Tag: Wi-Fi

22
May
2017

macOS Wi-FI Tip

Did you know that you can quickly access information about your Router, and check if your Wi-Fi Network is performing well? See your BSSID, signal-to-noise ratio, and even the transmit rate between your Router and Computer. All it takes is a press of a button and a click of your trackpad/mouse.

If you hold down the Option (alt) key and click the Wi-Fi icon in the menu bar, it will provide you with details about your Router and the Network you’re using. The items in gray (except for “Wi-Fi: On”) are all pieces of additional information seen only in this mode.

IP Address: This is your computer’s IP address.

Router: Your router’s IP address. You can type this into your browser to access your router’s web interface.

Internet: This tells you if you are able to access the internet or not. If not, open Wireless Diagnostics.

Security: Your router’s security. Most Routers on the market offer WPA2 Personal, and it keeps your network encrypted.

BSSID: This is your Router’s MAC, or hardware address. It acts as an identifier for your Router that lets it talk to other network-connected devices.

Channel: This is your WLAN channel, and it determines which radio frequency the router uses to transmit information.

RSSI: Received Signal Strength Indicator measures how well a device “hears” a signal from the router. It’s useful for determining if you have enough signal to get a good wireless connection.

Noise: This measures how much radio noise is interfering with the RSSI signal. Signal-to-noise ratio is a measure used in science and engineering that compares the level of a desired signal to the level of background noise. It is defined as the ratio of signal power to the noise power, often expressed in decibels.

TX Rate: The transmit rate is the speed of the data that is transmitted between your Router and your Computer. Right now I have a speed of 450 Mbps.

PHY Mode: This is the wireless protocol that the Router uses, according to the IEEE 802.11 wireless standard.

MCS Index: This number corresponds to the protocols uses to encode the radio signal.

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04
Nov
2013

Li-Fi LED Wireless Breakthrough

Light Fidelity

Researchers say they have achieved data transmission speeds of 10Gbit/s via “Li-Fi“; wireless internet connectivity using light via micro-LED light bulbs to transmit 3.5Gbit/s via each of the three primary colors – red, green, blue – that make up white light.

This means over 10Gbit/s is possible.

Li-Fi is an emerging technology that could see specialized LED lights bulbs providing low-cost wireless internet connectivity almost everywhere.

The research, known as the ultra-parallel visible light communications project, is a joint venture between the universities of Edinburgh, St Andrews, Strathclyde, Oxford, and Cambridge in the UK, and funded by the Engineering and Physical Sciences Research Council.

The tiny micro-LED bulbs, developed by the University of Strathclyde, Glasgow, allow streams of light to be beamed in parallel, each multiplying the amount of data that can be transmitted at any one time.

“If you think of a shower head separating water out into parallel streams, that’s how we can make light behave,” said Professor Harald Haas, an expert in optical wireless communications at the University of Edinburgh and one of the project leaders.

Using a digital modulation technique called Orthogonal Frequency Divisional Multiplexing (OFDM), researchers enabled micro-LED light bulbs to handle millions of changes in light intensity per second, effectively behaving like an extremely fast on/off switch.

This allows large chunks of binary data – a series of ones and zeros – to be transmitted at high speed.

Professor Haas coined the term “light fidelity” or li-fi – also known as visual light communications (VLC) – and set up a private company, PureVLC, to exploit the technology.

Li-Fi promises to be cheaper and more energy-efficient than existing wireless radio systems given the ubiquity of LED bulbs and the fact that lighting infrastructure is already in place.

Visible light is part of the electromagnetic spectrum and 10,000 times bigger than the radio spectrum, affording potentially unlimited capacity.

Another advantage, Professor Haas argues, is that evenly spaced LED transmitters could provide much more localized and consistent internet connectivity throughout buildings. The disadvantage of traditional Wi-Fi routers is that the signal weakens the further you are away from it, leading to inconsistent connectivity within offices and homes.

Professor Haas also believes light’s inability to penetrate walls makes VLC technology potentially more secure than traditional Wi-Fi connectivity.