HomePlug

HomePlug is the family name for various power line communications specifications that support networking over existing home electrical wiring. Several specifications exist under the HomePlug moniker, with each offering unique performance capabilities and coexistence or compatibility with other HomePlug specifications.

Some HomePlug specifications target broadband applications such as in-home distribution of low data rate IPTV, gaming, and Internet content, while others focus on low-power, low throughput, and extended operating temperatures for applications such as smart power meters and in-home communications between electric systems and appliances. All of the HomePlug specifications were developed by the HomePlug Powerline Alliance, which also owns the HomePlug trademark.

Home networking standards
Common name IEEE standard
HomePlug IEEE 1901
Wi-Fi 802.11a
802.11b
802.11g
802.11n
Common name ITU-T recommendation
HomePNA 2.0 G.9951–3
HomePNA 3.0 G.9954
HomePNA 3.1 G.9954
G.hn/HomeGrid G.9960–1
G.hn-mimo G.9963
G.hnta G.9970
G.cx G.9972

Contents

History

From its inception, the HomePlug Alliance has delivered technology that enables products to use existing home electrical wiring to communicate with each other and connect to the Internet. One of the greatest technical challenges was finding a way to reduce sensitivity to the electrical noise that is inevitably present on power lines. Whenever an appliance is turned on or off, it creates electrical noise that can interfere with data transfer through the wiring. Noise sensitivity was problematic in early powerline technology, though later versions have solved this problem. Also, earlier powerline technology could not reliably pass the communication signal through different electrical phases. HomePlug has solved this issue by increasing the communication carrier frequencies so that the signal will be conveyed by the neutral conductor, which is common to all phases.

The first HomePlug specification, HomePlug 1.0, was released in June 2001. The HomePlug AV specification, which was released in 2005, increased physical layer (PHY) peak data rates from 14 to 200 Mbit/s. The HomePlug Green PHY specification was released in June 2010 and targets Smart Energy and Smart Grid applications as an interoperable "sibling" to HomePlug AV with lower cost, lower power consumption and decreased throughput. (HomePlug Command and Control low frequency specification was released in 2007, but later deprecated and replaced by HomePlug Green PHY.)[1][2]

On September 30, 2010, the IEEE’s 1901 Broadband Powerline Standard was approved and HomePlug AV, as baseline technology for the FFT-OFDM PHY within the standard, is now ratified and validated as an international standard. The HomePlug Powerline Alliance is a certifying body for IEEE 1901 products. The three major specifications published by HomePlug (HomePlug AV, HomePlug Green PHY and the forthcoming HomePlug AV2) are interoperable and compliant. As of November 2011, there are 4 chip vendors that are shipping interoperable HomePlug AV chipsets with IEEE 1901 support (Broadcom, Qualcomm Atheros, Sigma Designs, and SPiDCOM) and millions of units are shipped each month throughout the world. Many HomePlug AV products are shipping from key vendors such as ATRIE Technology P Limited,Cisco, devolo, ZyXEL, D-Link, Logitech, NETGEAR and Western Digital. Major IPTV service providers such as France Telecom, British Telecom, and Deutsche Telekom are also shipping large volumes of HomePlug products. In November 2011, the HomePlug Green PHY specification was adopted by 7 key American and German automobile companies, Ford, General Motors, Audi, BMW, Daimler, Porche, and Volkswagen, as a connectivity standard for Plug-In Electrical Vehicle.[3]

Newer versions of HomePlug support the use of Ethernet in bus topology. This is achieved by means of OFDM modulation that enables several distinct data carriers to coexist in the same wire. Also, HomePlug's OFDM technology can turn off (mask) any sub-carriers that overlap previously allocated radio spectrum in a given geographic region, thus preventing interference. In North America, for instance, HomePlug AV only uses 917 of 1155 sub-carriers.[4]

Usage

The major benefit of powerline networking is that users can easily establish a network using a home's existing electrical wiring as the communication medium. There is no need to drill holes in walls or ceiling to route new wiring and, as a result, installation is quick, easy and relatively inexpensive. In most homes throughout most geographies, power outlets are found in most rooms. For AC-powered devices that must already be near an outlet, powerline networking is a natural and easily accomplished networking method.

