Wi-Fi

From Wikipedia, the free encyclopedia

Jump to: navigation, search
Wi-Fi logo
The Internet Protocol Suite
Application Layer
BGP · DHCP · DNS · FTP · GTP · HTTP · IMAP · IRC · Megaco · MGCP · NNTP · NTP · POP · RIP · RPC · RTP · RTSP · SDP · SIP · SMTP · SNMP · SOAP · SSH · Telnet · TLS/SSL · XMPP · (more)
Transport Layer
TCP · UDP · DCCP · SCTP · RSVP · ECN · (more)
Internet Layer
IP (IPv4, IPv6) · ICMP · ICMPv6 · IGMP · IPsec · (more)
Link Layer
ARP · RARP · NDP · OSPF · Tunnels (L2TP) · Media Access Control (Ethernet, MPLS, DSL, ISDN, FDDI) · Device Drivers · (more)
This box: view  talk  edit

Wi-Fi (IPA: /ˈwaɪfaɪ/) is a trademark of the Wi-Fi Alliance for certified products based on the IEEE 802.11 standards (also called Wireless LAN (WLAN) and Wi-Fi). This certification warrants interoperability between different wireless devices.

The term Wi-Fi often is used by the public as a synonym for wireless Internet (WLAN); but not every wireless Internet product has a Wi-Fi certification, which may be because of certification costs that must be paid for each certified device type.

Wi-Fi is supported by most personal computer operating systems, many game consoles, laptops, smartphones, printers, and other peripherals.

Contents

[edit] History

Half-size ISA 2.4 GHz WaveLAN card by AT&T

Wi-Fi uses both single carrier direct-sequence spread spectrum radio technology (part of the larger family of spread spectrum systems) and multi-carrier OFDM (Orthogonal Frequency Division Multiplexing) radio technology. The regulations for unlicensed spread spectrum enabled the development of Wi-Fi, its onetime competitor HomeRF, Bluetooth, and many other products such as some types of cordless telephones.

Unlicensed spread spectrum was first made available in the US by the Federal Communications Commission in 1985 and these FCC regulations were later copied with some changes in many other countries enabling use of this technology in all major countries.[1] The FCC action was proposed by Michael Marcus of the FCC staff in 1980 and the subsequent regulatory action took 5 more years. It was part of a broader proposal to allow civil use of spread spectrum technology and was opposed at the time by main stream equipment manufacturers and many radio system operators.[2]

The precursor to Wi-Fi was invented in 1991 by NCR Corporation/AT&T (later Lucent & Agere Systems) in Nieuwegein, the Netherlands. It was initially intended for cashier systems; the first wireless products were brought on the market under the name WaveLAN with speeds of 1 Mbit/s to 2 Mbit/s. Vic Hayes, who held the chair of IEEE 802.11 for 10 years and has been named the 'father of Wi-Fi,' was involved in designing standards such as IEEE 802.11b, and 802.11a.

[edit] Uses

A roof mounted Wi-Fi antenna
A Wi-Fi antenna

A Wi-Fi enabled device such as a PC, game console, mobile phone, MP3 player or PDA can connect to the Internet when within range of a wireless network connected to the Internet. The coverage of one or more interconnected access points — called a hotspot — can comprise an area as small as a single room with wireless-opaque walls or as large as many square miles covered by overlapping access points. Wi-Fi technology has served to set up mesh networks, for example, in London.[3] Both architectures can operate in community networks.

In addition to restricted use in homes and offices, Wi-Fi can make access publicly available at Wi-Fi hotspots provided either free of charge or to subscribers to various providers. Organizations and businesses such as airports, hotels and restaurants often provide free hotspots to attract or assist clients. Enthusiasts or authorities who wish to provide services or even to promote business in a given area sometimes provide free Wi-Fi access. Metropolitan-wide Wi-Fi (Muni-Fi) already has more than 300 projects in process.[4] There were 879 Wi-Fi based Wireless Internet service providers in the Czech Republic as of May 2008.[5][6]

Wi-Fi also allows connectivity in peer-to-peer (wireless ad-hoc network) mode, which enables devices to connect directly with each other. This connectivity mode can prove useful in consumer electronics and gaming applications.

