Wireless icon
A wireless network is a computer network that uses wireless data connections between network nodes.
Wireless networking is a method by which homes, telecommunications networks
and business installations avoid the costly process of introducing
cables into a building, or as a connection between various equipment
locations. Wireless telecommunications networks are generally implemented and administered using radio communication. This implementation takes place at the physical level (layer) of the OSI model network structure.
Examples of wireless networks include cell phone networks, wireless local area networks (WLANs), wireless sensor networks, satellite communication networks, and terrestrial microwave networks.
History
The first professional wireless network was developed under the brand ALOHAnet in 1969 at the University of Hawaii and became operational in June 1971. The first commercial wireless network was the WaveLAN product family, developed by NCR in 1986.
- 1991 2G cell phone network
- June 1997 802.11 "Wi-Fi" protocol first release
- 1999 803.11 VoIP integration
Wireless links
Computers are very often connected to networks using wireless links, e.g. WLANs
- Terrestrial microwave – Terrestrial microwave communication uses Earth-based transmitters and receivers resembling satellite dishes. Terrestrial microwaves are in the low gigahertz range, which limits all communications to line-of-sight. Relay stations are spaced approximately 48 km (30 mi) apart.
- Communications satellites – Satellites communicate via microwave radio waves, which are not deflected by the Earth's atmosphere. The satellites are stationed in space, typically in geosynchronous orbit 35,400 km (22,000 mi) above the equator. These Earth-orbiting systems are capable of receiving and relaying voice, data, and TV signals.
- Cellular and PCS systems use several radio communications technologies. The systems divide the region covered into multiple geographic areas. Each area has a low-power transmitter or radio relay antenna device to relay calls from one area to the next area.
- Radio and spread spectrum technologies – Wireless local area networks use a high-frequency radio technology similar to digital cellular and a low-frequency radio technology. Wireless LANs use spread spectrum technology to enable communication between multiple devices in a limited area. IEEE 802.11 defines a common flavor of open-standards wireless radio-wave technology known as .
- Free-space optical communication uses visible or invisible light for communications. In most cases, line-of-sight propagation is used, which limits the physical positioning of communicating devices.
Types of wireless networks
Wireless PAN
Wireless personal area networks (WPANs) connect devices within a relatively small area, that is generally within a person's reach. For example, both Bluetooth radio and invisible infrared light provides a WPAN for interconnecting a headset to a laptop. ZigBee also supports WPAN applications. Wi-Fi
PANs are becoming commonplace (2010) as equipment designers start to
integrate Wi-Fi into a variety of consumer electronic devices. Intel "My WiFi" and Windows 7 "virtual Wi-Fi" capabilities have made Wi-Fi PANs simpler and easier to set up and configure.
Wireless LAN
Wireless LANs are often used for connecting to local resources and to the Internet
A wireless local area network (WLAN) links two or more devices over a
short distance using a wireless distribution method, usually providing a
connection through an access point for internet access. The use of spread-spectrum or OFDM technologies may allow users to move around within a local coverage area, and still remain connected to the network.
Products using the IEEE 802.11 WLAN standards are marketed under the Wi-Fi brand name .
Fixed wireless technology implements point-to-point links between computers or networks at two distant locations, often using dedicated microwave or modulated laser light beams over line of sight paths. It is often used in cities to connect networks in two or more buildings without installing a wired link.
To connect to Wi-Fi, sometimes are used devices like a router or connecting HotSpot using mobile smartphones.
Wireless ad hoc network
A wireless ad hoc network, also known as a wireless mesh network or mobile ad hoc network
(MANET), is a wireless network made up of radio nodes organized in a
mesh topology. Each node forwards messages on behalf of the other nodes
and each node performs routing. Ad hoc networks can "self-heal",
automatically re-routing around a node that has lost power. Various
network layer protocols are needed to realize ad hoc mobile networks,
such as Distance Sequenced Distance Vector routing, Associativity-Based Routing, Ad hoc on-demand Distance Vector routing, and Dynamic source routing.
Wireless MAN
Wireless metropolitan area networks are a type of wireless network that connects several wireless LANs.
- WiMAX is a type of Wireless MAN and is described by the IEEE 802.16 standard.
