and the distance is very short (several hundred feet), the
standard dipole or mast mount 5.2 dBi omni-directional may be used. An alternative is to use two patch antennas. For very long
distances (1/2 mi. or more) directional high gain antennas must be used. These antennas should be installed as high as possible,
and above obstructions such as trees, buildings, and so on; and if the directional antennas are used, they must be aligned so that
their main radiated power lobes are directed at each other. With a line-of-site configuration, distances of up to 25 miles at
2.4GHz can be reached using parabolic dish antennas, if a clear line-of-site is maintained. With the use of directional antennas,
you are subject to fewer interference possibilities, and less likely to cause interference to anyone else.
• Point-to-Multipoint Bridge—In this case (in which a single point is communicating to several remote points) the use of an
omni-directional antenna at the main communication point must be considered. The remote sites can use a directional antenna
that is directed at the main point antenna.
Cabling
As stated above, cabling introduces losses into the system, negating some of the gain an antenna introduces, and reducing range of
the RF coverage.
Interconnect Cable
Attached to all antennas (except the standard dipoles), this cable provides a 50 Ohm impedance to the radio and antenna, with a
flexible connection between the two items. It has a high loss factor and should not be used except forvery short connections (usually
less than 10 feet). Typical length on all antennas is 36" (or 12" on some outdoor antennas).
Low Loss/Ultra Low Loss Cable
This cable provides a much lower loss factor than the interconnect cable, and it is used when the antenna must be placed at any
distance from the radio device. While it is a low loss cable, it should still be kept to a minimum length. This cable is the only cable
type supplied by Cisco for mounting the antenna away from the radio unit. It is offered in four different lengths with one RTNC
plug and one RTNC jack connector attached. This allows for connection to the radio unit and to the interconnect cable supplied
on the antennas.
Connectors
Connectors used on equipment manufactured after June 1994 must be unique, nonstandard connectors (per FCC and DOC
regulations).Therefore, Cisco Aironet products use a connector known as Reverse-TNC (RTNC)connectors. Whilethey are similar
to the normal TNC connectors, they cannot be mated to the standard connectors. To ensure compatibility with Cisco Aironet
products, use antennas and cabling from Cisco.
Each antenna requires some type of mounting. The standard dipole antenna simply connects to the RTNC connector on the back
of the unit. The 5.2 dBi mast mount omni and the yagi antennas are designed to mount to a mast up to 1.5 inches, and each comes
with mounting hardware for attachment. The 13.5 dBi yagi has an articulating mount option listed in the back of this document.
For most indoor applications, a .75" or 1" electrical conduit provides a suitable mounting. For outdoor application, a heavy
galvanized or aluminum wall mast should be used that will withstand the wind loading rating of the selected antenna. Patch
antennas are designed to mount flat against a wall orceiling. Ceiling mount antennas are equipped with a drop ceiling cross member
attachment. The 21 dBi Parabolic Dish mounts to a 1.625" to a 2.375" mast. Fine threaded turnbuckles allow accurate aiming of
the antenna.
Lightning Arrestors
When using outdoor antenna installations, it is always possible that an antenna will suffer damage from potential charges
developing on the antenna and cable, or surges induced from nearby lightning strikes. The Aironet Lightning Arrestor is designed
to protect radio equipment from static electricity and lightning induced surges that travel on coaxial transmission lines. It protects
equipment from surges up to 5,000 Amperes. This will not prevent damage in the event of a direct lightning hit.
Theory of Operation
The Cisco Aironet Lightning Arrestor prevents energy surges from reaching the RF equipment by the shunting effect of the device.
Surges are limited to less than 50 volts, in about .0000001 seconds (100 nano seconds). A typical lightning surge is about .000002
(2 micro seconds).
The accepted IEEE transient (surge) suppression is .000008 seconds (8 micro seconds). The Lightning Arrestor is a 50 ohm
transmission line with a gas discharge tube positioned between the center conductor and ground. This gas discharge tube changes
from an open circuit to a short circuit almost instantaneously in the presence of voltage and energy surges, providing a path to
ground for the energy surge.
Installation
This Arrestor is designed to be installed between your outdoor antenna cable and the Aironet Wireless Device. Installation should
be indoors, or inside a protected area. A good ground must be attached to the Arrestor. This can be accomplished by use of a ground
lug attached to the Arrestor, and a heavy wire (#6 solid copper) connecting the lug to a good earth ground. See Figure 5.
