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Overview
In traditional real-time communication, voice sessions have a one-to-one relationship between signaling and media (S1:M1), either with or without transcoding. A traditional, integrated signaling and media network element (integrated SBC, or I-SBC) effectively meets the requirements of this type of session. I-SBCs often run on custom hardware and are scaled horizontally to provide a deployment its required scaling and capacity.
As services evolve to support multimedia sessions, the traffic becomes more dynamic. The next generation communication may have one session with no media (S1:M0), or one session with multiple media (S1:Mn) relationships, with or without transcoding. Due to this dynamic nature, effective handling of the next generation communication service Effective handling requires considering the following three planes independently:
Signaling plane: for more IM presence status
Media plane: for video, MSRP, multiple streams per session
Transcoding plane: for transcoding / transrating / transizing of audio or video
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The D-SBC architecture supported by SBC SWe breaks the main SBC functions into separate services and assigns them to separate clusters. A cluster consists of multiple discrete nodes supporting one main function, such as signaling or media, with all nodes providing the same service. A virtual environment supports multiple clusters simultaneously, each providing a specific SBC function:
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These clusters coordinate with each other and are linked by the S-SBC using the
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SBC Redundancy Groups
An SBC redundancy group (RG) consists of one or more SBC SWe node instances. All the instances in an RG must have homogeneous resource allocation, configuration and personality. All RGs in a cluster must be of the same SBC type (signaling SBC or media SBC), which dictates the cluster type such as a signaling cluster or a media cluster.
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Why Distribute the SBC?
The D-SBC architecture provides SBC applications the ability to distribute distributes functions throughout the network and to utilize network resources effectively.
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- Flexibility to Scale: In an I-SBC all the components use the same hardware to service incoming calls on the SBC instance. But, in a distributed SBC (D-SBC) each component scales can scale independently within its cluster depending on the call and traffic requirements.
Example: Signaling components can be scaled if the traffic requires high signaling such as presence without the media component. Similarly, traffic with high media requirements, like video calls, requires can be served by instantiating more instances in the media cluster. Traffic that needs high transcoding requires instantiating more instances in the transcoding cluster.
- Service Chaining: The SBC includes functions such as call control, routing and policy, signaling normalization, IP firewall and policy, and media transcoding (or trans-rating). Each component of the D-SBC logically provides one or more such functions instantiated in a cluster to support scaling based on the traffic requirement. The signaling component of the SBC chains one or more such functions per call without knowing the media cluster details.
- Investment protectionProtection: Reusing existing custom hardware for media interworking saves cost. Custom hardware can coexist with the software media components providing media inter-working services. Also, when required it is invoked as an external media server.
- High Resilience with Low Media Latency: Geographically separated media clusters can be deployed closer to the edge of the network. This results in switching media at the edge instead of backhauling to the core which . This reduces media latency and backhaul costs with increased quality of experience. The use of multiple media instances provides resiliency enabling selection of media service components from different sites.
Overview
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