Download - Wlan Hotspot Indoor Design
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WLAN-PRJ-V4_E_C - 1 © P. Nicoletti: see note pag. 2
Wireless LAN:Indoor, Hot Spot & Outdoor design
Pietro Nicolettipiero[at]studioreti.it
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Copyright noteThis set of transparencies, hereinafter referred to as slides, is protected by copyright laws and provisions of International Treaties. The title and copyright regarding the slides (including, but not limited to, each and every image, photography, animation, video, audio, music and text) are property of the authors specified on page 1.
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Information included in these slides is deemed as accurate at the date of publication. Such information is supplied for merely educational purposes and may not be used in designing systems, products, networks, etc. In any case, these slides are subject to changes without any previous notice. The authors do not assume any responsibility for the contents of these slides (including, but not limited to, accuracy, completeness, enforceability, updated-ness of information hereinafter provided).
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Wireless LAN implementations
� Indoor Wireless LAN:
�Cover an area inside the building
� Outdoor Wireless LAN:
�Connect Building LANs across wireless medium
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Wireless LAN implementations
� HOT SPOT
�Cover a public limited internal or external area where the people can access to Internet services via Wireless LAN
Railway Station
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Wireless Indoor networks: features and problems
� They cover a limited area like:
�meeting room
� flat or office home
� area with architectural constraints
� office area as complement to the wired network
� store
� Design problems:
� cell coverage and performances
� security and privacy
� users’ access
�DSSS Access Point interference
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Wireless-LAN IN-DOOR 802.11b: approximate radio covering ray in Europe
5.5 Mbps HR-DSSS48 mt ray
11 Mbps HR-DSSS
40 mt ray
2 Mbps DSSS57 mt ray
1 Mbps DSSS
67 mt ray
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Wireless-LAN: Automatic Rate Fallback
� Lowest Data rate are characterized by a more robust communication with longer distance coverage with respect to higher data rate
� Station try to work at the maximum speed
� The station in the inner cell area most internal operate at the maximum speed, while that in outer cell area operate at the minimum speed
� The ARF algorithm (Automatic Rate Fallback) allows the station to change automatically date rate as it goes away from the inner cell area
� Mechanism based on the count of lost ACK
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IN-DOOR Wireless-LAN: design steps
� The design can be divided into 3 steps:
� examination of the area to be served and cells planning
� site survey
� cell planning reexamination
� At the end of installation could be necessary update the project documentation adding the last modifications
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IN-DOOR Wireless-LAN : cell planning and channels assignments
� Having the building plan it is possible to start planning the area covering with several cells, of which a specific channel will be assigned
� Cell overlap
� fully overlapped to increase the available bandwidth in a determinate area
� partially overlapped
� Cell overlap typology:
� horizontal
� vertical
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IN-DOOR Wireless-LAN : Criteria of cell design and their density
� The design of cell covering and of cell population density can be based on:
�Maximum wireless performances raise in the area to be covered
� high AP number
� low area of competence of a cell
� design which must consider the possible interferences between the cells
�Big area with the smallest possible AP number
� low AP number
� high area competence of a single cell
� design which must avoid not covered zones
� performances which change according to the zones
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IN-DOOR Wireless-LAN receiver sensitivity: some examples
� Receiver sensitivity must be at least of -76 dBm
�Average product sensitivities: -84 dBm at 11 Mb/s, -87 dBm at 5,5 Mb/s, -90 dBm at 2 Mb/s, -93 dBm at 1 Mb/s
� Some Cisco product sensitivities: -85 dBm at 11 Mb/s, -89 dBm at 5,5 Mb/s, -91 dBm at 2 Mb/s, -94 dBm at 1 Mb/s
� Some Alvarion product sensitivities: -85 dBm at 11 Mb/s, -88 dBm at 5,5 Mb/s, -90 dBm at 2 Mb/s, -93 dBm at 1 Mb/s
� Some 3COM AP sensitivities: -80 dBm at 11 Mb/s, -84 dBm at 5,5 Mb/s, -85 dBm at 2 Mb/s, -88 dBm at 1 Mb/s
� Some 3COM NIC sensitivities: -86 dBm at 11 Mb/s, -88 dBm at 5,5 Mb/s, -91 dBm at 2 Mb/s, -93 dBm at 1 Mb/s
