Broadband over power lines

Broadband over power lines (BPL) is a method of power line communication (PLC) that allows relatively high-speed digital data transmission over the public electric power distribution wiring. BPL uses higher frequencies, a wider frequency range and different technologies from other forms of power-line communications to provide high-rate communication over longer distances. BPL uses frequencies which are part of the radio spectrum allocated to over-the-air communication services therefore the prevention of interference to, and from, these services is a very important factor in designing BPL systems.

History

BPL is based on PLC technology developed as far back as 1914 by US telecommunications company AT&T.[1] Electricity companies have been bundling radio frequency on the same line as electrical current to monitor the performance of their own power grids for years. More recently there have been attempts to implement access BPL, or the provision of internet services to customers via the grid. The prospect of BPL was predicted in 2004 to possibly motivate DSL and cable operators to more quickly serve rural communities.[2]

The high level of attenuation (or data signal loss) from access BPL power cables had two critical effects: It limited bandwidth, and it attracted opposition from groups within the radio community.

Implementation

Generally BPL is described as either In-House BPL to network machines within a building, or Access BPL which will carry broadband Internet using power lines and allow power companies to monitor power systems.[3]

Because electric current and radio (data) signals vibrate at different frequencies they do not interfere with each other enough to significantly disrupt data transmission. This only works on low-voltage and medium-voltage cables. High-voltage cables do not vibrate at a consistent frequency, causing regular spikes which cancel the data signal and severely interrupt the transmission.[4]

MV lines carry generally up to 100 kilovolts, over a few kilometres between the electricity distribution stations and pole-mounted transformers. Low voltage lines transmit a few hundred volts over a few hundreds of metres, usually from pole-mounted transformers into a home or business.

Typically modem couplers embed data signals on to MV lines at the substation, with extractors at the LV distribution transformer feeding power into a group of buildings.

BPL modems transmit in medium and high frequency (1.6 to 80 MHz electric carrier). The asymmetric speed in the modem is generally from 256 kbit/s to 2.7 Mbit/s. In the repeater situated in the meter room the speed is up to 45 Mbit/s and can be connected to 256 PLC modems. In the medium voltage stations, the speed from the head ends to the Internet is up to 135 Mbit/s. To connect to the Internet, utilities can use optical fiber backbone or wireless link.

Utility companies use frequencies below 490KHz for their own data applications. Most BPL equipment was built to operate between 1.7MHz and 30MHz and occasionally up to 80MHz.

Technical challenges

Deployment of BPL has illustrated a number of fundamental challenges, the primary one being that power lines are inherently a very noisy environment. Every time a device turns on or off, it introduces a pop or click into the line. Switching power supplies often introduce noisy harmonics into the line. And unlike coaxial cable or twisted-pair, the wiring has no inherent noise rejection.

The second major issue is electromagnetic compatibility (EMC). The system was expected to use frequencies of 10 to 30 MHz in the high frequency (HF) range, used for decades by military, aeronautical, amateur radio, and by shortwave broadcasters. Power lines are unshielded and will act as antennas for the signals they carry, and they will cause interference to high frequency radio communications and broadcasting. In 2007, NATO Research and Technology Organisation released a report which concluded that widespread deployment of BPL may have a "possible detrimental effect upon military HF radio communications."[5]

Deployments

There have been many attempts world wide to implement access BPL, all which have indicated that BPL is not viable as a means of delivering broadband Internet access. This is because of two problems: limited reach, and low bandwidth which do not come close to matching ADSL, Wi-Fi, and even 3G mobile. World major providers have either limited their BPL deployments to low-bandwidth connected equipment via smart grids, or ceased BPL operations altogether.

Australia saw trials of access BPL between 2004 and 2007; but no active access BPL deployments appear to remain there.[4]

In the UK, the BBC published the results of tests to detect interference from BPL installations.[6][7][8]

In the US, in October 2004, the U.S. Federal Communications Commission adopted rules to facilitate the deployment of "Access BPL", the marketing term for Internet access service over power lines.

The technical rules are more liberal than those advanced by the US national amateur radio organization, the American Radio Relay League (ARRL), and other spectrum users, but include provisions that require BPL providers to investigate and correct any interference they cause.