Wireless WAN
Wireless wide area networks
are wireless networks that typically cover large areas, such as between
neighbouring towns and cities, or city and suburb. These networks can
be used to connect branch offices of business or as a public Internet
access system. The wireless connections between access points are
usually point to point microwave links using parabolic dishes on the 2.4 GHz and 5.8Ghz band, rather than omnidirectional antennas
used with smaller networks. A typical system contains base station
gateways, access points and wireless bridging relays. Other
configurations are mesh systems where each access point acts as a relay
also. When combined with renewable energy systems such as photovoltaic
solar panels or wind systems they can be stand alone systems.
Cellular network
Example of frequency reuse factor or pattern 1/4
A cellular network or mobile network is a radio network distributed over land areas called cells, each served by at least one fixed-location transceiver, known as a cell site or base station.
In a cellular network, each cell characteristically uses a different
set of radio frequencies from all their immediate neighbouring cells to
avoid any interference.
When joined together these cells provide radio coverage over a
wide geographic area. This enables a large number of portable
transceivers (e.g., mobile phones, pagers,
etc.) to communicate with each other and with fixed transceivers and
telephones anywhere in the network, via base stations, even if some of
the transceivers are moving through more than one cell during
transmission.
Although originally intended for cell phones, with the development of smartphones, cellular telephone networks routinely carry data in addition to telephone conversations:
- Global System for Mobile Communications (GSM): The GSM network is divided into three major systems: the switching system, the base station system, and the operation and support system. The cell phone connects to the base system station which then connects to the operation and support station; it then connects to the switching station where the call is transferred to where it needs to go. GSM is the most common standard and is used for a majority of cell phones.
- Personal Communications Service (PCS): PCS is a radio band that can be used by mobile phones in North America and South Asia. Sprint happened to be the first service to set up a PCS.
- D-AMPS: Digital Advanced Mobile Phone Service, an upgraded version of AMPS, is being phased out due to advancement in technology. The newer GSM networks are replacing the older system.
Global area network
A global area network
(GAN) is a network used for supporting mobile across an arbitrary
number of wireless LANs, satellite coverage areas, etc. The key
challenge in mobile communications is handing off user communications
from one local coverage area to the next. In IEEE Project 802, this
involves a succession of terrestrial wireless LANs.
Space network
Space
networks are networks used for communication between spacecraft,
usually in the vicinity of the Earth. The example of this is NASA's Space Network.
Uses
Some examples
of usage include cellular phones which are part of everyday wireless
networks, allowing easy personal communications. Another example,
Intercontinental network systems, use radio satellites to communicate across the world. Emergency services
such as the police utilize wireless networks to communicate effectively
as well. Individuals and businesses use wireless networks to send and
share data rapidly, whether it be in a small office building or across
the world.
Properties
General
In a general sense, wireless networks offer a vast variety of uses by both business and home users.
"Now, the industry accepts a handful of different wireless technologies. Each wireless technology is defined by a standard that describes unique functions at both the Physical and the Data Link layers of the OSI model. These standards differ in their specified signaling methods, geographic ranges, and frequency usages, among other things. Such differences can make certain technologies better suited to home networks and others better suited to network larger organizations."
Performance
Each
standard varies in geographical range, thus making one standard more
ideal than the next depending on what it is one is trying to accomplish
with a wireless network.
The performance of wireless networks satisfies a variety of applications
such as voice and video. The use of this technology also gives room for
expansions, such as from 2G to 3G and, 4G and 5G
technologies, which stand for the fourth and fifth generation of cell
phone mobile communications standards. As wireless networking has become
commonplace, sophistication increases through configuration of network
hardware and software, and greater capacity to send and receive larger
amounts of data, faster, is achieved. Now the wireless network has been
running on LTE, which is a 4G mobile communication standard. Users of an
LTE network should have data speeds that are 10x faster than a 3G
network.
Space
Space is
another characteristic of wireless networking. Wireless networks offer
many advantages when it comes to difficult-to-wire areas trying to
communicate such as across a street or river, a warehouse on the other
side of the premises or buildings that are physically separated but
operate as one.
Wireless networks allow for users to designate a certain space which
the network will be able to communicate with other devices through that
network.
Space is also created in homes as a result of eliminating clutters of wiring. This technology allows for an alternative to installing physical network mediums such as TPs, coaxes, or fiber-optics, which can also be expensive.
Home
For homeowners, wireless technology is an effective option compared to Ethernet
for sharing printers, scanners, and high-speed Internet connections.
WLANs help save the cost of installation of cable mediums, save time
from physical installation, and also creates mobility for devices
connected to the network.
Wireless networks are simple and require as few as one single wireless access point connected directly to the Internet via a router.