When wireless networking technology first entered the market many problems ensued for consumers who could not rely on products from different vendors working together. The Wi-Fi Alliance began as a community to solve this issue — aiming to address the needs of the end-user and to allow the technology to mature. The Alliance created the branding Wi-Fi CERTIFIED to reassure consumers that products will interoperate with other products displaying the same branding.

Many consumer devices use Wi-Fi. Amongst others, personal computers can network to each other and connect to the Internet, mobile computers can connect to the Internet from any Wi-Fi hotspot, and digital cameras can transfer images wirelessly.

Routers which incorporate a DSL-modem or a cable-modem and a Wi-Fi access point, often set up in homes and other premises, provide Internet-access and internetworking to all devices connected (wirelessly or by cable) to them. One can also connect Wi-Fi devices in ad-hoc mode for client-to-client connections without a router. Wi-Fi also enables places which would traditionally not have network to be connected, for example bathrooms, kitchens and garden sheds. The "father of Wi-Fi", Vic Hayes, stated that being able to access the internet whilst answering a call of nature was "one of life's most liberating experiences".

As of 2007 Wi-Fi technology had spread widely within business and industrial sites. In business environments, just like other environments, increasing the number of Wi-Fi access-points provides redundancy, support for fast roaming and increased overall network-capacity by using more channels or by defining smaller cells. Wi-Fi enables wireless voice-applications (VoWLAN or WVOIP). Over the years, Wi-Fi implementations have moved toward "thin" access-points, with more of the network intelligence housed in a centralized network appliance, relegating individual access-points to the role of mere "dumb" radios. Outdoor applications may utilize true mesh topologies. As of 2007 Wi-Fi installations can provide a secure computer networking gateway, firewall, DHCP server, intrusion detection system, and other functions.

[edit] Advantages and challenges

A keychain size Wi-Fi detector.

[edit] Operational advantages

Wi-Fi allows local area networks (LANs) to be deployed without wires for client devices, typically reducing the costs of network deployment and expansion. Spaces where cables cannot be run, such as outdoor areas and historical buildings, can host wireless LANs.

Wireless network adapters are now built into most laptops. The price of chipsets for Wi-Fi continues to drop, making it an economical networking option included in even more devices. Wi-Fi has become widespread in corporate infrastructures.

Different competitive brands of access points and client network interfaces are inter-operable at a basic level of service. Products designated as "Wi-Fi Certified" by the Wi-Fi Alliance are backwards compatible. Wi-Fi is a global set of standards. Unlike mobile telephones, any standard Wi-Fi device will work anywhere in the world.

Wi-Fi is widely available in more than 220,000 public hotspots and tens of millions of homes and corporate and university campuses worldwide.[7] Wi-Fi Protected Access encryption (WPA and WPA2) is not easily cracked if strong passwords are used. New protocols for Quality of Service (WMM) make Wi-Fi more suitable for latency-sensitive applications (such as voice and video), and power saving mechanisms (WMM Power Save) improve battery operation.

[edit] Limitations

Spectrum assignments and operational limitations are not consistent worldwide. Most of Europe allows for an additional 2 channels beyond those permitted in the U.S. for the 2.4 GHz band. (1–13 vs. 1–11); Japan has one more on top of that (1–14). Europe, as of 2007, was essentially homogeneous in this respect. A very confusing aspect is the fact that a Wi-Fi signal actually occupies five channels in the 2.4 GHz band resulting in only three non-overlapped channels in the U.S.: 1, 6, 11, and three or four in Europe: 1, 5, 9, 13 can be used if all the equipment on a specific area can be guaranteed not to use 802.11b at all, even as fallback or beacon. Equivalent isotropically radiated power (EIRP) in the EU is limited to 20 dBm (100 mW).