The most widely deployed powerline networking devices are "adapters", which are standalone modules that plug into wall outlets (or power strips or extension cords) and provide one or more Ethernet ports. In a simple home network, the Internet gateway router connects via Ethernet cable to a powerline adapter, which in turn plugs into a nearby power outlet. A second adapter, plugged into any other outlet in the home, could connect via Ethernet cable to any Ethernet-enabled device (e.g., computer, printer, IP phone, gaming station). Data communications between the router and Ethernet devices would be conveyed over existing home electrical wiring. More complex networks with multiple adapters can be implemented by plugging in additional adapters as needed. A powerline adapter may also be plugged into a hub or switch so that it supports multiple Ethernet devices residing in a common room.

Increasingly, the functionality found in standalone adapters is being built into end devices such as power control centers, digital media adapters, and Internet security cameras. It is anticipated that powerline networking functionality will be embedded in TVs, set-top boxes, DVRs, and other consumer electronics, especially with the emergence of global powerline networking standards such as the IEEE 1901 standard, ratified in September 2010.[5]

Versions

HomePlug 1.0

HomePlug 1.0 was the first HomePlug specification. It provides a peak PHY-rate of 14 Mbit/s. It was first introduced in June, 2001 and has since been replaced by HomePlug AV. On May 28, 2008 Telecommunications Industry Association (TIA) incorporated HomePlug 1.0 powerline technology into the newly published TIA-1113 international standard. TIA-1113 defines modem operations on user-premises electrical wiring. The new standard is the world's first multi-megabit powerline communications standard approved by an American National Standards Institute (ANSI)-accredited organization.

There are also HomePlug 1.0 with Turbo adapters that still may be found on the market. These comply with the HomePlug 1.0 specification but feature a faster, proprietary mode that increases the peak PHY-rate to 85 Mbit/s.

HomePlug AV

The HomePlug AV specification, which was introduced in August 2005, provides sufficient bandwidth for applications such as HDTV and VoIP. HomePlug AV offers a peak data rate of 200 Mbs at the physical layer, and about 80 Mbs at the MAC layer. HomePlug AV devices are required to coexist, and optionally to interoperate, with HomePlug 1.0 devices.

Utilizing adaptive modulation on up to 1155 OFDM sub-carriers, turbo convolution codes for error correction, two-level MAC framing with ARQ,[6] and other techniques, HomePlug AV can achieve near the theoretical maximum bandwidth across a given transmission path.[4] For security reasons, the specification includes key distribution techniques and the use of 128 bit AES encryption. Furthermore, the specification's adaptive techniques present inherent obstacles to eavesdropping and cyber attacks.[7][8]

HomePlug AV2

The HomePlugAV2 project is currently under development and is the next generation for the HomePlug line. Current specification states 500 Mbit/s on powerline and 700 Mbit/s on coax wiring. That translates to 350 Mbps on MAC interface in case of powerline wiring used. HomePlug AV2 is fully interoperable with HomePlug AV and will be brought into the IEEE 1901 standard once the specification is completed. HomePlug AV2 offers Gigabit speed at the physical layer and 500Mbs at the MAC layer. The AV2 spec is expected to be completed in mid 2011, products started shipping in late 2011. Completion of the HomePlug AV2 Marketing Requirements Document was announced in November 2009.[9]

HomePlug GreenPhy

HomePlug Green PHY is a new specification that is a subset of HomePlug AV and is specifically designed for the requirements of the smart grid market. It has peak rates of 10 Mbit/s and is designed to go into smart meters and smaller appliances such as HVAC/thermostats,, home appliances and plug-in electric hybrid vehicles.[10] so that data can be shared over a Home Area Network (HAN) and back to the utility. For these applications, there’s not a great need for high capacity broadband; the most important requirements are for lower power, robust, reliable coverage throughout the home, smaller size and less costly Bill of Materials. GreenPHY uses up to 75% less energy than AV.[10] The HomePlug Powerline Alliance worked closely with utilities and meter manufacturers to develop this 690-page specification (sold on the HomePlug website)[11]. HomePlug Green PHY-based products will be fully interoperable with products based on HomePlug AV, IEEE 1901 or the upcoming HomePlug AV2 specification.

HomePlug Access BPL

Access Broadband Power Line (BPL) refers to a to-the-home broadband access technology. The HomePlug Alliance formed the HomePlug Access BPL Working Group, whose first charter was to develop the Market Requirements Document (MRD) for a HomePlug Access BPL specification. The Alliance made an open invitation to the BPL industry to participate in the development of or provide input for consideration in the MRD. After several months of collaboration between utilities, ISPs and other BPL industry groups, the MRD was completed in June 2005. HomePlug's work on the Access BPL was subsequently contributed and merged into the IEEE 1901 standard.[1]

Security

Since signals may travel outside the user's residence or business and be eavesdropped on, HomePlug includes the ability to set an encryption password. The HomePlug specification requires that all devices are set to a default out-of-box password — although a common one. Users should change this password. On many new powerline adapters that come as a boxed pair, a unique security key has already been established and the user does not need to change the password, unless using these with existing powerline adapters, or adding new adapters. Some manufacturers supply adapters with security key buttons on them, allowing users to easily set unique security keys by plugging each unit in one at a time and pressing the button on the front (see more detailed instructions that come with the units).

