Weightless (wireless communications)

Weightless was a set of low-power wide-area network (LPWAN) wireless technology specifications for exchanging data between a base station and many of machines around it.

History

Cambridge Wireless held an event at the Moller Centre in Cambridge, United Kingdom on September 30, 2011. Neul, Landis+Gyr, Cable & Wireless, and ARM Holdings provided presentations. The Weightless Special Interest Group promoted the technology (SIG), announced on December 7, 2012. The group was led by William Webb, a professor at Cambridge and a founder of the company Neul. A subsequent event was held in September 2013, when version 1.0 was published.

The name Weightless was chosen to reflect the intention at a low overhead per transmission for devices that need to communicate just a low amounts of data. The Weightless logo appears in uppercase letters with the 'W' appearing in the top-right corner of a light blue box with a solid blue line above it.

In September 2014, Neul was acquired by Huawei for an estimated $25 million. By 2015, the company Nwave Technologies announced deployments in Copenhagen, Denmark, and Esbjerg, Denmark. However, observers noted no products on the market. A company called Ubiik, based in Taiwan, announced pre-orders in 2017.

Implementation

Weightless-N uses a differential binary phase shift keying (DBPSK) digital modulation scheme to transmit within narrow frequency bands using a frequency hopping algorithm for interference mitigation and enhanced security. It provides encryption and implicit authentication using a shared secret key regime to encode transmitted information via a 128-bit AES algorithm. The technology supports mobility with the network automatically routing terminal messages to the correct destination. Multiple networks, typically operated by different companies, are enabled and can be co-located. Each base station queries a central database to determine which network the terminal is registered to decode and route data accordingly.

Weightless-W uses time-division duplex operation with frequency hopping and variable spreading factors to increase range and accommodate low-power devices in frequency bands, or channels, within the terrestrial television broadcast band. Channels used by a nearby television transmitter are identified and left unaffected, while channels not being used for broadcasting television can be allocated for use by Weightless devices.^[1]

A network of base stations communicates with the Internet, or a private network, to pass information from devices to a computer system; and data back to the devices. The downlink to devices uses time slots (TDMA), and the uplink to the base station is divided into sub-channels so that several devices can communicate with the base station.

Initially, there were three published Weightless connectivity standards Weightless-P, Weightless-N, and Weightless-W. Weightless-N was an uplink-only LPWAN technology. Weightless W was designed to operate in the TV whitespace. Weightless-P, with bi-directional, narrowband technology intended to be operated in licensed and unlicensed ISM frequencies, was then just called "Weightless."^[2]

Communication and Connection

A base station transmits a Weightless frame received by a few thousand devices. The devices are allocated a specific time and frequency to transfer their data back to the base station. The base station is connected to the Internet or a private network. The base station accesses a database to identify the frequencies or channels that it can use without interfering with terrestrial television broadcasts in its local area.^[3]

Weightless is a wireless communications protocol for machine-to-machine (M2M) communications known as the Internet of things (IoT) – over distances ranging from a few meters to about 10 km.^[4]

Related technologies

Other technologies which use the channels not used for terrestrial television broadcast in a particular area are also said to be in development. One is Wi-Fi under the standard IEEE 802.11af. The IEEE 802.22 standard defines a MAC and PHY layer for TV white spaces that comply with the FCC and international standards for broadcasting in this spectrum. It also defines a general protocol model for negotiating and selecting a shared spectrum band for device operation. A Weightless Radio implementation would comply with this standard to cooperatively share the available spectrum.

Another technology is developed by the company Sigfox.^[5]

Specifications and features

The original Weightless specification was developed for machine-to-machine, low-cost, low-power communication system for use in the white space between TV channels in 2011 by engineers working at Neul in Cambridge, UK.^[6] The Weightless-W specification is based on time-division duplex technology with spread spectrum frequency hopping in an attempt to minimise the impact of interference and with variable spreading factors in an attempt to increase range (at the expense of lower data rate) and to accommodate low power devices with low data rates.

