- Professional video over IP
Professional video over IP systems use some existing standard
video codec to reduce the program material to abitstream (such as anMPEG-2 transport stream ), and then to use anInternet Protocol (IP) network to carry that bitstream encapsulated in a stream of IP packets. This is typically accomplished using some variant of the RTP protocol.Carrying professional
video over IP networks has special challenges compared to most non-time-critical IP traffic. Many of these problems are similar to those encountered invoice over IP , but to a much higher level of engineering requirements. In particular, there are very strictquality of service requirements which must be fulfilled for use in professional broadcast environments.Packet loss
Since even well-engineered IP networks tend to have a small residual
packet loss rate caused by low-probability statistical congestion events and amplification ofbit error s in the underlying hardware, most professional solutions use some kind offorward error correction to ensure that the encoded video stream can be reconstructed even if a few packets are lost. This is typically applied at the packet level, since the encapsulated video bitstream is typically only designed to tolerate low levels of bit or burst errors, rather than the loss of whole packets. Resending packets is not an option because of the sequential nature of the underlying video signal. For live video, a resent packet would arrive well after the arrival of the next frame of video.Network delay variation
Network delay variation can be kept to a minimum by using a high-speed network backbone, and ensuring that video traffic does not encounter excessive queue delays. This is typically done by either ensuring that the network is not too close to its full capacity, or that video traffic is prioritized using traffic engineering techniques (see below).
The remaining delay variation can be removed by buffering, at the expense of added time delay. If forward error correction is used, a small proportion of packets arriving after the deadline can be tolerated, since they can be dealt with by being discarded on receipt, and then treated in the same way as lost packets. Added time delay is particularly unwelcome in
PTZ cameras as it makes operator control difficult at values over 250ms.0Timing reconstruction
The other problem presented by latency variation is that it makes
synchronization more complex by making the recovery the underlying timing of the video signal far more difficult. This is typically solved bygenlock ing both ends of the system to externalstation sync signals, typically generated from sources such asGPS oratomic clock s, thus only requiring the extraction of coarse timing information at the receiving end in order to achieve high-quality video synchronization. The extraction of coarse timing data is typically done using aphase locked loop with a long time constant.Adequate bandwidth
Even with packet loss mitigation, video over IP will only work if the network is capable of carrying the content with some reasonable maximum packet loss rate. In practice, this means that video over IP will not work on overloaded networks. Since IP does not of itself offer any traffic guarantees, this must be applied at the network engineering level. One approach to this is the "quantity of service" approach which simply allocates sufficient bandwidth to video-carrying traffic that it will not congest under any possible load pattern. Other approaches include dynamic reduction in frame rate or resolution,
network admission control ,bandwidth reservation ,traffic shaping , andtraffic prioritization techniques, which require more complex network engineering, but will work when the simple approach of building a non-blocking network is not possible. See RSVP for one approach to IP network traffic engineering.The
Pro-MPEG Wide Area Network group has done much recent work on creating a draft standard for interoperable professional video over IP.Use by Security Industry
Within the security products industry, IP-based Closed Circuit Television (CCTV) is making gains on the analog market. Key components of IP-based CCTV remain consistent with analog technologies:
image capture , with a combination of IP-based cameras or analog cameras using IP-based encoders;image transmission ; Storage and Retrieval, which uses techologies such as RAID arrays andiSCSI for recorded and indexed video; andvideo management , which affords web browser-enabled management and control of IP-based CCTV systems.One key advantage of IP-based CCTV is the ability to use network infastructure, providing adequate bandwidth and availability of switching and routing, rather than coaxial cabling. However, running bandwidth-intensive surveillance video over corporate data networks is a point of organizational contention, depending on the potential impact on network performance.
A class of companies (including
Milestone Systems , videoNEXT, Verint and others) produce Video Management Software to help manage capture and storage of video content. Digital video also makes possible Video Content Analysis, which allows automatic detection and identification of various kinds of objects or motion. Companies in this market include VideoIQ, ObjectVideo, and Cernium. [ [http://www.csoonline.com/read/090107/fea_analytics.html Video Analytics] , CSO Magazine, September 2007.] [ [http://ipvideomarket.info/topics/VideoAnalytics IP Video Surveillance News and Reviews] , IP Video Market Info, May 2008.]Several manufacturers of CCTV equipment, such as
Dallmeier ,Axis Communications ,General Electric ,Bosch ,Pelco ,Siemens andSanyo are steadily integrating IP network technology into their product portfolios.Compare with
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Professional video over ATM
* DTMReferences
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