Understanding RF Power Values
Radio Frequency signals are subject to various losses and gains as they pass from transmitter through cable to antenna, through air
(or solid obstruction), to receiving antenna, cable and receiving radio. With the exceptionof solid obstructions, most of these figures
and factors are known and can be used in the design process to determine whether an RF system such as a WLAN will work.
Decibels
The Decibel (dB) scale is a logarithmic scale used to denote the ratio of one power value to another—for example:
• dB = 10 log10 (Power A/Power B)
An increase of 3 dB indicates a doubling (2x) of power. An increase of 6 dB indicates a quadrupling (4x) of power. Conversely, a
decrease of 3 dB is a halving (1/2) of power, and a decrease of 6 dB is a quarter (1/4) the power. Some examples are shown below
in Table 1.
Table 1 Decibel Values and Corresponding Factors
IncreaseFactorDecreaseFactor
0 dB1 x (same)0 dB1 x (same)
1 dB1.25 x-1 dB0.8 x
3 dB2 x-3 dB0.5 x
6 dB4 x-6 dB0.25 x
10 dB10 x-10 dB0.10 x
12 dB16 x-12 dB0.06 x
20 dB100 x-20 dB0.01 x
30 dB1000 x-30 dB0.001 x
40 dB10,000 x-40 dB0.0001 x
WLAN equipment is usually specified in decibels compared to known values.
TransmitPower and Receive Sensitivity are specified in “dBm,” where “m” means 1 milliWatt (mW). So, 0 dBm is equal to 1 mW;
3 dBm is equal to 2 mW; 6 dBm is equal to 4 mW, and so on. For example, a Cisco Aironet 350 Series Access Point at 100 mW
transmit power is equal to 20 dBm. dBw is occasionally used for the same purpose, but as a comparison against 1 Watt(1000 mW).
Common mW values to dBm values are shown below in Table 2.
1. The 1, 2, 5, 20, 50, and 100 mW transmit power settings for the Cisco Aironet 350 Series radios correspond to 0, 3, 7, 13, 17, and 20 dBm.
1
1
-17 dBm0.02 mw
-20 dBm0.01 mW
Outdoor Range
The range of a wireless link is dependent upon the maximum allowable path loss. For outdoor links this is a straightforward
calculation as long as there is clear line of sight between the two antennas with sufficient clearance for the Fresnel zone.
For line of sight, you should be able to visibly see the remote locations antenna from the main site. (Longer distance may require
the use of binoculars). There should be no obstructions between the antennas themselves. This includes trees, buildings, hills, and
so on.
As the distance extends beyond 6 miles, the curve of the earth (commonly called earth bulge) affects installation, requiring antennas
to be placed at higher elevations.
Fresnel zone is an elliptical area immediately surrounding the visual path. It varies depending on the length of the signal path and
the frequency of the signal. The Fresnel zone can be calculated, and it must be taken into account when designing a wireless link.
Figure 6 Fresnel Zone
Fresnel Zone
Raise Antennas
Based on both line of sight and Fresnel zone requirements, the following table provides a guideline on height requirements for
antennas as various distances. This refers to height above any obstacles located in the middle of the RF path.
Table 3
Wireless Link Distance
(miles)
110313
530535
10441357
15552883
206550115
257278150
Approx. Value “F” (60%
Fresnel Zone) ft. at 2.4 GHz
Approx. Value “C”
(Earth Curvature)
Value “H” (mounting Ht.)
ft. with no obstructions
Cisco.com provides an Outdoor Bridge Range Calculation Utility that calculates the Fresnel zone and maximum range based upon
cable types and lengths; transmitter and receiver models; and antennas. The utility can be found at:
www.cisco.com/go/aironet/calculation.
Note that as path loss increases and distance decreases with frequency, these distances are only applicable to the 2.4 GHz band. A
10dB fade margin is included for dependable communications in all weather conditions. The distances given are only theoretical
and should only be used to determine the feasibility of a particular design.
Outdoors, every increase of 6 dB will double the distance. Every decrease of 6 dB will halve the distance. Shorter cable runs and
higher gain antennas can make a significant difference to the range.