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IN-DOOR Wireless-LAN: TX-Power
� For the maximum TX-Power the standard refer to the national regulations
� For the maximum TX-Power the standard refer to the national regulations
� 32 mW TX-Power is adopted by all manifactures
� 100 mW (EIRP) TX-Power is adopted by the most manifacturers and is the maximum usable level in Europe
� Cisco product granularity = 5, 20, 30, 50, 100 mW (7, 13, 15, 17, 20 dBm)
� Some 3COM cards limit TX-Power at 17 dBm (50 mW)
�TX-Power of 250 mW is adopted by some Alvarionproducts and is usable in USA
� alvarion granularity = -4, -2, 4, 6, 12, 14, 20, 24 dBm
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2.4 GHz Transmit Power Level
� USA TX power limit 1000 mW
� Europe TX power limit 100 mW (EIRP)
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Data Rate 1 Mb/s 2 Mb/s 5,5 Mb/s 11 Mb/s
Receiver sensitivity for BER 10-5 -93 dBm -90 dBm -87 dBm -84 dBm
Range covered 99% point TX Power 20 dBm (100 mW)
Open plan building 270 mt 198 mt 144 mt 105 mt
Semiopen office 74 mt 59 mt 48 mt 39 mt
Closed office 25 mt 22 mt 19 mt 16 mt
IN-DOOR Wireless-LAN: reliable ranges according to Path Loss using 100 mW TX-Power
� The receiver sensitivity changes according to data rate
� The maximum distances change according to the environment and data rate
� The maximum distances shown are referred to an acceptable receiver quality (1 brick wall of 10 cm in the closed offices)
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IN-DOOR Wireless-LAN: full horizontal overlap of 3 cells using not-overlapped channels
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USA: DSSS not overlapped channels
� 3 not overlapped channels may be used on the same cell/area
� 1, 6, 11
� 25 MHz spacing
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Europe: DSSS not overlapped channels
� 3 not overlapped channels may be used on the same cell/area with 25 or more MHz spacing
� 1, 7, 13
�Other possible combinations with 25 MHz spacing
� 1, 6, 11
� 2, 7, 12
� 3, 8, 13
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IN-DOOR Wireless-LAN: multi-cell area design
� Establish the axis along which it is necessary to install AP and define the centers cell
� Establish the density cells and their positioning along the defined axis
� Choose an alternative antenna to the one integrated in Access Point in case is not necessary an omni-directional coverage
� Establish the channels to be used in the various cells avoiding the interferences
� Define physical Access Point installation type (wall, roof etc.)
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IN-DOOR Wireless-LAN : cells dimensioning on medium open space area
� Area composed by 4 cells in which 2 of these use the same channel
� use of not-overlapped channels and reuse of one channel
CH 1
CH 1
CH 13
CH 7
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CH 1
CH 1
CH 13
CH 7
d1
IN-DOOR Wireless-LAN : cells dimensioning on medium open space area
� Asymmetrical type coverage of the area
� Distance between the reused channels
� low-density model:
� d = 100 m, d2 = 50 mt
�medium-density model:
� d1 = 60 m, d2 = 30 mt
� high-density model:
� d1 = 40 m, d2 = 20 mt
d2
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36 mt
30 mt
IN-DOOR Wireless-LAN: High-density area Cisco coverage example
� High-density model
� SNR = 1 or little more at the center of area between the reused channels
� Symmetric type coverage of the area
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Cisco coverage area example: cell ray calculation
30 mt
36
mt
Hypotenuse = 362 + 302 = 46,861
Circles ray = hypotenuse / 4 = 46,861 / 4 = 11,715
� Axis definition� diagonals of the area to be covered
� a diagonal is the hypotenuse triangle formed by two adjacent sides
�Hypotenuse
�Circles ray
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Cisco coverage area example: dimensions and position cells, channel selection
11,715
9
9
9
9
7,5 7,5 7,5 7,5
23,43
CH 1
CH 1
CH 13
CH 7
� Symmetrictype coverage of the area:
� cell centers equidistant with respect to the ends of the axis
� Reuse Channelat 23,43 mt
� channel 1 reused
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Alternative to the Cisco example: Reuse Channel at about 30,8 mt
30 mt
36
mt
γ
i
c
b
� Lengths and distances
� I = 46,86 mt, i1 & i2 = 8 mt, d = 30,86 mt
� Sine calculation of β
sin β = c / i
sin β = 36/46,86
sin β = 0,768
� Cathetus calculation
c1 = i1 * sine b
c1 = 8 * 0,768 = 6,144
b1 = 82 - 6,1442
b1 = 5,133 β
i 1
c 1
b 1
i 2
d
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30 mt
36
mt
γ
c
b
β
i 1
c 1
b 1
i 2
d
CH 1
CH 1
CH 13
CH 7
Alternative to the Cisco example: Reuse Channel at about 30,8 mt
� Asymmetrical type coverage of the area
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30 mt
36
mt
7,5 mt 7,5 mt15 mt
12 mt
6 mt
12 mt
6 mt 15 mt
2 nd alternative to the Cisco example: 3 cells coverage with 3 not-overlapped channels