Weightless v1.0

The formal Weightless-W Standard was published in February 2013. The Weightless-N Standard was published in May 2015. For networks using Weightless-W technology, a base station queries a database which identifies the channels that are being used for terrestrial television broadcast in its local area. The channels not in use – the so-called white space – can be used by the base station to communicate with terminals using the Weightless-W protocol. Terminal endpoints were designed to be low-cost devices using minimal power so that they could work autonomously for up to several years.^[7]

Air interface

The Weightless-W protocol operates in the TV channels band. The Weightless-W protocol divides the band into channels. A database is queried by a base station to determine which channels are in use by terrestrial television broadcast stations in the area, and which ones are free for use by white space devices (such as those using Weightless). A range of modulation and encoding techniques are used to permit each base station to communicate at a variety of speeds with terminals, some of which may be nearby and others several km away. Data rates may vary depending on the distance and the presence of radio interference – the typical range is alleged to be between about 0.1 Mbit/s and 16 Mbit/s. The design of the air interface and protocol minimises the costs of the equipment and its power consumption. A broadband downlink from a base station to a terminal uses single carrier in an unused 6 MHz (for US) or 8 MHz (for UK) TV channel.^[8]

References

↑ Bill Ray (August 18, 2011). "White Space: The Next Big Thing in networks". The Register. https://www.theregister.co.uk/2011/08/18/white_space/.
↑ Marc Ambasna-Jones (August 15, 2018). "Meet the LPWAN clan: The Internet of Things' low power contenders". The Register. https://www.theregister.com/2018/08/15/lpwan_runners_and_riders/. Retrieved September 23, 2021.
↑ Bill Ray (June 27, 2011). "Cambridge gets a white (space) wash". The Register. https://www.theregister.co.uk/2011/06/27/white_space_trials/. Retrieved September 24, 2021.
↑ Bill Ray (June 14, 2011). "Cambridge startup launches world's first white space radio: 16Mb/s, 10km range, battery-powered and licence-free... just not legal". The Register. https://www.theregister.co.uk/2011/06/14/neul_radio/. Retrieved September 24, 2021.
↑ Calum McClelland (June 30, 2020). "IoT Connectivity - Comparing NB-IoT, LTE-M, LoRa, SigFox, and other LPWAN Technologies". IoT for All. https://www.iotforall.com/iot-connectivity-comparison-lora-sigfox-rpma-lpwan-technologies. Retrieved September 23, 2021.
↑ Bill Ray (April 22, 2011). "How to build a national cellular wireless network for £50m: It's easy when all your customers are machines". The Register. https://www.theregister.co.uk/2011/04/22/white_space_neul/. Retrieved September 24, 2021.
↑ Brian Benchoff (October 25, 2013). "Weightless, the Internet of things chip, becomes less vaporware". Hackaday Blog. https://hackaday.com/2013/10/25/weightless-the-internet-of-things-chip-becomes-less-vaporware/.
↑ Ian Poole (2012). "Weightless Wireless M2M White Space Communications". Radio-Electronics. http://radio-electronics.com/info/wireless/weightless-m2m-white-space-wireless-communications/basics-overview.php.

External links

Weightless Alliance
White Space Networks and Machine-to-Machine (M2M) Services at Oxford University

0.00

(0 votes)

Original source: https://en.wikipedia.org/wiki/Weightless (wireless communications). Read more

[1] Bill Ray (August 18, 2011). "White Space: The Next Big Thing in networks". The Register. https://www.theregister.co.uk/2011/08/18/white_space/.

[2] Marc Ambasna-Jones (August 15, 2018). "Meet the LPWAN clan: The Internet of Things' low power contenders". The Register. https://www.theregister.com/2018/08/15/lpwan_runners_and_riders/. Retrieved September 23, 2021.

[3] Bill Ray (June 27, 2011). "Cambridge gets a white (space) wash". The Register. https://www.theregister.co.uk/2011/06/27/white_space_trials/. Retrieved September 24, 2021.

[4] Bill Ray (June 14, 2011). "Cambridge startup launches world's first white space radio: 16Mb/s, 10km range, battery-powered and licence-free... just not legal". The Register. https://www.theregister.co.uk/2011/06/14/neul_radio/. Retrieved September 24, 2021.

[5] Calum McClelland (June 30, 2020). "IoT Connectivity - Comparing NB-IoT, LTE-M, LoRa, SigFox, and other LPWAN Technologies". IoT for All. https://www.iotforall.com/iot-connectivity-comparison-lora-sigfox-rpma-lpwan-technologies. Retrieved September 23, 2021.

[6] Bill Ray (April 22, 2011). "How to build a national cellular wireless network for £50m: It's easy when all your customers are machines". The Register. https://www.theregister.co.uk/2011/04/22/white_space_neul/. Retrieved September 24, 2021.