• Connectors—In 1985, the FCC enacted standards for the commercial use of spread spectrum technology in the ISM frequency
bands. Spread spectrum is currently allowed in the 900, 2400, and 5200 MHz bands. In 1989, the FCC drafted an amendment
governingspread spectrum systems in the unlicensed ISM band. This amendment iscommonly referred to as the “new” or “’94”
rules because it impacts all spread spectrum products manufactured after June 23, 1994. Products manufactured before June 23
are not affected by the amendment. Congress enacted this amendment into law in 1990. The FCC 1994 rules are intended to
discourage use of amplifiers, high-gain antennas or other means of significantly increasing RF radiation. The rules are further
intended to discourage “home brew” systems which are installed by inexperienced users and which-either accidentally or
intentionally-do not comply with FCC regulations for use in the ISM band. Both the original rules and the amendments sought
to enable multiple RF networks to “coexist” with minimum impact on one another by exploiting properties of spread spectrum
technology. Fundamentally, the FCC 1994 rules intend to limit RF communications in the ISM band to a well defined region,
while ensuring multiple systems can operate with minimum impact on one another. These two needs are addressed by limiting
the type and gain of antennas used with a given system, and by requiring a greater degree of RF energy “spreading.”
• Antenna Gain and Power Output—FCC regulations specify maximum power output and antenna gain. At 2.4GHz the
maximum transmitter power is 1watt, or 30dBm. Using this maximum power, the maximum antenna gain is 6dBi. However,
the regulations also define the maximum values in regards to the following two different system scenarios.
In Point-to-Multipoint systems, the FCC has limited the maximum EIRP (effective isotropic radiated power) to 36dBm. EIRP =
TX power + antenna gain. For every dB that the transmitter power is reduced, the antenna may be increased by 1dB. (29dBm
TX, +7dB antenna = 36dBm EIRP, 28dBm TX, +8dB antenna = 36dBm EIRP).
The Cisco Aironet Bridge transmitter power is 20dBm, which is 10dBm lower than maximum. This then allows the use of
antennas up to 10dB over the initial 6dBi limit, or 16dBi.
In Point-to-Point systems for 2.4GHz systems, using directional antennas, the rules have changed. Because a high gain antenna
has a narrow beamwidth, and therefore the likelihood is high that it will cause interference to other area users. Under the rule
change, for every dB the transmitter is reduced below 30dBm, the antenna may be increased from the initial 6dBi, by 3dB. (29dB
Transmittermeans 9dBi antenna, 28dB transmitter means 12dBi antenna). Because we are operating at 20dBm, which is 10dB
below the 30dBm level, we can increase the out antenna by 30dB. However Cisco has never tested, and therefore is not certified
with any antenna larger than 21dBi.
The main issue concerns what components comprise a point-to-point and multipoint system.
In Figure 7, Point A communicates to a single point, B, and Point B communicates to a single point A. Therefore it is simple to
see that both locations see this as a point to point installation.
In Figure 8, Point A communicates to more than one, or multiple points. Therefore Point A is operating in a multipoint
configuration,and the largest antenna permitted is 16dBi. Point B orPoint C can each communicate to only one point, (Point A).
Therefore Point B and Point C actually operate in a single point or point-to-point operation, and a larger antenna may be used.
• Amplifiers—The FCC rules Section 15.204-Part C states “External radio frequency power amplifiers shall not be marketed as
separate products...” Part D states “Only the antenna with which an intentional radiator (transmitter) is originally authorized
may be used with the intentional radiator.” This means that unless the amplifier manufacturer submits the amplifier for testing
with the radio and antenna, it cannot be sold in the US. If it has been certified, then it must be marketed and sold as a complete
system including transmitter, antenna, and coax. It also must be installed exactly this way.
If using a system that includes an amplifier, remember that the above rules concerning power are still in effect. If the amplifier
is 1/2 watt (27dBm) this means in a multipoint system the maximum antenna gain is only 9dBi, and in a point-to-point system,
it is only 15dBi.
ETSI
The European Telecommunication Standardization Institute has developed standards that have been adopted by many European
countriesas well asmany others. Underthe ETSI regulations,the power output and EIRP regulations are much different than in the US.
• Antenna Gain and Power Output—The ETSI regulations specify maximum EIRP as 20dBm. Since this includes antenna gain,
this limits the antennas that can be used with a transmitter. Touse a larger antenna, the transmitter power must be reduced, so
that the overall gain of the transmitter, plus the antenna gain less any losses in coax is equal to or less than +20dBm. This
drastically reduces the overall distance an outdoor link can operate.
• Amplifiers—Since the ETSI regulation has such a low EIRP the use of amplifiers are typically not permitted in any ETSI system.