� Small/medium dimension areas possible solution
� Choice of the 3 cell centers
� they must be as much as possible barycentric
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30 mt
36
mt
7,5 mt 7,5 mt15 mt
12 mt
6 mt
12 mt
6 mt 15 mt
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Overlapping channels
� Not overlapped channels
�Minimum 25 MHz spacing from central frequency
�May operate in the same cell/area without interference
� Slightly overlapping channels
�Operate in adjacent cell/areas slightly overlapped;
�Minimum 15 MHz spacing from central frequency
� It is necessary to ensure an attenuation of the signal interference from a neighbor cell that want to use the same channel
� minimum 6 dB over interference signal at 2 Mb/s
� minimum 12 dB over interference signal at 11 Mb/s
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3 th alternative to the Cisco example: use of 4 slightly overlapping channels
11,715
9
9
9
9
7,5 7,5 7,5 7,5
23,43
CH 4
CH 1
CH 13
CH 7
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Distance between APs using the same channel
Medium high density area using high density cells with Reuse Channel
� 1st step: Cells coverage planning
� 2nd step: Use a channel with 25 (preferable) or 15 MHz spacing between the adjacent cells using the same channel
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Outdoor area: receiver near AP(-45 dBm)
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Outdoor area: receiver at 10 mt from AP(-48 dBm)
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Outdoor area: receiver at 15 mt from AP(-50 dBm)
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802.11 DSSS: transmitter output theoretical spectrum
Trasmit Spectrum Mask Unfiltered Sinx/x
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802.11 DSSS: transmitter output real spectrum
Marker a 14,5 MHz -32,74 dB
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Europe: 802.11 slightly overlapping channels
� Cells planning considering 5 channels with 15 MHz spacing
� 1, 4, 7, 10, 13
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32 mt between APs using the same channel
AP1 AP3AP2
9,6 mt
6,4 mt
12,5 mt
16 mt 16 mt
High density area with channel reuse (model 1)� Critical solution in open plan building
� Possible interference between AP using the same channel because of low distance and low signal attenuation
� If STA move away from AP1, the SNR at 9,6 mt implies cell search followed by handover
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40 mt between APs using
the same channel
AP1 AP3AP2
12 mt
8 mt
15,6 mt
20 mt 20 mt
High density area with channel reuse (model 2)� Critical solution in open plan building
� Possible interference between AP using the same channel because of low distance and low signal attenuation
� If STA move away from AP1, the SNR at 12 mt implies cell search followed by handover
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60 mt between APs using
the same channel
AP1 AP3AP2
18 mt
12 mt
23,4 mt
30 mt 30 mt
High density area with channel reuse (model 3)� Acceptable solution in open plan building
� If STA move away from AP1, the SNR at 18 mt implies cell search followed by handover
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High density area with channel reuse (model 4)
� Good solution in open plan building� If STA move away from AP1, the SNR at 24 mt implies cell search followed by handover
80 mt between APs using
the same channel
AP1 AP3AP2
24 mt
16 mt
31,2 mt
40 mt 40 mt
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High density area with channel reuse (model 5)
� Good solution for outdoor environments and open plan building� If STA move away from AP1, the SNR at 36 mt implies cell search followed by handover
120 mt between APs using
the same channel
AP1 AP3AP2
36 mt
24 mt
46,9 mt
60 mt 60 mt
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IN-DOOR Wireless-LAN: High density Multi-Cellular infrastructure with Channel Reuse
CH 1
CH 7
CH 10
CH 7
CH 13
CH 10
CH 10
CH 4
CH 1
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IN-DOOR Wireless-LAN : vertical overlap
� If the floor is small is possible install just 1 AP per floor using non overlapped channel between adjacent floors
� Typical attenuation between floor
� 22 dB between two adjacent floors
� 30 dB tra two floor separated by an other floor (example p1 & p3)
� In this case the attenuation of 30 dB permit to reuse channel
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IN-DOOR Wireless-LAN : vertical overlap on small building example
CH 1
CH 7
CH 13
CH 1
CH 7
CH 13
CH 1
30 mt length
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R
R
R
Floor with AP
Upper Floor
Lower Floor
Ray of about 15 mt
IN-DOOR Wireless-LAN: Idealized coverage model on axis x and y of adjacent floors