[edit] Reach

See also: Long-range Wi-Fi
Large satellite dish specially made for long-range Wi-Fi connection in Venezuela

Wi-Fi networks have limited range. A typical Wi-Fi home router using 802.11b or 802.11g with a stock antenna might have a range of 32 m (120 ft) indoors and 95 m (300 ft) outdoors. Range also varies with frequency band. Wi-Fi in the 2.4 GHz frequency block has slightly better range than Wi-Fi in the 5 GHz frequency block. Outdoor range with improved (directional) antennas can be several kilometres or more with line-of-sight. In general, the maximum amount of power that a Wi-Fi device can transmit is limited by local regulations, such as FCC Part 15[8] in USA.

Wi-Fi performance decreases roughly quadratically as distance increases at constant radiation levels.

Due to reach requirements for wireless LAN applications, power consumption is fairly high compared to some other short-range standards. Technologies such as Zigbee and Bluetooth, which are designed to support wireless PAN applications, provide a much shorter propagation range of <10m (ref. e.g. IEEE Std. 802.15.4 section 1.2 scope) and so in general have a lower power consumption. The high power consumption of Wi-Fi makes battery life a concern for mobile devices.

A number of "no new wires" technologies have been developed to provide alternatives to Wi-Fi for applications in which Wi-Fi's indoor range is not adequate and where installing new wires (such as CAT-5) is not possible or cost-effective. One example is the ITU-T G.hn standard for high speed Local area networks using existing home wiring (coaxial cables, phone lines and power lines). Although G.hn does not provide some of the advantages of Wi-Fi (such as mobility or outdoor use), it's designed for applications (such as IPTV distribution) where indoor range is more important than mobility.

[edit] Mobility

Speed vs. Mobility of wireless systems: Wi-Fi, HSPA, UMTS, GSM

Because of the very limited practical range of Wi-Fi, mobile use is essentially confined to such applications as inventory taking machines in warehouses or retail spaces, barcode reading devices at check-out stands or receiving / shipping stations. Mobile use of Wi-Fi over wider ranges is limited to move, use, move, as for instance in an automobile moving from one hotspot to another (Wardriving). Other wireless technologies are more suitable as illustrated in the graphic.

[edit] Threats to security

The most common wireless encryption standard, Wired Equivalent Privacy or WEP, has been shown to be easily breakable even when correctly configured. Wi-Fi Protected Access (WPA and WPA2), which began shipping in 2003, aims to solve this problem and is now available on most products. Wi-Fi Access Points typically default to an "open" (encryption-free) mode. Novice users benefit from a zero-configuration device that works out of the box, but this default is without any wireless security enabled, providing open wireless access to their LAN. To turn security on requires the user to configure the device, usually via a software graphical user interface (GUI). Wi-Fi networks that are open (unencrypted) can be monitored and used to read and copy data (including personal information) transmitted over the network, unless another security method is used to secure the data, such as a VPN or a secure web page. (See HTTPS/Secure Socket Layer.)

[edit] Population

Many 2.4 GHz 802.11b and 802.11g access points default to the same channel on initial startup, contributing to congestion on certain channels. To change the channel of operation for an access point requires the user to configure the device.

[edit] Channel pollution

For more details on this topic, see Electromagnetic interference at 2.4 GHz.

Standardization is a process driven by market forces. Interoperability issues between non-Wi-Fi brands or proprietary deviations from the standard can still disrupt connections or lower throughput speeds on all user's devices that are within range, to include the non-Wi-Fi or proprietary product. Moreover, the usage of the ISM band in the 2.45 GHz range is also common to Bluetooth, WPAN-CSS, ZigBee and any new system will take its share.

Wi-Fi pollution, or an excessive number of access points in the area, especially on the same or neighboring channel, can prevent access and interfere with the use of other access points by others, caused by overlapping channels in the 802.11g/b spectrum, as well as with decreased signal-to-noise ratio (SNR) between access points. This can be a problem in high-density areas, such as large apartment complexes or office buildings with many Wi-Fi access points. Additionally, other devices use the 2.4 GHz band: microwave ovens, security cameras, Bluetooth devices and (in some countries) Amateur radio, video senders, cordless phones and baby monitors, all of which can cause significant additional interference. General guidance to those who suffer these forms of interference or network crowding is to migrate to a Wi-Fi 5 GHz product, (802.11a, or the newer 802.11n if it has 5 GHz support) because the 5 GHz band is relatively unused, and there are many more channels available. This also requires users to set up the 5 GHz band to be the preferred network in the client and to configure each network band to a different name (SSID). It is also an issue when municipalities,[9] or other large entities such as universities, seek to provide large area coverage. This openness is also important to the success and widespread use of 2.4 GHz Wi-Fi.