Frequencies and Channels Sets
IEEE 802.11b Direct Sequence Channels
Fourteen channels are defined in the IEEE 802.11b Direct Sequence (DS) channel set. Each DS channel as transmitted is 22 MHz
wide, however the channel center separation is only 5 MHz. This leads to channel overlap such that signals from neighboring
channels can interfere with each other. In a 14-channel DS system (11 usable in the US), only three non-overlapping (and hence,
non-interfering) channels, 25 MHz apart are possible (for example, Channels 1, 6, and 11).
This channel spacing governs the use and allocation of channels in a multi-access points environment such as an office or campus.
Access points are usually deployed in “cellular” fashion within an enterprise where adjacent access points are allocated
non-overlapping channels. Alternatively,access points can be collocated using Channels 1, 6, and 11 to deliver 33 Mbps bandwidth
to a single area (but only 11 Mbps to a single client). The channel allocation scheme is illustrated in Figure 9.
AIR-ANT3351Diversity OmniPOS diversity dipoles for use with LMC radio cards with two MMCX
connectors—This antenna contains two standard 2.2 dBi “rubber duck” and
36" of cable with two MMCX connectors. It has a platform with a adhesive
backing to raise the antennas above obstructions.
AIR-ANT5959Diversity OmniCeiling mount diversity Indoor antenna with RP-TNC—This antenna was
designed for WLAN applications for frequencies of 2400 to 2500 MHz. The
antenna is omni directional and has a nominal gain of 2.2 dBi. Its low
profile allows it to remain unnoticed in the ceiling. It comes with a clip that
permits it to be mounted to a drop ceiling cross member.
AIR-ANT2012Diversity PatchWall mount indoor/outdoor antenna with two RP-TNC—Similar to the
above patch, but providing diversity antennas in the same package for
areas where multipath problems exist.
AIR-ANT3213Diversity OmniPillar mount diversity,indoor antenna with two RP-TNC—Cosmetic antenna
ideal for retail or hospital environment. Includes 36" of white RG58 cable
with a separation of Siamese co-ax of 10". Has a tan cloth covering, in a 12
x 5 rectangle. Included are two mounting brackets that will keep the
antenna 6 inches off of the wall.
AIR-ANT1728OmniCeiling mount indoor antenna with RP-TNC connector—This antenna was
designed for WLAN applications for frequencies of 2400 MHz to 2500 MHz.
The antenna is omni directional and has a nominal gain of 5.2 dBi. It comes
with a clip that allows it to be mounted to a drop ceiling cross member.
AIR-ANT4941Omni-directionalSingle dipole antenna with an RP-TNC connector. The antenna provides
indoor omni-directional coverage and is for use in the 2400-2500 MHz
frequency band. It has a 90' articulation radius. It is for use with all radios
that utilize an RP-TNC antenna connector.
AIR-ANT3549PatchWall mount indoor/outdoor antenna with RP-TNC—Special type of antenna
unique to data transmission is the patch antenna. This works well and fits
aesthetically into most work environments. Mechanically they are small
rectangles about 1/2 inch thick. They are designed to mount flat to a wall
and seem to disappear into the wall in most environments. The radiation
pattern is in the shape of a hemisphere. A typical application would be for
coverage of an area where the transmitter is located on the side of the
coverage area. Good for both indoor and outdoor use.
AIR-ANT1729DirectionalWall mount, indoor/outdoor directional patch antenna. Designed for use
with any radio that features an RP-TNC antenna connector. For use in the
2400-2500 MHz frequency band. The pigtail cable is 30" long.
AIR-ANT2506OmniMast mount indoor/outdoor antenna with RP-TNC—This antenna was
designed for WLAN applications for frequencies of 2400 MHz to 2500 MHz.
The antenna is omni directional and has a nominal gain of 5.2 dBi. It is
designed to be mounted on a round mast.
AIR-ANT4121OmniMast mount outdoor high gain antenna with RP-TNC—This antenna was
designed for WLAN applications for frequencies of 2400 MHz to 2500 MHz.
The antenna is omni directional and has a nominal gain of 12 dBi. This
design uses an elevated center-feed to produce an elevation pattern with very
little “squint” or beam-tilt. It is designed to be mounted on a round mast.
AIR-ANT1949YagiHigh gain outdoor directional antenna with RP-TNC—This WLAN antenna is
a completely enclosed 16 element yagi. It is designed to be used as a bridge
antenna between two networks or for point-to-point communications. It
has a nominal VSWR of 1.5:1 and is less than 2:1 over the entire frequency
band. The gain is 13.5 dBi and the half-power beamwidth is 30 degrees.
This antenna is normally mounted on a mast and is vertically polarized.
