Understanding Where 802.11ad WiGig Fits Into the Gigabit Wi-Fi Picture
The wireless world is evolving rapidly in response to the explosion of intelligent devices, applications and data, and the IEEE 802.11ad standard, commonly known as WiGig, is poised to help.
Wed, December 04, 2013
Network World — The wireless world is evolving rapidly in response to the explosion of intelligent devices, applications and data, and the IEEE 802.11ad standard, commonly known as WiGig, is poised to help.
WiGig is a step change from the 802.11 evolution we have witnessed over the last 10 years, adding a new frequency band, 60 GHz, to existing products: 802.11n operates in the 2.4-GHz and 5-GHz bands, while newer 802.11ac products operate in the 5-GHz band.
By enabling the emergence of tri-band products -- such as 802.11n/ac + 802.11ad -- WiGig opens the door to exciting applications and makes it more possible for all intelligent devices to be connected through a high speed Wi-Fi network.
But, we get ahead of ourselves. First, let's see what WiGig is all about.
* Speed.A The WiGig spec is defined to support speeds up to 7Gbps, but this is really just a start. By using some of the basic techniques we see today in .11n and .11ac, up to 100Gbps is achievable within the next few years. How?
" A While .11ac can go up to 8x8 MIMO, 256 QAM modulation and channel bond four 40 MHz channels, .11ad is able to achieve the same speeds with one spatial stream, 64 QAM modulation and a single channel.
" A Using all of the techniques that 802.11 has used in the last decade to achieve higher performance in the legacy bands (channel bonding and MIMO and higher modulation), the Wi-Fi industry can easily achieve much faster speeds.
" Using an industry analogy 60 GHz technology today is in the ".11b phase" of the technology evolution. We are just at the beginning of an exciting technical road map progression that will take WiGig to new heights using proven techniques, as well as new ones, yet to be discovered.
* High capacity. 16-32 antenna element arrays generate real spatial separation and make high capacity wireless deployments a reality.
" Approximately the same area of a single 2.4 GHz antenna module can contain 32 or more 60GHz antennas.
" Beamforming with such a large antenna array allows for highly directive communication, allowing for multiple devices working side by side in the same room with minimal effect on devices around them.
" Interference-free transmissions allow for capacity to be additive. In most omni-directional radio technologies, the overall bandwidth is divided by the number of users, which is dilutive rather than additive.
* Most power efficient Wi-Fi technology yet. Running multiple gigabits per second of real throughput at only hundreds of milliwatts total system power is achievable with 802.11ad, making it far and away the most power efficient technology in the Wi-Fi portfolio.