Versions Compared

Key

  • This line was added.
  • This line was removed.
  • Formatting was changed.

Project Technical Lead: Tapio Tallgren  Ferenc Szekely .Elected 110/1712/1920.


Project Committers detail:

...

Only Committers for a project are eligible to vote for a project’s Project Technical Lead.


Please see Akraino Technical Community Document section 3.1.3 for more detailed information.


Participants updated 13 Oct, 2020!


Marvell

Committer

Committer

Company

Committer

Contact Info

 Committer BioCommitter Picture 

Self Nominate for PTL (Y/N)

Nokia

tapio.tallgren@nokia.com

Y

Tapio SärkkäNokiatapio.sarkka@nokia.com

N

Ind.

bob.monkman@gmail.com



N

Chencho Munoz 

smunoz@marvell.comGorka GarciaMarvellggarcia@marvell.comFerenc SzékelySUSEInd.ferenc.szekely@suseszekely@gmail.com

Y


Presentation:


View file
nameµMEC blueprint intro.pdf
height250

µMEC blueprint

Use Case:

Use Case Attributes

Description

Informational

Type

New


Industry Sector

Telco networks, especially network edge (Ultra Far)


Business driver

The uMEC will enable new functionalities and business models on the network edge. The benefits of running applications on the network edge are

  • Better latencies for end users

  • Less load on network since more data can be processed locally

  • Better security and privacy since sensitive data need not be transferred to a centralized location

All these new services support the business case for building new high-speed networks which in turn enable new things.


Business use cases

The uMEC has several deployment models that each support different business cases:

  1. Fixed installation as part of 5G NR base stations enables new services that leverage especially low latency, such as AR/VR

  2. As an extension of the previous, the “Smart City” deployments have additional functions such as weather stations, cameras, displays, or drone charging stations. The control software for these functions would run on the uMEC

  3. In an Industry 4.0 use case set, the uMEC is deployed as part of a 5G network and would provide a platform for running services for the factory floor

  4. In a train, the uMEC could collect and store surveillance camera data for later uploading


Business Cost - Initial Build

The cost of the uMEC hardware and software should be tens of dollars. This does not include power supplies, casing, modems, and other external components. Installation and cabling will be the highest cost item.


Business Cost - Operational

The uMEC device software should be fully manageable remotely with automation. The power consumption for uMEC without peripherals supports Power over Ethernet types 1, 2 and 3 which are covered as different PODs


Operational need

The uMEC must be fully operable remotely with automation. It should be able to recover from network failures by reverting to a known good network configuration.


Security need

The uMEC device will be used outdoors in untrusted environments and it handles potentially privacy-sensitive data such as live video. Therefore, the device needs to support trusted boot, trusted key storage, and encrypted communication. The device will also have application from different parties and must provide isolation between them.

The Linux application security, either SELinux or AppArmor, must be used.


Regulations

The uMEC should meet all the industry regulations of   data privacy, security, and environmental conditions.


Other restrictions

Depending on the uMEC deployment scenarios, there can be other requirements.


Additional details

There are three blueprint species related to this blueprint which correspond to the different power classes of the uMEC.



Blueprint species:

Use Case Attributes

Description

Informational

Type

New


Blueprint Family - Proposed Name

uMEC


Use Case

Small deployment of uMEC


Blueprint proposed Name

uMEC Type 1


Initial POD Cost (capex)

  • The defining factor is power consumption < 15 W

  • The cost of the POD will depend on peripherals and case


Scale & Type

  • A single-board computer that meets the power limit


Applications

uMEC applications


Power and memory restrictions

  • Less than 7 W for the SoC

  • Less than 512MB of memory


Infrastructure orchestration

ONAP Edge Cloud orchestration


SDN

SR-IOV & OVS-DPDK or VPP-DPDK


Workload Type

  • Containers

  • MEC compatible


Additional Details

Submitter to provide additional use case details



Blueprint species:

Use Case Attributes

Description

Informational

Type

New


Blueprint Family - Proposed Name

uMEC


Use Case

Medium deployment of uMEC


Blueprint proposed Name

uMEC Type 2


Initial POD Cost (capex)

  • The defining factor is power consumption < 30 W

  • The cost of the POD will depend on peripherals and case


Scale & Type

  • A single-board computer that meets the power limit


Applications

uMEC applicatios


Power and memory restrictions

  • Less than 15 W for the SoC

  • Less than 4GB of memory


Infrastructure orchestration

ONAP Edge Cloud orchestration


SDN

SR-IOV & OVS-DPDK or VPP-DPDK


Workload Type

  • Containers

  • MEC compatible


Additional Details

Submitter to provide additional use case details


Blueprint species:

Use Case Attributes

Description

Informational

Type

New


Blueprint Family - Proposed Name

uMEC


Use Case

Large deployment of uMEC


Blueprint proposed Name

uMEC Type 3


Initial POD Cost (capex)

  • The defining factor is power consumption < 60 W

  • The cost of the POD will depend on peripherals and case


Scale & Type

  • A single-board computer that meets the power limit


Applications

uMEC applications


Power and memory restrictions

  • Less than 30 W for the SoC

  • Over 4GB of memory


Infrastructure orchestration

ONAP Edge Cloud orchestration


SDN

SR-IOV & OVS-DPDK or VPP-DPDK


Workload Type

  • Containers

  • MEC compatible


Additional Details

Submitter to provide additional use case details


...