[edit] Hardware

[edit] Standard devices

An embedded RouterBoard 112 with U.FL-RSMA pigtail and R52 mini PCI Wi-Fi card widely used by wireless Internet service providers (WISPs) in the Czech Republic.
OSBRiDGE 3GN - 802.11n Access Point and UMTS/GSM Gateway in one device.
USB wireless adapter

A wireless access point (WAP) connects a group of wireless devices to an adjacent wired LAN. An access point is similar to a network hub, relaying data between connected wireless devices in addition to a (usually) single connected wired device, most often an ethernet hub or switch, allowing wireless devices to communicate with other wired devices.

Wireless adapters allow devices to connect to a wireless network. These adapters connect to devices using various external or internal interconnects such as PCI, miniPCI, USB, ExpressCard, Cardbus and PC card. Most newer laptop computers are equipped with internal adapters. Internal cards are generally more difficult to install.

Wireless routers integrate a Wireless Access Point, ethernet switch, and internal Router firmware application that provides IP Routing, NAT, and DNS forwarding through an integrated WAN interface. A wireless router allows wired and wireless ethernet LAN devices to connect to a (usually) single WAN device such as cable modem or DSL modem. A wireless router allows all three devices (mainly the access point and router) to be configured through one central utility. This utility is most usually an integrated web server which serves web pages to wired and wireless LAN clients and often optionally to WAN clients. This utility may also be an application that is run on a desktop computer such as Apple's AirPort.

Wireless network bridges connect a wired network to a wireless network. This is different from an access point in the sense that an access point connects wireless devices to a wired network at the data-link layer. Two wireless bridges may be used to connect two wired networks over a wireless link, useful in situations where a wired connection may be unavailable, such as between two separate homes.

Wireless range extenders or wireless repeaters can extend the range of an existing wireless network. Range extenders can be strategically placed to elongate a signal area or allow for the signal area to reach around barriers such as those created in L-shaped corridors. Wireless devices connected through repeaters will suffer from an increased latency for each hop. Additionally, a wireless device connected to any of the repeaters in the chain will have a throughput that is limited by the weakest link between the two nodes in the chain from which the connection originates to where the connection ends.

[edit] Distance records

Electronics portal

Distance records (using non-standard devices) include 382 km (237 mi) in June 2007, held by Ermanno Pietrosemoli and EsLaRed of Venezuela, transferring about 3 MB of data between mountain tops of El Aguila and Platillon.[10][11] The Swedish Space Agency transferred data 310 km (193 mi), using 6 watt amplifiers to reach an overhead stratospheric balloon.[12]

[edit] Embedded systems

Embedded serial-to-Wi-Fi module

Wi-Fi availability in the home is on the increase.[13] This extension of the Internet into the home space will increasingly be used for remote monitoring.[citation needed] Examples of remote monitoring include security systems and tele-medicine. In all these kinds of implementation, if the Wi-Fi provision is provided using a system running one of operating systems mentioned above, then it becomes unfeasible due to weight, power consumption and cost issues.

Increasingly in the last few years (particularly as of early 2007), embedded Wi-Fi modules have become available which come with a real-time operating system and provide a simple means of wireless enabling any device which has and communicates via a serial port.[14] This allows simple monitoring devices – for example, a portable ECG monitor hooked up to a patient in their home – to be created. This Wi-Fi enabled device effectively becomes part of the internet cloud and can communicate with any other node on the internet. The data collected can hop via the home's Wi-Fi access point to anywhere on the internet. [15]

These Wi-Fi modules are designed so that designers need minimal Wi-Fi knowledge to wireless-enable their products.

