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9/7/17 | Peter L | Copied text from the v4 document, must check the v5 document for additional parts |
Introduction
Each Service Provider (SP) needs to support a rich set of advanced 5G wireless services, such as enhanced Mobile Broad Band (eMBB), massive Internet of Things (mIoT), and Ultra-Reliable, Low-latency Communications (URLLC ), for mission critical communications.
These services have very different requirements on latency, reliability, availability, mobility, and bandwidth. Deploying multiple separate networks to support these varying requirements is not practical. End to End vertical network slicing as defined by 3GPP provides specifications for efficient creation of multiple logical networks[PL1] sharing a common network infrastructure while meeting the specified service levels for each of the services. ONAP must support the complete lifecycle management of such network slicing.
Automated Configuration: Automated configuration of a slice during the instantiation, configuration, and activation phases, a newly created set of identifying parameters automatically configured
Automated reconfiguration. Automated reconfiguration happens during run-time e.g. an active slice can be reconfigured automatically because of a change in the service requirements or service conditions.
Here are some of the network elements participating in E2E Slicing:
- Distributed Radio Element
- Distributed BBU
- Centralized BBU and nrt-L2 function (CU-UP)
- Centralized Radio Control Unit (CU-CP)
- Layer 3 Transport Elements
- NG S/P Gateway
- NG PCRF
- Etc.
Introduction
Each Service Provider (SP) needs to support a rich set of advanced 5G wireless services, such as enhanced Mobile Broad Band (eMBB), massive Internet of Things (mIoT), and Ultra-Reliable, Low-latency Communications (URLLC ), for mission critical communications.
These services have very different requirements on latency, reliability, availability, mobility, and bandwidth. Deploying multiple separate networks to support these varying requirements is not practical. End to End vertical network slicing as defined by 3GPP provides specifications for efficient creation of multiple logical networks[PL1] sharing a common network infrastructure while meeting the specified service levels for each of the services. ONAP must support the complete lifecycle management of such network slicing.
Automated Configuration: Automated configuration of a slice during the instantiation, configuration, and activation phases, a newly created set of identifying parameters automatically configured
Automated reconfiguration. Automated reconfiguration happens during run-time e.g. an active slice can be reconfigured automatically because of a change in the service requirements or service conditions.
Here are some of the network elements participating in E2E Slicing:
- Distributed Radio Element
- Distributed BBU
- Centralized BBU and nrt-L2 function (CU-UP)
- Centralized Radio Control Unit (CU-CP)
- Layer 3 Transport Elements
- NG S/P Gateway
- NG PCRF
- Etc.
In order to enable both an e2e service view and re-usable services from the different segments/domains in the network, the design must be done in such a way as to support:
- Abstraction of the services offered by the different domains/segments
- Ability to tie the services offered by the different domains/segments into an e2e service.
- Support the network to provide isolation between the slices (to the extent that is reasonable according to the networks capabilities).
Goal
A request from the order handling system is received by ONAP. ONAP instantiates the slice without any manual operator interaction. ONAP start actively monitoring the slice.
Use Case 1: Design slice template
Use Case 2: Instantiate slice automatic trigger by request from BSS system
Use Case 3: Manage the slice SLA/SLO
The ONAP Design Studio (SDC) must support the following capabilities
- Define model/attributes for slice and its relationship to underlying VNF/Resources
- Design parameters needed for use by ONAP Optimization Framework (HAS) for decomposition and placement of resources needed for the slice
Design recipes/models for instantiating slices, modifying / expanding / shrinking slices, etc.
Design recipes/models for instantiating dedicated resources (e.g. AR / VR server)
Question (Stephen Terrill): what constitutes a dedicated resource? I agree we need to do this, but how to treat e.g. transport tin this context.