CWNA – Chapter 2 Summary & Exam Essentials

CWNA Chapter 2 – IEEE 802.11 Standards and Amendments.

“Defined” means the amendment either no longer exists or it was rolled into the existing (or prior versions) 802.11-2007 spec. “Defines” means it is a ratified amendment that will be rolled into 802.11-2011. “Will define” means it is a work in progress and not yet amended.

802.11-1997 (sometimes called 802.11 “prime”) — the original 802.11 specifications included the base functionality along with FHSS and DSSS PHYs.

802.11a — Defined OFDM usage in 5 GHz with data rates up to 54 Mbps.
802.11b —Defined 5.5 and 11 Mbps with HR/DSSS in 2.4 GHz.
802.11c — Defined MAC bridging for 802.11. Was incorporated into 802.1D.

802.11-1999 rolled up 802.11 prime with new enhancements.

802.11d — Defined 802.11 operation in new regulatory domains.
802.11e — Defined QoS
802.11F — Recommended Inter-Access Point Protocol (IAPP) for interoperability of different vendor products. Was not used by anyone and is now withdrawn.

Note: A capital letter designates a recommended practice standalone standard (similar to 802.1X). A lowercase letter designates an amendment to a parent standard. Hence, 802.11F was designed to be a standalone document (and also happened to be a recommended practice), not a part of the full 802.11 standards. This is often a confusing topic in standards naming.

802.11g — Defined ERP PHY, which introduces data rates up to 54 Mbps in 2.4 GHz.

802.11-R2003 rolled up 802.11-1999 and prior amendments, excluding 802.11e.

802.11h — Defined Dynamic Frequency Selection (DFS) for radar detection and avoidance in some 5 GHz bands. Also defined Transmit Power Control (TPC) for managing client transmit power.
802.11i — Defined security enhancements including TKIP, CCMP, and use of 802.1X with WLANs.
802.11j — Defined 4.9 – 5 GHz operation in Japan.

802.11-2007 rolled up 802.11-R2003 with prior amendments.

802.11k — Defines radio resource management processes for RF data collection and sharing.
802.11l — Due to potential confusion between an “l” (letter) and “1” (number), 802.11l was bypassed.
802.11m — Was used as a maintenance amendment that updated inaccuracies, omissions, and ambiguities.
802.11n — Defines High Throughput (HT) PHY with MCS rates up to 600 Mbps in 2.4 GHz and 5 GHz.
802.11o — For similar reasons as 802.11l, 802.11o was bypassed. ‘Is that an “o” (letter) or a “0” (number)? I don’t know, let’s just skip it.’
802.11p — Defines wireless access for the vehicular environment (WAVE).
802.11q — Due to potential confusion with 802.1Q, 802.11q was bypassed.
802.11r — Defines fast BSS transitions (fast secure roaming). Maybe one of these days we’ll use it.
802.11s — Will define 802.11 mesh internetworking.
802.11T — Specified a way to test wireless performance prediction. Remember, capital letters are recommended practices standalone standards. 802.11T was canceled.
802.11u — Will define internetworking with external networks, such as cellular.
802.11v — Will define enhancements for network management.
802.11w — Defines protected management frames to prevent some security vulnerabilities.
802.11x — 802.11 technologies as a whole are often referred to as 802.11x, so this amendment was bypassed.
802.11y — Defines use of OFDM in 3650-3700 MHz.
802.11z —Defines enhancements to Direct Link Setup, which no one uses.
802.11aa — Will define enhancements to video transport streams.
802.11ab —Was bypassed to avoid confusion with devices using 802.11a and 802.11b PHY technologies, which are often abbreviated as 802.11ab.
802.11ac — Will define Very High Throughput (VHT) with gigabit speeds, building on 802.11n MIMO technology.
802.11ad — Will define short range Very High Throughput (VHT) in the 60 GHz spectrum.
802.11ae — Will define enhancements for QoS management.
802.11af — Will define the usage of Wi-Fi in newly opened TV whitespace frequencies.
802.11ag — Similar to 802.11ab, 802.11ag was skipped to avoid confusion with devices using 802.11a and 802.11g PHY technologies, which are often abbreviated as 802.11ag.
802.11ah — Will define the usage of Wi-Fi in frequencies below 1 GHz. Also used as an expression of Wi-Fi pleasure. 802.11…ah!
802.11ai — Will define FILS (fast initial link setup). Designed to address challenges in high-density environments which a large number of mobile users face.
802.11aj – Will define modifications to the IEEE 802.11ad-2012 amendment’s PHY and MAC layer to provide support to the Chinese Millimeter Wave (CMMW).
802.11ak – Will define amendment to General Link for use in bridged networks.
802.11aq – Will define delivery of network service information prior to the association of stations on 802.11 networks.
802.11ax – Will define HE(High Efficiency). Expected to be next big PHY enhancement to the 802.11 standards. Operate in both 2.4/5GHz.
802.11ay – Will define improvement of an 802.11ad amendment providing faster speeds.
802.11az – TBC

CWNA , IEEE 802.11!