[edit] Network security

The main issue with wireless network security is its simplified access to the network compared to traditional wired networks such as ethernet. With wired networking it is necessary to either gain access to a building, physically connecting into the internal network, or break through an external firewall. Most business networks protect sensitive data and systems by attempting to disallow external access. Thus being able to get wireless reception (and thus possibly break the encryption) becomes an attack vector on the network as well.[16]

Attackers who have gained access to a Wi-Fi network can use DNS spoofing attacks very effectively against any other user of the network, because they can see the DNS requests made, and often respond with a spoofed answer before the queried DNS server has a chance to reply.[17]

[edit] Securing methods

Two common, but unproductive, measures to deter unauthorized users include suppressing the AP's SSID broadcast, allowing only computers with known MAC addresses to join the network, and various encryption standards. Suppressed SSID and MAC filtering are ineffective security methods as the SSID is broadcast in the open in response to a client SSID query and a MAC address can easily be spoofed. If the eavesdropper has the ability to change his MAC address, then he can potentially join the network by spoofing an authorized address.

Wired Equivalent Privacy (WEP) encryption was designed to protect against casual snooping, but is now considered completely broken. Tools such as AirSnort or aircrack can quickly recover WEP encryption keys. Once it has seen 5-10 million encrypted packets, AirSnort can determine the encryption password in under a second;[18] newer tools such as aircrack-ptw can use Klein's attack to crack a WEP key with a 50% success rate using only 40,000 packets.

To counteract this in 2002, the Wi-Fi Alliance blessed Wi-Fi Protected Access (WPA) which uses TKIP as a stopgap solution for legacy equipment. Though more secure than WEP, it has outlived its designed lifetime, has known attack vectors and is no longer recommended.

In 2004 the full IEEE 802.11i (WPA2) encryption standards were released. If used with a 802.1X server or in pre-shared key mode with a strong and uncommon passphrase WPA2 is still considered secure, as of 2009.

[edit] Piggybacking

Main article: Piggybacking (internet access)

During the early popular adoption of 802.11, providing open access points for anyone within range to use was encouraged to cultivate wireless community networks;[19] particularly since people on average use only a fraction of their upstream bandwidth at any given time.

Recreational logging and mapping of other people's access points has become known as wardriving. It is also common for people to use open (unencrypted) Wi-Fi networks as a free service, termed piggybacking. Indeed, many access points are intentionally installed without security turned on so that they can be used as a free service. These activities do not result in sanctions in most jurisdictions, however legislation and case law differ considerably across the world. A proposal to leave graffiti describing available services was called warchalking. In a Florida court case, owner laziness was determined not to be a valid excuse. [20]

Piggybacking is often unintentional. Most access points are configured without encryption by default, and operating systems such as Windows XP SP2 and Mac OS X may be configured to automatically connect to any available wireless network. A user who happens to start up a laptop in the vicinity of an access point may find the computer has joined the network without any visible indication. Moreover, a user intending to join one network may instead end up on another one if the latter's signal is stronger. In combination with automatic discovery of other network resources (see DHCP and Zeroconf) this could possibly lead wireless users to send sensitive data to the wrong middle man when seeking a destination (see Man-in-the-middle attack). For example, a user could inadvertently use an insecure network to login to a website, thereby making the login credentials available to anyone listening, if the website is using an insecure protocol like HTTP, rather than a secure protocol like HTTPS.

[edit] City wide Wi-Fi

Further information: Municipal wireless network
Sister project Wikibooks has a book on the topic of
A municipal wireless antenna in Minneapolis

In the early 2000s, many cities around the world announced plans for a city wide Wi-Fi network. This proved to be much more difficult than their promoters initially envisioned with the result that most of these projects were either canceled or placed on indefinite hold. A few were successful, for example in 2005, Sunnyvale, California became the first city in the United States to offer city wide free Wi-Fi.[21]

[edit] Origin and meaning of the term "Wi-Fi"

The term "Wi-Fi" suggests "Wireless Fidelity", compared with the long-established audio recording term "High Fidelity" or "Hi-Fi". "Wireless Fidelity" has often been used in an informal way, even by the Wi-Fi Alliance itself, but officially the term does not mean anything.

