Wi-Fi standards every engineer should know about
In just 19 years (starting in September 1998), Wi-Fi has evolved from an inactive technology to one that’s robust and versatile. It now also plays an integral role in the lives of hundreds of millions of people, it is being improved almost constantly.But will these changes bring about the two most important things consumers and companies are looking for: range and speed?
Three recently-adopted Wi-Fi standards that have been created to reach these goals:
802.11ad (AD)—2012: created for multigigabit speeds (sans wires) and high-performance networking.
802.11af (AF)—2014: created for applications similar to HaLow. (This network option relies on unused TV spectrums instead of 2.4 GHz or 5 GHz bands for transmission.)
802.11ah (HaLow)—2016: created for low data rate, long-range sensors and controllers.
The Institute of Electronics and Electronics Engineers is a professional association that acts as an authority for electronic communication. The IEEE creates standards and protocols for communication in industries like telecommunications and information technology, says Mayank Singh, IoT instructor at Eckovation.
Each standard the IEEE ratifies is designated by a unique number; 802 is the prefix used for any protocol or amendment that entails area networking. For instance, standards for ethernet local area networks (LANs); are designated by 802.3, and Bluetooth personal area networks (PANs) are designated by 802.15; Wireless LANs—the subject of this article—are designated by 802.11.
Here are a few Wi-Fi standards
802.11a (1990): “Wi-Fi A” — also known as the OFDM (Orthogonal, Frequency Division Multiplexing) waveform — was the first amendment, coming two years after the standard was complete. This amendment defined 5 gigahertz band extensions, which made Wi-Fi A more flexible (since the 2.4 GHz space was crowded with wireless home telephones, baby monitors, microwaves and more).
802.11b (2000): As one of the first widely used protocols, “Wi-Fi B”; had an improved range and transfer rate over 802.11a; but it is very slow by today’s standards (maxing out at 11 mbps). 802.11b defined 2.4 GHz band extensions. This protocol is still supported (80% of Wi-Fi runs off 2.4 GHz),; but the technology isn’t manufactured anymore because it’s been replaced by faster options.
802.11g (2003): “Wi-Fi G” came onto the market three years after b,; offering roughly five times the transfer rate, at 54 mbps. It defined 2.4 GHz band extensions at a higher data rate. Its primary benefit was greater speed, which was important to consumers. Today, however, these speeds are not fast enough to keep up with the average number of Wi-Fi;-enabled devices in a household or a strong wireless draw from a number of devices.
2.4 GHz ISM
2.4 GHz ISM gg
5 GHz U-NII aa
BPSK, QPSK, 16-, 64-QAM
Optional- RC4m AESin802.11iAESin802.11i
802.11n (2007): “Wi-Fi N” offered another drastic improvement in transfer rate speed — 300-450 mbps, depending on the number of antennas — and range. This was the first main protocol that operated on both 2.4 GHz and 5 GHz. These transfer rates allowed large amounts of data to be transmitted more quickly than ever before.
Some new standards
802.11ac (2013): In 2013, “Wi-Fi AC” was introduced. AC was the first step in what is considered “Gigabit […]