One service was announced in 2004 for Ohio, Kentucky, and Indiana by Current Communications [9] but they left the BPL business in 2008.[10][11]

On 3 August 2006 FCC adopted a memorandum opinion and an order on broadband over power lines, giving the go-ahead to promote broadband service to all Americans.[12] The order rejected calls from aviation, business, commercial, amateur radio and other sectors of spectrum users to limit or prohibit deployment until further study was completed. FCC chief Kevin Martin said that BPL "holds great promise as a ubiquitous broadband solution that would offer a viable alternative to cable, digital subscriber line, fiber, and wireless broadband solutions".[13][14]

In the USA, International Broadband Electric Communications (IBEC), which had a ambitious plan to provide access BPL in the USA, ceased BPL operations in January 2012.[15][16]

Standards

IEEE 1901 is a standard for high speed (up to 500 Mbit/s at the physical layer) BPL.[17] It uses transmission frequencies below 100 MHz. It is usable by all classes of BPL devices, including BPL devices used for the last mile connection (less than 1500m to the premises) to internet access services as well as BPL devices used within buildings for local area networks, smart grid, PLC applications.[18]

Failure scenarios

There are many ways in which the communication signal may have error introduced into it. Interference, cross chatter, some active devices, and some passive devices all introduce noise or attenuation into the signal. When error becomes significant the devices controlled by the unreliable signal may fail, become inoperative, or operate in an undesirable fashion.

  1. Interference: Interference from nearby systems can cause signal degradation as the modem may not be able to determine a specific frequency among many signals in the same bandwidth.
  2. Signal degradation by active devices: Devices such as relays, transistors, and rectifiers create noise in their respective systems, increasing the likelihood of signal degradation. Arc-fault circuit interrupter (AFCI) devices, required by some recent electrical codes for living spaces, may also attenuate the signals.[19]
  3. Signal attenuation by passive devices: Transformers and DC-DC converters attenuate the input frequency signal almost completely. "Bypass" devices become necessary for the signal to be passed on to the receiving node. A bypass device may consist of three stages, a filter in series with a protection stage and coupler, placed in parallel with the passive device.

Ultra-High-frequency (≥100 MHz)

Even higher information rate transmissions over power line use RF through microwave frequencies transmitted via a transverse mode surface wave propagation mechanism that requires only a single conductor. An implementation of this technology is marketed as E-Line. These use microwaves instead of the lower frequency bands, up to 2–20 GHz. These frequencies would interfere with radio astronomy [20] when used outdoors. But, the advantage of speeds competitive with fibre optic cables, without new wiring, are likely to outperform that problem.

These systems claim symmetric and full duplex communication in excess of 1 Gbit/s in each direction.[21] Multiple Wi-Fi channels with simultaneous analog television in the 2.4 and 5.3 GHz unlicensed bands have been demonstrated operating over a single medium voltage line conductor. Because the underlying propagation mode is extremely broadband (in the technical sense), it can operate anywhere in the 20 MHz - 20 GHz region. Also, since it is not restricted below 80 MHz, as is the case for high-frequency BPL, these systems can avoid the interference issues associated with use of shared spectrum with other licensed or unlicensed services.[22]

Real Plug and Play Last Mile Communications System

The worldwide patented UHF based power line communication products' advantages are that: there is no need for any installation to deploy several hundred Mbit/s to several Gbit/s throughput speed with AC-WAN(TM) to AC-LAN(TM) modems for the Last Mile communication application; there are no interference problems; it is the cheapest Last Mile solution; the most stable Last Mile solution among wireless and BPL products; it communicates without repeater for +500 meter distance in any rural area directly through any size transformers, between the 3 phase power lines and through the electricity meters; it communicates with repeater for the last couple of mile distances directly through any size transformers, between the 3 phase power lines and through the electricity meters; it delivers around 100 Mbit/s throughput speed for the Last Mile application.

Typical wireless and BPL products throughput speed is about 10-20% of the raw data rate. What this means is that the advertised 200 Mbit/s modem will deliver maybe 1-10 Mbit/s throughput speed beyond 300 meters after several repeaters. These types of modems throughput speed is also significantly changing when the power load or the number of users are changing.