The term "Wi-Fi", first used commercially in August 1999,[22] was coined by a brand consulting firm called Interbrand Corporation that had been hired by the Alliance to determine a name that was "a little catchier than 'IEEE 802.11b Direct Sequence'."[23][24][25] Interbrand invented "Wi-Fi" as simply a play-on-words with "Hi-Fi", as well as creating the yin yang style Wi-Fi logo.

The Wi-Fi Alliance initially complicated matters by stating that it actually stood for "Wireless Fidelity", as with the advertising slogan "The Standard for Wireless Fidelity",[24] but later removed the phrase from their marketing. The Wi-Fi Alliance's early White Papers still held in their knowledge base: "… a promising market for wireless fidelity (Wi-Fi) network equipment."[26] and "A Short History of WLANs." The yin yang logo indicates that a product had been certified for interoperability.[27]

The Alliance has since downplayed the connection to "Hi-Fi". Their official position is that it is merely a brand name that stands for nothing in particular, and they now discourage the use of the term "Wireless Fidelity".

[edit] Wi-Fi Alliance

Main article: Wi-Fi Alliance

The Alliance promotes standards with the aim of improving the interoperability of wireless local area network products based on the IEEE 802.11 standards. The Wi-Fi Alliance, a consortium of separate and independent companies, agrees on a set of common interoperable products based on the family of IEEE 802.11 standards.[28] The Wi-Fi Alliance certifies products via a set of defined test-procedures to establish interoperability. Those manufacturers with membership of Wi-Fi Alliance and whose products pass these interoperability tests can mark their products and product packaging with the Wi-Fi logo.[29]

[edit] See also

Sister project Wikimedia Commons has media related to: Wi-Fi
Sister project Wikinews has related news: Wi-Fi
Sister project Look up wi-fi in
Wiktionary, the free dictionary.