� In a building, for effect of the attenuation of about 22 dB between two adjacent floors, the cell coverage is ideally comparable to a series of concentric circular crowns
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50 m0 m 10 m 20 m 30 m 40 m
0 m
12 m
- 60 dB - 65 dB
- 70 dB
- 75 dB
- 80 dB
- 85 dB
- 90 dB
- 95 dB
- 100 dB
50 m0 m 10 m 20 m 30 m 40 m
0 m
12 m
- 35 dB - 40 dB
- 45 dB - 50 dB
- 55 dB - 60 dB
- 65 dB
- 70 dB
- 75 dB
- 80 dB- 85 dB
- 90 dB
Floorwith AP
Adjcentfloor
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IN-DOOR Wireless-LAN : vertical overlapping cells in a big building
CH 1 CH 13
CH 1CH 7
CH 1 CH 132nd Floor
Building length 40 ÷ 160 mt
3th Floor
1st Floor
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IN-DOOR Wireless-LAN: The choice of antenna type
� Omni Directional antenna
� low gain, covering at 360 degrees on the horizontal plan and degrees reduced on the vertical plan
� range gain between 0 and 6 dB
� Patch antenna
�medium gain, covering angle reduced on the two horizontal and vertical plans
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WLAN-PRJ-V4_E_C - 49 © P. Nicoletti: see note pag. 2
Omni Directional antenna Cisco AIR-ANT1728: ceiling mounting
Dimension and mounting specifications Vertical Radiation Pattern
22,8 cm
5,2 dBi
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Omni Directional antenna Cisco AIR-ANT1728: Technical Data
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Omni Directional antenna HUBER+SUNER: ceiling mounting Technical Data
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� Mounting and security instructions
� dimensions (mm)
Omni Directional antenna HUBER+SUNER: ceiling mounting specifications
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Antenna Omni-direzionale HUBER+SUNER: Radiation Pattern
Radiation Pattern
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Dipole Cisco AIR-ANT4941: Technical Data
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Dipole Cisco AIR-ANT4941: Technical Data
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Planar antenna HUBER+SUNER: Dipole Cisco AIR-ANT4941: Technical Data
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Planar antenna HUBER+SUNER: RadiationPattern
Radiation Pattern
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Planar antenna HUBER+SUNER: mounting specifications
� Mounting and security instructions
� dimensions (mm)
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Patch antenna Cisco AIR-ANT1729: Technical Data
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Patch antenna Cisco AIR-ANT1729: Technical Data
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Diversity Dipole antenna Cisco AIR-ANT3351
Vertical radiation pattern
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Diversity Dipole antenna Cisco AIR-ANT3351: Technical Data
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Cable antenna choosing criteria
� Cable choosing criteria
�Attenuation
� as higher as much as the distance is high between AP and antenna
�Diameter and minimum bending ray
� the cable depends on the installation place and on the narrowest passages on which should be installed
� a cable with high minimum bending ray requires several care during installation
�Costs
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IN-DOOR Wireless-LAN: AP physical installation
AP Ceiling installation AP Wall installation
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Hot Spot Wireless-LAN
� The cell design, of their installation and channels assignment, follows rules very like those of the Indoor networks
� Access Point allows the access to the wireless network within his covering ray
� The problems of privacy and security:
�The Hot Spot are typically used to provide the access to Internet
� Allowing the access to the users qualified through software or appliance which realize functions of Hot Gateway Spot or Captive Portal
� The user accesses through Web page via HTTPS, is traced and his activity is present in the log file
� The privacy is not warranted
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Hot Spot Gateway
� Hot Spot Gateway (named also Captive Portal):
� Software or Appliance allows the access to the network through a HTTPS page of presentation which requires Username and password
�He intercepts the DHCP or ARP requests and sends one splash-page via HTTPS
�Have at least 2 net interfaces:
� 2 Ethernet
� 1 Wireless + 1 Ethernet
�Has an internal Firewall that by default deny any user access
�He has control mechanisms to prevent intrusion of not authorized users
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Wireless authentication & security: 1
Wired Switched LAN
BSS
BSS
Distribution System
BSS
ESS
R Router/FirewalServer RADIUS
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Wired Switched LAN
Server RADIUS/Router/Firewall
BSS
BSS
Distribution System
BSS
ESS
Wireless authentication & security: 2