Wireless Network Elements
The telecommunications network at the physical layer also consists of many interconnected wireline network elements
(NEs). These NEs can be stand-alone systems or products that are either
supplied by a single manufacturer or are assembled by the service
provider (user) or system integrator with parts from several different
manufacturers.
Wireless NEs are the products and devices used by a wireless carrier to provide support for the backhaul network as well as a mobile switching center (MSC).
Reliable wireless service depends on the network elements at the
physical layer to be protected against all operational environments and
applications (see GR-3171, Generic Requirements for Network Elements Used in Wireless Networks – Physical Layer Criteria).
What are especially important are the NEs that are located on the cell tower to the base station
(BS) cabinet. The attachment hardware and the positioning of the
antenna and associated closures and cables are required to have adequate
strength, robustness, corrosion resistance, and resistance against
wind, storms, icing, and other weather conditions. Requirements for
individual components, such as hardware, cables, connectors, and
closures, shall take into consideration the structure to which they are
attached.
Difficulties
Interference
Compared to wired systems, wireless networks are frequently subject to electromagnetic interference.
This can be caused by other networks or other types of equipment that
generate radio waves that are within, or close, to the radio bands used
for communication. Interference can degrade the signal or cause the
system to fail.
Absorption and reflection
Some materials cause absorption
of electromagnetic waves, preventing it from reaching the receiver, in
other cases, particularly with metallic or conductive materials
reflection occurs. This can cause dead zones where no reception is
available. Aluminium foiled thermal isolation in modern homes can easily
reduce indoor mobile signals by 10 dB frequently leading to complaints
about the bad reception of long-distance rural cell signals.
Multipath fading
In multipath fading
two or more different routes taken by the signal, due to reflections,
can cause the signal to cancel out at certain locations, and to be
stronger in other places (upfade).
Hidden node problem
In
a hidden node problem Station A can communicate with Station B. Station
C can also communicate with Station B. However, Stations A and C cannot
communicate with each other, but their signals can interfere at B.
The hidden node problem occurs in some types of network when a node is visible from a wireless access point (AP), but not from other nodes communicating with that AP. This leads to difficulties in media access control (collisions).
Exposed terminal node problem
The exposed terminal problem is when a node on one network is unable to send because of co-channel interference from a node that is on a different network.
The wireless spectrum is a limited resource and shared by all nodes in the range of its transmitters. Bandwidth allocation becomes complex with multiple participating users. Often users are not aware that advertised numbers (e.g., for IEEE 802.11 equipment or LTE
networks) are not their capacity, but shared with all other users and
thus the individual user rate is far lower. With increasing demand, the capacity crunch is more and more likely to happen. User-in-the-loop (UIL) may be an alternative solution to ever upgrading to newer technologies for over-provisioning.
Capacity
Channel
Understanding of SISO, SIMO, MISO and MIMO.
Using multiple antennas and transmitting in different frequency
channels can reduce fading, and can greatly increase the system
capacity.
Shannon's theorem
can describe the maximum data rate of any single wireless link, which
relates to the bandwidth in hertz and to the noise on the channel.
One can greatly increase channel capacity by using MIMO techniques,
where multiple aerials or multiple frequencies can exploit multiple
paths to the receiver to achieve much higher throughput – by a factor of
the product of the frequency and aerial diversity at each end.
Under Linux, the Central Regulatory Domain Agent (CRDA) controls the setting of channels.
Network
The
total network bandwidth depends on how dispersive the medium is (more
dispersive medium generally has better total bandwidth because it
minimises interference), how many frequencies are available, how noisy
those frequencies are, how many aerials are used and whether a
directional antenna is in use, whether nodes employ power control and so
on.
Cellular wireless networks generally have good capacity, due to
their use of directional aerials, and their ability to reuse radio
channels in non-adjacent cells. Additionally, cells can be made very
small using low power transmitters this is used in cities to give
network capacity that scales linearly with population density.
Safety
Wireless access points are also often close to humans, but the drop off in power over distance is fast, following the inverse-square law.
The position of the United Kingdom's Health Protection Agency
(HPA) is that “...radio frequency (RF) exposures from WiFi are likely
to be lower than those from mobile phones.” It also saw “...no reason
why schools and others should not use WiFi equipment.”
In October 2007, the HPA launched a new “systematic” study into the
effects of WiFi networks on behalf of the UK government, in order to
calm fears that had appeared in the media in a recent period up to that
time". Dr Michael Clark, of the HPA, says published research on mobile phones and masts does not add up to an indictment of WiFi.