[edit] References

  1. ^ "Authorization of Spread Spectrum Systems Under Parts 15 and 90 of the FCC Rules and Regulations" (TXT). Federal Communications Commission. June 18, 1985. http://www.marcus-spectrum.com/documents/81413RO.txt. Retrieved on 2007-08-31. 
  2. ^ "The Genesis of Unlicensed Wireless Policy". George Mason University. April 4, 2008. http://www.iep.gmu.edu/UnlicensedWireless.php. Retrieved on 2008-04-20. 
  3. ^ "Switch on for Square Mile wi-fi". news.bbc.co.uk. http://news.bbc.co.uk/2/hi/technology/6577307.stm. Retrieved on 2007-11-08. 
  4. ^ "MuniWireless » City Initiatives Directory". www.muniwireless.com. http://www.muniwireless.com/initiatives/2008/01/02/7483/. Retrieved on 2008-03-12. 
  5. ^ "Wi-Fi: Poskytovatelé bezdrátového připojení". internetprovsechny.cz. http://translate.google.com/translate?u=http%3A%2F%2Fwww.internetprovsechny.cz%2Fwifi-poskytovatele.php&hl=cs&ie=UTF8&sl=cs&tl=en. Retrieved on 2008-03-17. 
  6. ^ "Bezdrátové připojení k internetu". bezdratovepripojeni.cz. http://translate.google.com/translate?u=http%3A%2F%2Fwww.bezdratovepripojeni.cz&hl=cs&ie=UTF8&sl=cs&tl=en. Retrieved on 2008-05-18. 
  7. ^ "Wi-Fi Finder". jiwire.com. http://www.jiwire.com/search-hotspot-locations.htm. Retrieved on 2008-04-20. 
  8. ^ FCC Sec.15.249 Operation within the bands 902–928 MHz, 2400–2483.5 MHz, 5725–5875 MHZ, and 24.0–24.25 GHz.
  9. ^ Wilson, Tracy V.. "How Municipal WiFi Works". computer.howstuffworks.com. http://computer.howstuffworks.com/municipal-wifi.htm. Retrieved on 2008-03-12. 
  10. ^ "Ermanno Pietrosemoli has set a new record for the longest communication Wi-Fi link". http://interred.wordpress.com/2007/06/18/ermanno-pietrosemoli-has-set-a-new-record-for-the-longest-communication-wi-fi-link/. Retrieved on 2008-03-10. 
  11. ^ "Wireless technology is irreplaceable for providing access in remote and scarcely populated regions". http://www.apc.org/en/news/strategic/world/wireless-technology-irreplaceable-providing-access. Retrieved on 2008-03-10. 
  12. ^ "Long Distance WiFi Trial" (PDF). http://www.eslared.org.ve/articulos/Long%20Distance%20WiFi%20Trial.pdf. Retrieved on 2008-03-10. 
  13. ^ "estimated number of wi-fi spots globally". http://blogs.msdn.com/alexbarn/archive/2005/09/28/474794.aspx. Retrieved on 2005-05-28. 
  14. ^ "Quatech Rolls Out Airborne Embedded 802.11 Radio for M2M Market". http://edageek.com/2008/04/18/embedded-wifi-radio/. Retrieved on 2008-04-29. 
  15. ^ "CIE article on embedded WiFi for M2M applications". http://www.cieonline.co.uk/cie2/articlen.asp?pid=1810&id=19742. Retrieved on 2008-08-27. 
  16. ^ "802.11 X Wireless Network in a Business Environment -- Pros and Cons.". NetworkBits.net. http://networkbits.net/wireless-printing/80211-g-pros-cons-of-a-wireless-network-in-a-business-environment/. Retrieved on 2008-04-08. 
  17. ^ http://cr.yp.to/djbdns/forgery.html (first sentence
  18. ^ "Wireless Vulnerabilities & Exploits". wirelessve.org. http://www.wirelessve.org/entries/show/WVE-2005-0020. Retrieved on 2008-04-15. 
  19. ^ NoCat's goal is to bring you Infinite Bandwidth Everywhere for Free
  20. ^ See the wikinews article mentioned in this section.
  21. ^ "Sunnyvale Uses MetroFi". unstrung.com. http://www.unstrung.com/document.asp?doc_id=85119&WT.svl=wire1_1. Retrieved on 2008-07-16. 
  22. ^ U.S. Patent and Trademark Office.
  23. ^ "What is the True Meaning of Wi-Fi?". Teleclick. http://www.teleclick.ca/2005/12/what-is-the-true-meaning-of-wi-fi/. Retrieved on 2007-08-31. 
  24. ^ a b "WiFi isn't short for "Wireless Fidelity"". boingboing.net. http://www.boingboing.net/2005/11/08/wifi_isnt_short_for_.html. Retrieved on 2007-08-31. 
  25. ^ "Wireless Fidelity' Debunked". Wi-Fi Planet. http://www.wi-fiplanet.com/columns/article.php/3674591. Retrieved on 2007-08-31. 
  26. ^ "Enabling the Future of Wi-Fi Public Access". Wi-Fi.org. http://www.wi-fi.org/white_papers/whitepaper-010204-wifipublicaccess/. Retrieved on 2007-08-31. 
  27. ^ "Securing Wi-Fi Networks with Today's Technologies". Wi-Fi.org. http://www.wi-fi.org/white_papers/whitepaper-020603-securingwifi/. Retrieved on 2007-08-31. 
  28. ^ "Wi-Fi Alliance - Get to Know the Alliance". www.wi-fi.org. http://www.wi-fi.org/about_overview.php. Retrieved on 2007-11-08. 
  29. ^ "Wi-Fi Alliance - Certified Products". certifications.wi-fi.org. http://certifications.wi-fi.org/wbcs_certified_products.php. Retrieved on 2007-11-08. 

[edit] Further reading

Internet Access
Network Type Wired Wireless
Optical Coaxial Cable Ethernet Cable Phone line Power line Unlicensed terrestrial bands Licensed terrestrial bands Satellite
LAN 1000BASE-X G.hn Ethernet HomePNA  · G.hn G.hn Wi-Fi · Bluetooth · DECT · Wireless USB
WAN PON DOCSIS Dial-up · ISDN · DSL BPL Muni Wi-Fi GPRS · iBurst · WiBro/WiMAX · UMTS-TDD, HSPA · EVDO · LTE Satellite
Retrieved from "http://en.wikipedia.org/wiki/Wi-Fi"
Personal tools