To simplify the process of configuring passwords on a HomePlug network, each device has a built-in master password, chosen at random by the manufacturer and hard-wired into the device, which is used only for setting the encryption passwords. A printed label on the device lists its master password.

The data at either end (Ethernet side) of the HomePlug link is not encrypted (unless an encrypted higher-layer protocol such as TLS or IPsec is being used), only the link between HomePlug devices is encrypted. The HomePlug AV standard uses 128-bit AES, while the older versions use the less secure DES.

Since HomePlug devices typically function as transparent network bridges, computers running any operating system can use them for network access. However, some manufacturers only supply the password-setup software in a Microsoft Windows version; in other words, enabling encryption requires a computer running Windows [1]. Once the encryption password has been configured, Windows will no longer be needed, so in the case of a network where all computers run other systems a borrowed laptop could be used for initial setup purposes.

Interoperability

Products are tested for interoperability and certified based on the HomePlug specification and the IEEE 1901 powerline standard. Devices marked with the HomePlug certification mark will interoperate with each other, but not with devices that employ other powerline technologies such as UPA (silicon vendor Marvell) or HD-PLC (silicon vendor Panasonic), which are found primarily in Japan.

HomePlug 1.0 devices do not interoperate with HomePlug AV devices. Although it is technically possible to achieve backward compatibility, this is not economically feasible because of the high cost of circuitry that would have to support different Forward error correction (FEC) techniques and feature sets.[12] HomePlug AV, GP, and AV2 are fully interoperable, and will also interoperate with the IEEE 1901 devices.

Similarly, HomePlug (1.0, GP, AV, AV2) devices will not interoperate with products based on the G.hn standard (for power lines, phone lines and coaxial cables) developed by ITU-T because it was deemed prohibitively expensive to implement both HomePlug's turbo coding forward error correction and the low density parity check (LDPC) proposed for G.hn.[13]

See also

References

  1. ^ a b “Frequently Asked Questions,” HomePlug Powerline Alliance, http://www.homeplug.org/about/faqs/ (accessed June 22, 2010).
  2. ^ HomePlug Powerline Alliance Inc. HomePlug AV White Paper. Program documentation. HomePlug. Web. http://www.homeplug.org/tech/whitepapers/HPAV-White-Paper_050818.pdf.
  3. ^ Seven Auto Manufacturers Collaborate on Harmonized Electric Vehicle Fast Charging Solution, http://media.ford.com/article_display.cfm?article_id=35430
  4. ^ a b Katar, S.; Krishnam, M.; Newman, R.; and Latchman, H. (August 2006). "Harnessing the potential of powerline communications using the HomePlug AV Standard". RF Design: 16–26. http://rfdesign.com/mag/608RFDF1.pdf. Retrieved 2008-01-06. 
  5. ^ "IEEE P1901 Working Group." IEEE Standards Association. Web. 30 June 2010. <http://grouper.ieee.org/groups/1901/>.
  6. ^ Katar, Srinivas; Yonge, Larry; Newman, Richard; and Haniph Latchman. Efficient Framing and ARQ for High-Speed PLC systems. http://www.cise.ufl.edu/~nemo/papers/ISPLC2005-framing.pdf. Retrieved 2008-01-07. 
  7. ^ Newman, Richard; Yonge, Larry; Gavette, Sherman; and Anderson, Ross. HomePlug AV Security Mechanisms. http://www.cise.ufl.edu/~nemo/papers/ISPLC2007_AV_Security.pdf. Retrieved 2008-01-06. 
  8. ^ Newman, Richard; Gavette, Sherman; Yonge, Larry; and Anderson, Ross. Protecting Domestic Power-line Communications. http://cups.cs.cmu.edu/soups/2006/proceedings/p122_newman.pdf. Retrieved 2008-01-06. 
  9. ^ HomePlug Alliance Press Kit
  10. ^ a b HomePlug GreenPHY Overview
  11. ^ HomePlug GreenPHY Specs
  12. ^ EDN, Voices: Intellon’s Mark Hazen on the HomePlug AV powerline-networking alternative
  13. ^ Debate breaks out over home net standards

External links