AIR-ANT3338DishVery high gain outdoor antenna with RP-TNC—This WLAN antenna is a
parabolic dish designed to be used as a bridge antenna between two
networks or for point-to-point communications. It consists of an aluminum
parabolic reflector and feed antenna. The antenna features a rugged
mount. It also offers 20 degree fine adjustment for both horizontal and
vertical planes. The antenna is provided with hardware for mast mounting.
13.5dbi
21dBi
Cisco Cables
Table 5 Cisco Cables
Cisco Part NumberType of CableDescriptionLoss (2.4GHz)
AIR-CAB020LL-RInterconnect20 ft. low-loss cable with RP-TNC connectors1.3 dB
AIR-CAB050LL-RInterconnect50 ft. low-loss cable with RP-TNC connectors3.4 dB
AIR-CAB100ULL-RInterconnect100 ft. ultra-low-loss cable with RP-TNC connectors4.4 dB
AIR-CAB150ULL-RInterconnect150 ft. ultra-low-loss cable with RP-TNC connectors6.6 dB
AIR-420-002537-060Bulkhead60" RG58 type cable with RP-TNC connectors2dB
Table 6 Accessories
Cisco Part NumberNameDescription
AIR-ACC2662Yagi Articulating MountThis mount permits the yagi antenna to be mounted to a flat surface or a
mast, and then be adjusted in both horizontal and vertical angles.
AIR-ACC3354Lightning ArrestorProvides lightning and related energy surges at the antenna from reaching
2.2dBi POS Diversity Dipole
for use with LMC cards
AIR-ANT3351
Dimensions and Mounting SpecificationsVertical Radiation
6.5
"
7.0
"
2.12
"
Cable length — 36
"
Frequency Range2.4-2.483GHz
VSWRLess than 2:1
Gain2.14 dBi
PolarizationLinear
Azimuth 3dB BWOmni directional
Elevations 3dB BW80 degrees
Antenna ConnectorMMCX (2)
Dimensions (H x W x D)6.5 x 7.0 x 2.12 in.
Dimensions and Mounting SpecificationsVertical Radiation
2.8
5.3
"
0.9
"
"
2.0 dBi
Ceiling Bracket
shown for reference
Frequency Range2.4-2.5GHz
VSWR1.7:1
Power5 watts
Gain2dBi
PolarizationVertical linear
Azimuth 3dB BWOmni directional
Elevations 3dB BW80 degrees
Antenna ConnectorRP-TNC
Dimensions (H x W x D)5.3 x 2.8 x 0.9 in.
MountingDrop ceiling cross member mount
Dimensions and Mounting SpecificationsVertical RadiationHorizontal Radiation
6–21/32
"
4–25/32
"
4–1/4
6–1/8
"
"
0.82
5.2 dBi
5.2 dBi
0.173ø THRU
4–PLACES
Frequency Range2.4-2.5GHz
VSWR1.7:1 Nominal
Gain6dBi
PolarizationVertical
Azimuth 3dB BW80 degrees
Elevations Plan (3dB BW)55 degrees
Antenna ConnectorRP-TNC
Dimensions (H x W x D)6.65 x 4.78 x .82 in.
MountingWall mount
Dimensions and Mounting SpecificationsVertical Radiation Pattern
5
"
1
"
12
"
Frequency Range2.4-2.83GHz
VSWR2:1 Nominal
Gain5.2dBi
PolarizationVertical
Azimuth 3dB BWOmni directional—360 degree
Elevation 3dB BW25 degrees
Antenna ConnectorRP-TNC
Dimensions (H x W x D)12 x 5 x 1 in.
Dimensions and Mounting SpecificationsVertical Radiation Pattern
Attaches to Ceiling
Cross Member
9.0
"
Frequency Range2.4-2.83GHz
VSWRLess than 2:1, 1.5:1 Nominal
Gain5.2dBi
PolarizationVertical
Azimuth 3dB BWOmni directional 360 degrees
Elevations Plan (3dB BW)50 degrees
Antenna ConnectorRP-TNC
Dimensions (H x W)9 x 1.25 in.