[summit2013-7] Brian Benchoff (October 25, 2013). "Weightless, the Internet of things chip, becomes less vaporware". Hackaday Blog. https://hackaday.com/2013/10/25/weightless-the-internet-of-things-chip-becomes-less-vaporware/.

[8] Ian Poole (2012). "Weightless Wireless M2M White Space Communications". Radio-Electronics. http://radio-electronics.com/info/wireless/weightless-m2m-white-space-wireless-communications/basics-overview.php.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

v t e Internet access
Wired	Cable Dial-up DOCSIS DSL Ethernet FTTx G.hn HD-PLC HomePlug HomePNA IEEE 1901 ISDN MoCA PON Power-line Broadband
Wireless PAN	Bluetooth Li-Fi Wireless USB
Wireless LAN	Wi-Fi
Long range wireless	DECT EVDO GPRS HSPA iBurst LTE MMDS Muni Wi-Fi Satellite UMTS-TDD WiMAX WiBro

v t e Spread spectrum in digital communications
Main articles	Spread spectrum Code-division multiple access (CDMA) History Hedy Lamarr Commercial use More...
Spread spectrum methods	Direct-sequence spread spectrum (DSSS) Frequency-hopping spread spectrum (FHSS) Chirp spread spectrum (CSS) Time-hopping spread spectrum (THSS)
CDMA schemes	W-CDMA TD-CDMA TD-SCDMA DS-CDMA FH-CDMA MC-CDMA
Major implementations	Space Network (NASA) GPS Galileo GLONASS Bluetooth Cordless phones: DECT Cellular EV-DO Mobile IS-95 (aka cdmaOne) CDMA2000 (aka IS-2000) Also Qualcomm Verizon
Major concepts	PN (pseudorandom noise) code Chip Near–far problem Power spectral density (PSD) Process gain Rake receiver Low probability of intercept
See also Digital communication Modulation Statistical multiplexing Waveform

v t e Telecommunications
History	Beacon Broadcasting Cable protection system Cable TV Communications satellite Computer network Data compression audio DCT image video Digital media Internet video online video platform social media streaming Drums Edholm's law Electrical telegraph Fax Heliographs Hydraulic telegraph Information Age Information revolution Internet Mass media Mobile phone Smartphone Optical telecommunication Optical telegraphy Pager Photophone Prepaid mobile phone Radio Radiotelephone Satellite communications Semaphore Semiconductor device MOSFET transistor Smoke signals Telecommunications history Telautograph Telegraphy Teleprinter (teletype) Telephone The Telephone Cases Television digital streaming Undersea telegraph line Videotelephony Whistled language Wireless revolution
Pioneers	Nasir Ahmed Edwin Howard Armstrong Mohamed M. Atalla John Logie Baird Paul Baran John Bardeen Alexander Graham Bell Tim Berners-Lee Jagadish Chandra Bose Walter Houser Brattain Vint Cerf Claude Chappe Yogen Dalal Donald Davies Lee de Forest Philo Farnsworth Reginald Fessenden Elisha Gray Oliver Heaviside Erna Schneider Hoover Harold Hopkins Internet pioneers Bob Kahn Dawon Kahng Charles K. Kao Narinder Singh Kapany Hedy Lamarr Innocenzo Manzetti Guglielmo Marconi Robert Metcalfe Antonio Meucci Jun-ichi Nishizawa Radia Perlman Alexander Stepanovich Popov Johann Philipp Reis Claude Shannon Henry Sutton Nikola Tesla Camille Tissot Alfred Vail Charles Wheatstone Vladimir K. Zworykin
Transmission media	Coaxial cable Fiber-optic communication optical fiber Free-space optical communication Molecular communication Radio waves wireless Transmission line data transmission circuit telecommunication circuit
Network topology and switching	Bandwidth Links Nodes terminal Network switching (circuit packet) Telephone exchange
Multiplexing	Space-division Frequency-division Time-division Polarization-division Orbital angular-momentum Code-division
Networks	ARPANET BITNET Cellular network Computer CYCLADES Ethernet FidoNet Internet Internet2 ISDN LAN Mobile NGN NPL network Public Switched Telephone Radio Telecommunications equipment Television Telex WAN Wireless network World Wide Web
Category Outline Portal Commons

Anonymous

Search

Weightless (wireless communications)

Namespaces

More

Page actions

Contents

History