The AC-WAN(TM) to AC-LAN(TM) modems' throughput speed is about 50% of the raw data rate and resolve these problems since the power load changes or the number of user changes don't affect its throughput speed significantly.[23]

See also

References

  1. "Telephony over Power Lines (Early History) - Engineering and Technology History Wiki". ethw.org. Retrieved 2016-02-20.
  2. Denis Du Bois (9 December 2004). "Broadband over Powerlines (BPL) in a Nutshell". Energy Priorities blog. Retrieved 6 November 2013.
  3. "How Broadband Over Powerlines Works". HowStuffWorks. Retrieved 2016-02-22.
  4. 1 2 "Whatever happened to Broadband over Power Line? - E & T Magazine". eandt.theiet.org. Retrieved 2016-02-20.
  5. "HF Interference, Procedures and Tools" (PDF). Final Report of NATO RTO Information Systems Technology Panel Research Task Group IST-050/RTG-022. NATO Research and Technology Organisation. June 2007. Retrieved 6 November 2013.
  6. The effects of PLT on broadcast reception
  7. PLT and Broadcasting
  8. Co-existence of PLT and Radio Services
  9. Grant Gross (2 March 2004). "Vendor Offers Broadband by Power Lines". PC World. Retrieved 22 July 2011.
  10. Katie Fehrenbacher (13 Sep 2011). "Current's pivot: From broadband to smart grid to overseas". GigaOM. Retrieved 13 June 2012.
  11. "CURRENT Group Says Goodbye to BPL Industry". SmartGrid News. 19 Feb 2008. Retrieved 13 June 2012.
  12. "FCC Adopts Memorandum Opinion and Order on Broadband over Power Lines to Promote Broadband Service to all Americans" (PDF). News release. 3 August 2006. Retrieved 22 July 2011.
  13. "Statement of Chairman Kevin J. Martin" (PDF). 3 August 2006. Retrieved 22 July 2011.
  14. Schwager, Andreas; Berger, Lars T. (February 2014). "PLC Electromagnetic Compatibility Regulations". In Berger, Lars T.; Schwager, Andreas; Pagani, Pascal; Schneider, Daniel M. MIMO Power Line Communications: Narrow and Broadband Standards, EMC, and Advanced Processing. Devices, Circuits, and Systems. CRC Press. pp. 169–186. doi:10.1201/b16540-9. ISBN 9781466557529.
  15. Joan Engebretson (3 January 2012). "IBEC Shutdown Deals Latest Blow to BPL". Telecompetitor. Retrieved 6 November 2013.
  16. "Nelson County Broadband Provider IBEC Drops Service". WVIR-TV. 2 January 2012. Retrieved 6 November 2013.
  17. Nayagam, Arun; Rajkotia, Purva R.; Krishnam, Manjunath.; Rindchen, Markus. (February 2014). "chapter 13". In Berger, Lars T.; Schwager, Andreas; Pagani, Pascal; Schneider, Daniel M. IEEE 1901: Broadband over Power Line Networks. CRC Press. pp. 391–426. ISBN 9781466557529.
  18. "Final IEEE 1901 Broadband Over Power Line Standard Now Published". Press release. IEEE Standard Association. 1 February 2011. Retrieved 23 December 2013.
  19. A Work in Progress: Belkin Gigabit Powerline HD available at http://www.smallnetbuilder.com/lanwan/lanwan-reviews/30888-a-work-in-progress-belkin-gigabit-powerline-hd-starter-kit-reviewed?start=4
  20. http://ntrg.cs.tcd.ie/undergrad/4ba2.05/group13/index.html#21
  21. Glenn Elmore (August 2006). "Understanding the information rate of BPL and other last-mile pipes". Computing Unplugged magazine. Retrieved 22 July 2011.
  22. Glenn Elmore (July 27, 2009). "Introduction to the Propagating TM Wave on a Single Conductor" (PDF). Corridor Systems. Retrieved 22 July 2011.
  23. Charles Abraham (21 April 2014). "The Real Plug and Play Broadband Last Mile Communication Device Without the Need for Installation Called AC-WAN".
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