Jump to content

Main menu Navigation ●Main page ●Contents ●Current events ●Random article ●About Wikipedia ●Contact us ●Donate Contribute ●Help ●Learn to edit ●Community portal ●Recent changes ●Upload file

●Create account ●Log in ●Create account ● Log in Pages for logged out editors learn more ●Contributions ●Talk

(Top) 1 Protocols 1.1 Layer-1 protocols 1.1.1 Open standards 1.1.2 Proprietary 1.2 Layer-2 protocols 1.2.1 Open standards 1.2.2 Proprietary 1.3 Layer-3 protocols 1.3.1 Open standards 1.3.2 Proprietary 2 Similar concepts 3 See also 4 References

Audio over Ethernet

Add links ●Article ●Talk ●Read ●Edit ●View history Tools Actions ●Read ●Edit ●View history General ●What links here ●Related changes ●Upload file ●Special pages ●Permanent link ●Page information ●Cite this page ●Get shortened URL ●Download QR code ●Wikidata item Print/export ●Download as PDF ●Printable version In other projects ●Wikimedia Commons Appearance From Wikipedia, the free encyclopedia

Inaudio and broadcast engineering, audio over Ethernet (AoE) is the use of an Ethernet-based network to distribute real-time digital audio. AoE replaces bulky snake cables or audio-specific installed low-voltage wiring with standard network structured cabling in a facility. AoE provides a reliable backbone for any audio application, such as for large-scale sound reinforcement in stadiums, airports and convention centers, multiple studiosorstages.

While AoE bears a resemblance to voice over IP (VoIP) and audio over IP (AoIP), AoE is intended for high-fidelity, low-latency professional audio. Because of the fidelity and latency constraints, AoE systems generally do not utilize audio data compression. AoE systems use a much higher bit rate (typically 1 Mbit/s per channel) and much lower latency (typically less than 10 milliseconds) than VoIP. AoE requires a high-performance network. Performance requirements may be met through use of a dedicated local area network (LAN) or virtual LAN (VLAN), overprovisioningorquality of service features.

Some AoE systems use proprietary protocols (at the lower OSI layers) which create Ethernet frames that are transmitted directly onto the Ethernet (layer 2) for efficiency and reduced overhead. The word clock may be provided by broadcast packets.

Protocols[edit]

There are several different and incompatible protocols for audio over Ethernet. Protocols can be broadly categorized into layer-1, layer-2 and layer-3 systems based on the layer in the OSI model where the protocol exists.

Layer-1 protocols[edit]

Layer-1 protocols use Ethernet wiring and signaling components but do not use the Ethernet frame structure. Layer-1 protocols often use their own media access control (MAC) rather than the one native to Ethernet, which generally creates compatibility issues and thus requires a dedicated network for the protocol.

Open standards[edit]

AES50 (SuperMAC) by Klark Teknik, a point-to-point interconnect for bidirectional digital audio and sync clock^[1]
MaGICbyGibson^[2]

Proprietary[edit]

HyperMAC, a gigabit Ethernet variant of SuperMAC^[3]
A-NetbyAviom^[4]
AudioRail^[5]
ULTRANET By Behringer^[6]

Layer-2 protocols[edit]

Layer-2 protocols encapsulate audio data in standard Ethernet packets. Most can make use of standard Ethernet hubs and switches though some require that the network (or at least a VLAN) be dedicated to the audio distribution application.

Open standards[edit]

AES51, a method of passing ATM services over Ethernet that allows AES3 audio to be carried in a similar way to AES47
Audio Video Bridging (AVB), when used with the IEEE 1722 AV Transport Protocol profile (which transports IEEE 1394/IEC 61883 (FireWire) over Ethernet frames, using IEEE 802.1AS for timing)

Proprietary[edit]

CobraNet
- RAVE by QSC Audio, an implementation of CobraNet^[7]
EtherSoundbyDigigram^[8]
- NetCIRA, a rebranded EtherSound by Fostex
REAC and RSS digital snake technology by Roland^[9]^[10]
SoundGridbyWaves Audio
dSNAKE by Allen & Heath

Layer-3 protocols[edit]

Layer-3 protocols encapsulate audio data in OSI model layer 3 (network layer) packets. By definition it does not limit the choice of protocol to be the most popular layer-3 protocol, the Internet Protocol (IP). In some implementations, the layer-3 audio data packets are further packaged inside OSI model layer-4 (transport layer) packets, most commonly User Datagram Protocol (UDP) or Real-time Transport Protocol (RTP). Use of UDP or RTP to carry audio data enables them to be distributed through standard computer routers, thus a large distribution audio network can be built economically using commercial off-the-shelf equipment.

Although IP packets can traverse the Internet, most layer-3 protocols cannot provide reliable transmission over the Internet due to the limited bandwidth, significant End-to-end delay and packet loss that can be encountered by data flow over the Internet. For similar reasons, transmission of layer-3 audio over wireless LAN are also not supported by most implementations.

Open standards[edit]

AES67^[11]
Audio Contribution over IP standardized by the European Broadcasting Union
Audio Video Bridging (AVB), when used with IEEE 1733 or AES67 (which uses standard RTP over UDP/IP, with extensions for linking IEEE 802.1AS Precision Time Protocol timing information to payload data)
NetJack, a network backend for the JACK Audio Connection Kit^[12]
Zita-njbridge, a set of clients for the JACK Audio Connection Kit
RAVENNA by ALC NetworX (uses PTPv2 timing)

Proprietary[edit]

Livewire by Axia Audio, a division of Telos Systems
Dante by Audinate (PTP version 1 timing)
Q-LANbyQSC Audio Products (PTP version 2 timing)^[13]
WheatNet-IP by Wheatstone Corporation^[14]

Similar concepts[edit]

High quality digital audio distribution was patented in 1988 by Tareq Hoque at the MIT Media Lab.^[15] The technology was licensed to several leading OEM audio and chip manufacturers that were further developed into commercial products.^{[citation needed]}

RockNet by Riedel Communications,^[16] uses Cat-5 cabling. Hydra2 by Calrec^[17] uses Cat-5e cabling or fiber through SFP transceivers.^[18]

MADI uses 75-ohm coaxial cable with BNC connectors or optical fibre to carry up to 64 channels of digital audio in a point-to-point connection. It is most similar in design to AES3, which can carry only two channels.

AES47 provides audio networking by passing AES3 audio transport over an ATM network using structured network cabling (both copper and fibre). This was used extensively by contractors supplying the BBC's wide area real-time audio connectivity around the UK.

Audio over IP differs in that it works at a higher layer, encapsulated within Internet Protocol. Some of these systems are usable on the Internet, but may not be as instantaneous, and are only as reliable as the network route — such as the path from a remote broadcast back to the main studio, or the studio/transmitter link (STL), the most critical part of the airchain. This is similar to VoIP, however AoIP is comparable to AoE for a small number of channels, which are usually also data-compressed. Reliability for permanent STL uses comes from the use of a virtual circuit, usually on a leased line such as T1/E1, or at minimum ISDNorDSL.

In broadcasting, and to some extent in studio and even live production, many manufacturers equip their own audio engines to be tied together. This may also be done with gigabit Ethernet and optical fibre rather than wire. This allows each studio to have its own engine, or for auxiliary studios to share an engine. By connecting them together, different sources can be shared among them.

AoE is not necessarily intended for wireless networks, thus the use of various 802.11 devices may or may not work with various (or any) AoE protocols.^[19]