The first wireless LAN technologies defined by the 802.11 standard were
low-speed proprietary offerings of 1 to 2 Mbps. Despite these shortcomings, the
freedom and flexibility of wireless allowed these early products to find a
place in technology markets. Mobile workers used hand-held devices for
inventory management and data collection in retail and warehousing. Later,
hospitals applied wireless technology to gather and deliver patient
information. As computers made their way into the classrooms, schools and
universities began installing wireless networks to avoid cabling costs, while
enabling shared Internet access. Realizing the need for an Ethernet-like
standard, wireless vendors joined together in 1991 and formed the Wireless
Ethernet Compatibility Alliance (WECA). WECA proposed and built a standard
based on contributed technologies. WECA later changed its name to Wi-Fi. In
June 1997, the IEEE released the 802.11 standard for wireless local-area
networking. Figure
illustrates the
wireless LAN evolution.
Just as the 802.3 Ethernet standard allows for data transmission over
twisted-pair and coaxial cable, the 802.11 WLAN standard allows for
transmission over different media. Specified media include the following:

- Infrared light
- Three types of radio transmission within the unlicensed 2.4-GHz frequency
bands:
- Frequency hopping spread spectrum (FHSS)
- Direct sequence spread spectrum (DSSS)
- Orthogonal frequency-division multiplexing (OFDM) 802.11g
- One type of radio transmission within the unlicensed 5-GHz frequency bands:
- Orthogonal frequency-division multiplexing (OFDM) 802.11a
Spread spectrum is a modulation technique that was developed in the
1940s. It spreads a transmission signal over a broad range of radio
frequencies. This technique is ideal for data communications because it is less
susceptible to radio noise and creates little interference.
The
Future of Wireless Local-Area Networking
Current WLAN technologies
offer increasing data rates, better reliability and dependability, and
decreasing costs. Data rates have increased from 1 Mbps to 54 Mbps,
interoperability has become a reality with the introduction of the IEEE 802.11
family of standards, and prices have dramatically decreased. As WLANs become
more popular, manufacturers can increasingly leverage economies of scale.
There will be many improvements to come. For example, many weaknesses have
been found in the basic security settings of WLANs, and stronger security in
all future products is a priority. Versions such as 802.11g will offer 54 Mbps
like 802.11a, but also will be backward compatible with 802.11b.
This course will cover the general technologies behind 802.11a and 802.11b
WLANs, including radio technologies, WLAN design, site preparation, and antenna
theory. Detailed coverage of the Cisco Aironet products and accessories will
also be presented. Students should be able to apply their knowledge at the
completion of the course to design WLANs using products from one or multiple
vendors.