Networking is the ability to makes the information transformed from one computer to another with the help of the data cables or through a wireless means. The article describes the implementation and the connections management of the Ethernet Audio which facilitates the connection, control of the multimedia system. AES-64 can be defined as a standard used for the discovery, enumeration, connection management and control of multimedia network devices. Network audio system is very vital in the life of a consumer since it makes the way of communication a bit efficient and easy to implement when it comes to that initiative.
Normally, the Ethernet AVB device enforced by an audio video bridging endpoint design that enables the time-synchronization and finally enables low latency streaming services via address design can at the same time transmit and receive multicore audio streams onto an Ethernet AVB network, function that exist between audio stream channels and a variety of audio hardware interfaces.
The importance of the system is like the case of the redundancy of the data and the increased efficiency of use and also a wide scope of network resources from single console to and up to a large variety. This type of the network normally differs from the normal LAN computer network in that there is a central server and the relationship between the two concepts of the network is the peer-to-peer and the design is placed in that the data possible to be removed and be added to the system.
One major reason why Audio networks is mostly needed to be implemented is that it allows convenient insure and supervising of power amps and digital signal working, and speedy shift of audio and firmware files between different components of the system.
This standard for networked statement, control, and connection management which are vital for integrated media which is an IP-grounded peer-to-peer network communications protocol, by which any communication device on the network may start or assume the control 0f the system, supervising of the system operation, and the connection management controls. The commands AES64 protocol was developed with three main concepts as follows:
- structuring,
- joining,
- indexing.
Every argument forms part of the structure, and control is potential at any of the degrees of the body structure of the multimedia system, which allows for the control over a group of arguments. It is believed that each and every argument has power related with it and, once it is detected, this power provides relatively low level of the bandwidth which is alternative to the parameter control.
These systems normally have some technical challenges despite its merits involved in the system. The revision which is based on the MAC Ethernet is always demanding to achieve and requires adequate knowledge to implement. The implementation of this system too requires adequate knowledge to come up with and makes the correct provision as per the requirement of the client.
Despite the challenges, like the case of calculating the number of variables available within the multimedia system, the system has varied importance to the users from different dimension. The effect way of controlling and monitoring the audio network system will enable efficient transmission of signals within the system and with the help of this it can help in the operation of the traditional system.
This type of network systems normally promises various gains and reductions for professional and consumer-level audio engineering. Nevertheless, until lately the most widely available network audio systems have been established on proprietorship technology mode of the system.
The audio network normally has some complexity in its structure and this makes it a bit complex to use and implement. It has some of the multiple components of the functional components like the case of the output and the input devices. These two components has some of their inbuilt components again with their own functional units. They enable the functionality of the two components in turn.
The AES-64 has several motivating factors which enabled its functionality as follows:
- The aim to come up with a way of standard with some suitable standard controls for the audio devices.
- It enhances the use of the concurrent processing of the task within the system.
- It gives the ability of the processes to be determined whether they are multi-threaded or not for the best implementation of the AES-64 system.
Conclusion
In conclusion, audio devices normally have some advantages as compared to the other type of the system and they make the transmission of the information more efficient. This facilitates also the ability to make the communication more efficient and all the controls are within the components in use.
For the case of the audio networking device, the system is that it creates simplicity of the system and enables the peer-to-peer communication between the system components. The implementation of the system adapts the concept parameter value functions and they refer to the design of the system. It is shown that it is not possible to specify values of the functions via the function pointers. The concept of the audio networking device implementation brings about the ability of a good quality of service over various technologies. This enables the priority in terms of bandwidth provision and also ensures that provision of some priorities does not hinder the performance of components.
Work cited
Audio Engineering Society. AES-64 standard for audio applications of networks-command, control and connection management for integrated media, 2012.
Networking in Audio Engineering, Retrieved from:
http://technet.microsoft.com/en-us/library/jj688118.aspx on 5th December, 2013
Networking in Audio Engineering, Retrieved from:
http://www.aes.org/standards/about/ on 5th December,2013
Networking in Audio Engineering, Retrieved from:
http://www.audionetwork.com/production-music/self-important_17208.aspx on 5th December,2013.
Eargle, J., & Foreman, C. (2002). Audio engineering for sound reinforcement. Milwaukee, Wis: Hal Leonard Corp.
Handa, A. (2009). System engineering for IMS networks. Amsterdam: Newnes/Elsevier.