  • Hi IEEE 802.11 Key Concepts

Let’s get started with the IEEE 802.11 Journey synopsis. Standards are defined at physical and mac-sub layer(data-link). We are referring to different ways of transmitting data over the air. Also how our communication signal would deliver information. One of the original ones we’ve come across is FHSS (Frequency Hopping Spread Spectrum) and DSSS (Distributed Sequence Spread Spectrum).

In 2007, the IEEE consolidated 8 ratified amendments along with the original standard, creating a single document that was published as the IEEE standard 802.11-2007
The standard covers IEEE standard 802.11-1999, 802.11a.1999, 802.11b-1999, 802.11g-2003,802.11i-2004

802.11b (Sep 1999) is high rate DSSS – Based on 2.4GHz to 2.4835 GHz ISM band
802.11a (Sep 1999) is OFDM (Orthogonal Frequency Divisional Multiplexing) would operate in 5GHz frequency.  There are 3 U-NIII (Unlicensed National Information Infrastructure) frequency bands consisting of 12 channels.
802.11b (1999) – High Rate DSSS, operates in 2.4 GHz frequency. OFDM transmission type and supports BPSK (binary phase shift keying) and QPSK (Quadrature PSK) – 1 & 5.5Mbps and 2 & 11 Mbps. 
802.11g (June 2003) – Speeds upto 54Mbps/works similar to 802.11b in 2.4 GHz. Used a new technology called Extended Rate Physical (ERP) – ISM frequency band.
802.11i (Security) – From 1997 – 2004, not much defined in terms of security in the original 802.11 standard. Three key components of security solution – Data Privacy/Data Integrity/Authentication. This amendment defined a RSN (Robust Security Network).
802.11r-2008 (FT)-  Technology is more often referred to as fast secure roaming because it defines faster handoffs when roaming occurs between cells in WLAN using a strong security defined by RSN.
802.11w (Sep 2009) – IEEE Task Group was a way of delivering management frames in a security manner. Preventing the management frames from being able to be spoofed.802.11 – only on 2.4. Uses hi rate DSSS. It actually came out before 802.11a. Enabled 5.5 and 11Mbps data rates. 22MHz wide channels. Today these rates have become legacy rates. 
802.11n (October 2009) – also known as Wi-Fi 4 is an amendment that improves upon the previous 802.11 standards by adding multiple-input multiple-output antennas (MIMO). 802.11n operates on both the 2.4 GHz and the 5 GHz bands. Support for 5 GHz bands is optional. Its net data rate ranges from 54 Mbit/s to 600 Mbit/s
802.11ac (December 2013) – VTH (Very high throughput, wider channel (20MHz-160MHz) – also known as Wi-Fi 5 is an amendment to IEEE 802.11, published in December 2013, that builds on 802.11n.[28] Changes compared to 802.11n include wider channels (80 or 160 MHz versus 40 MHz) in the 5 GHz band, more spatial streams (up to eight versus four), higher-order modulation (up to 256-QAM vs. 64-QAM), and the addition of Multi-user MIMO (MU-MIMO). As of October 2013, high-end implementations support 80 MHz channels, three spatial streams, and 256-QAM, yielding a data rate of up to 433.3 Mbit/s per spatial stream, 1300 Mbit/s total, in 80 MHz channels in the 5 GHz band
802.11ax ( Sometime in 2019*)  – IEEE 802.11ax also known as Wi-Fi 6 is the successor to 802.11ac, and will increase the efficiency of WLAN networks. Currently in development, this project has the goal of providing 4x the throughput of 802.11ac at the user layer, having just 37% higher nominal data rates at the PHY layer.  More can be read here

While learning about 802.11 PHYs (Physical) I have come across this extremely useful table from cleartosend podcasts/posts as below