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Wired Switched LAN
Server RADIUS
BSS
BSS
Distribution System
BSS
ESS
R Router/FirewalProxy RADIUS
Wireless authentication & security: 3
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Wired Switched LAN
Server RADIUS
BSS
BSS
Distribution System
BSS
ESS
R Router/Firewall
Wireless authentication & security: 4
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OUT-DOOR Wireless LAN
� Typically use for the connection of buildings which are in Line of Sight (optical visibility)
� Realization of broadband network in rural areas with low investment return
� costs at least 10 times lower respect the wired networks
� Use of Wireless bridge
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Point-to-Point bridge
0 to 10 Km
Ethernet
Bridge
Antenna
Building A Building B
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Point-to-Multipoint bridge configurationEthernet
Bridge
Building B Building C
Building A
Omni Directional antenna
Directional antenna
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Bridge used AP also as AP
Bridge
Bridge
PCI card
Hub
Bridge
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Bridge used as Repeater in the WM
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Bridge configuration example with BR350 Cisco
10.0.0.1
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Use of Wireless Bridge in OUT-DOOR networks
� A bridge must be configured as root or master
� he assumes also the AP function for the other bridges
� The other bridges must be configured as non-root
� they do a function such to that of the stations for the association
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WLAN-PRJ-V4_E_C - 78 © P. Nicoletti: see note pag. 2
OUT-DOOR Wireless-LAN: The choice of antenna type
� Omni Directional antenna
� low gain, covering at 360 degrees on the horizontal plan and 50 degrees in vertical plan
� Yagi and Patch antenna
�medium gain, covering angle reduced on the two horizontal and vertical plans
� Directional or parabolic antenna
� high gain, very narrow angle
� difficult to be aligned
� it allows to cover very long distances
� the narrow angle improve interferences immunity
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Directional antenna
� Directional antennas come in many different styles and shapes. An antenna does not offer any added power to the signal, 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.
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Antenna polarization
� Horizontal
� Vertical
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Cisco Omni Directional Antenna
Side View
(Vertical Pattern)
Top View(Horizontal Pattern)
New Pattern (with Gain)
Vertical Beamwidth
500
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Antenna Sector Omnia Alvarion
� Group of 3 antennas with wide angle (120 o) has a combined effect which reproduces omni directionality
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Antenna Sector Omnia Alvarion: Technical Data
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Antenna Sector Omnia Alvarion: Technical Data
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Cisco Yagi Antenna
Side View(Vertical Pattern)
Top View(Horizontal Pattern)
250
300
Antenna gain 13,5 dBi
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Cisco Directional Antenna
12,40 angle on horizontal and vertical plan
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� Main features:
�High gain (24 dB)
�Grid makes suitable for installations in outside windy zones and subject to snowfalls
Alvarion Directional Grid Antenna
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Alvarion Directional Grid Antenna: Technical Data
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Alvarion Directional Grid Antenna: Technical Data
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Fresnel Zone
� 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.
Raise Antennas
Fresnel Zone
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5 GHz in USA and Europe
Europe
19 Channels
1W200mW
5.15 5.35 5.470 5.725 5.8255 GHz
UNII Band
5.25
UNII-140mW
(22 dBm EIRP)
UNII-2200mW
(29 dBm EIRP)
US (FCC)
12 ChannelsUNII-3800mW
(35 dBm EIRP)
4 Channels 4 Channels 4 Channels11 Channels
FCC nuove licensed-
exempt band
(estensione del 2004)
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Usable 5 GHz channels in Europe
25 MHz
5470 5500 5520 5540 5560 5580 5600 5620 5640 5660 5680 5700 5725
Lower Band Edge Upper Band Edge
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5 GHz channels
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Point of retransmission
switch
Retransmission point
CH 100
CH 108
CH 116
switch
Path or Yagi
antenna for
village coverage
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Wireless and mountain
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Small village Wireless coverage
16
Yagi or patch
Antenna