MountingDrop ceiling cross member—indoor only
Dimensions and Mounting SpecificationsVertical Radiation
4.5
"
1
"
RP-TNC
Frequency Range2.4-2.484GHz
VSWRLess than 2:1
Power5 watts
Gain2 dBi
PolarizationLinear
Azimuth 3dB BWOmni directional
Elevations 3dB BW70 degrees
Antenna ConnectorRP-TNC
Dimensions (H x W x D)See Drawing
MountingWall mount
Dimensions and Mounting SpecificationsVertical RadiationHorizontal Radiation
4.88
"
0.66
"
8.5 dBi
4.88
"
8.5 dBi
Frequency Range2.4-2.5GHz
VSWR2:1 Max, 1.5:1 Nominal
Gain8.5dBi
PolarizationVertical
Azimuth 3dB BW60 degrees
Elevations 3dB BW55 degrees
Antenna ConnectorRP-TNC
Dimensions (H x W x D)4.88 x 4.88 x .6 in.
MountingWall mount
Dimensions and Mounting SpecificationsVertical RadiationHorizontal Radiation
3.75
"
0.5
"
5.2 dBi
5.5
"
5.2 dBi
Frequency Range2.4-2.5GHz
VSWRLess than 2:1
Gain6dBi
PolarizationLinear
Azimuth 3dB BW65 degrees
Elevations Plan (3dB BW)70 degrees
Antenna ConnectorRP-TNC
Dimensions (H x W x D)See Drawing
MountingWall mount
Dimensions and Mounting SpecificationsHorizontal Radiation PatternVertical Radiation Pattern
Mast 1.125
"
to 1.25
18
Direction of Signal
13.5 dBi
"
"
3
"
13.5 dBi
13.5dB Yagi—2.4GHz
Connector RP TNC
Frequency Range2.4-2.83GHz
VSWRLess than 2:1, 1.5:1 Nominal
Gain13.5
Front to Back RatioGreater than 30dB
PolarizationVertical
Azimuth 3dB BW30 degrees
Elevations 3dB BW25 degrees
Antenna ConnectorRP-TNC
Dimensions (H x W)18 x 3 in.
Wind Rating110MPH
Dimensions and Mounting SpecificationsRadiation Pattern
20 dBi
8 1/2
"
COAX
10 1/2
REF
"
5
"
8 1/2
24
"
"
Frequency Range2.4-2.83GHz
VSWRLess than 1.8:1, 15:1 Nominal
Power5 watts
Gain21dBi
Front to Back RatioGreater than 25dB
Maximum Side Lobe-17dB
PolarizationVertical
Azimuth 3dB BW12.4 degrees
Elevation 3dB BW12.4 degrees
Antenna ConnectorRP-TNC
Dimensions (H x W)24 x 15.5 in.
Wind Rating110MPH
Cisco Systems, Inc.
170 West Tasman Drive
San Jose, CA 95134-1706
USA
www.cisco.com
Tel: 408 526-4000
800 553-NETS (6387)
Fax: 408 526-4100
European Headquarters
Cisco Systems International BV
Haarlerbergpark
Haarlerbergweg 13-19
1101 CH Amsterdam
The Netherlands
www-europe.cisco.com
Tel: 31 0 20 357 1000
Fax: 31 0 20 357 1100
Cisco Systems has more than 200 offices in the following countries and regions. Addresses, phone numbers, and fax numbers are listed on the
Cisco Web site at www.cisco.com/go/offices
Argentina • Australia • Austria • Belgium • Brazil • Bulgaria • Canada • Chile • China PRC • Colombia • Costa Rica • Croatia
Czech Republic • Denmark • Dubai, UAE • Finland • France • Germany • Greece • Hong Kong SAR • Hungary • India • Indonesia • Ireland
Israel • Italy • Japan • Korea • Luxembourg • Malaysia • Mexico • The Netherlands • New Zealand • Norway • Peru • Philippines • Poland
Portugal • Puerto Rico • Romania • Russia • Saudi Arabia • Scotland • Singapore • Slovakia • Slovenia • South Africa • Spain • Sweden
Switzerland • Taiwan • Thailand • Turkey • Ukraine • United Kingdom • United States • Venezuela • Vietnam • Zimbabwe
All other trademarks mentioned in this document or Web site are the property of their respective owners. The use of the word partner does not imply a partnership relationship between Cisco and any other company.
(0301R)
Americas Headquarters
Cisco Systems, Inc.
170 West Tasman Drive
San Jose, CA 95134-1706
USA
www.cisco.com
Tel: 408 526-7660
Fax: 408 527-0883
Asia Pacific Headquarters
Cisco Systems, Inc.
Capital Tower
168 Robinson Road
#22-01 to #29-01
Singapore 068912
www.cisco.com
Tel: +65 6317 7777
Fax: +65 6317 7799
01/03 BW8282
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