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RRM Architectural Framework

RRM Architectural Framework. David Skellern Wireless Networking Business Unit Cisco Systems Inc skellern@cisco.com. Background. RRM architecture was discussed in recent teleconferences This submission Shows the 802.11 architectural framework in which RRM will reside

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RRM Architectural Framework

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  1. RRM Architectural Framework David Skellern Wireless Networking Business Unit Cisco Systems Inc skellern@cisco.com

  2. Background • RRM architecture was discussed in recent teleconferences • This submission • Shows the 802.11 architectural framework in which RRM will reside • Identifies some RRM models consistent with that framework

  3. A Proposed RRM Architecture M/C Application Measurement/Control Application (non-802.11) Control Data Outside of 802.11 RRM Standard Interfaces 802.11 RRM • Standardize format/contents of the data interface from RRM to upper layers • Define “pull” (polled) and “push” (event driven) interfaces • Upper layer entities (M/C Apps) communicate with each other via infrastructure and/or WLAN. • Peer-to-peer communication between RRM possible via RRM standard interfaces at least for AP’s. • Scope of Control, if any? MAC This is one model discussed in RRM teleconferences PHY BB Radio RF Channel

  4. 802.11 Station Architecture ISO/IEC 8802-11:1999(E) specifies the following STA architecture (this is Figure 11 of standard) Station Management Entity(SME) MAC SAP MAC sublayer MAC Layer Management Entity (MLME) MLME SAP PHY SAP PLME SAP PLCP sublayer PHY Layer Management Entity (PLME) PLME SAP PMD SAP PMD sublayer

  5. Location of RRM Extensions • RRM extensions will reside in one of the following entities: • MLME • PLME • MAC • PLCP • PMD • To see why this is the case, we consider text from ISO/IEC 8802-11:1999(E)

  6. Architectural constraint 5.1.1.4 Interaction with other IEEE 802 layers • IEEE 802.11 is required to appear to higher layers [logical link control (LLC)] as an IEEE 802 LAN. • This tells us that the mechanisms available to get to higher layers are via the MAC SAP or SME. • The MAC SAP provides data services (ie this is in the data path) and RRM extensions probably shouldn’t mess with this. • That leaves SME

  7. RRM Extension Options • RRM blue stars show the likely location of RRM extensions, though RRM pink stars are (remotely) possible. • RRM Applications are outside the 802.11 specs. SME RRM Applications (outside 802.11) MAC SAP MAC MLME RRM MLME SAP RRM PHY SAP PLME SAP PLCP PLME RRM PLME SAP RRM PMD SAP PMD RRM

  8. Station Service 5.3.1 Station service (SS) • The service provided by stations is known as the station service. The SS is present in every IEEE 802.11 station (including APs, as APs include station functionality). The SS is specified for use by MAC sublayer entities. All conformant stations provide SS. • The SS is as follows: a) Authentication b) Deauthentication c) Privacy d) MSDU delivery • TGh is adding e) DFS and f) TPC. We will add g) RRM

  9. MLME & PLME 10.1 Overview of management model • Both MAC and PHY layers conceptually include management entities, called MAC sublayer management and PHY layer management entities (MLME and PLME, respectively). • MLME & PLME provide the layer management service interfaces through which layer management functions may be invoked.

  10. SME 10.1 Overview of management model (cont.) • The exact functions of the SME are not specified in this standard, but in general this entity may be viewed as being responsible for such functions as the gathering of layer-dependent status from the various layer management entities, and similarly setting the value of layer-specific parameters. • SME would typically perform such functions on behalf of general system management entities and would implement standard management protocols.

  11. SAPs 10.1 Overview of management model (cont.) • Figure 11 depicts the relationship among management entities. • The various entities within this model interact in various ways. Certain of these interactions are defined explicitly within this standard, via a service access point (SAP) across which defined primitives are exchanged. • Other interactions are not defined explicitly within this standard, such as the interfaces between MAC and MLME and between PLCP and PLME, represented as double arrows within Figure 63. The specific manner in which these MAC and PHY management entities are integrated into the overall MAC and PHY layers is not specified within this standard.

  12. SAPs cont. 10.1 Overview of management model (cont.) • The management SAPs within this model are the following: — SME-MLME SAP — SME-PLME SAP — MLME-PLME SAP • The latter two SAPs support identical primitives, and in fact may be viewed as a single SAP (called the PLME SAP) that may be used either directly by MLME or by SME. In this fashion, the model reflects what is anticipated to be a common implementation approach in which PLME functions are controlled by the MLME (on behalf of SME). In particular, PHY implementations are not required to have separate interfaces defined other than their interfaces with the MAC and MLME.

  13. The TGh model • The 802.11 standard place MIBs in the MLME and PLME and specifies access from SME via the MLME SAP and PLME SAP using generic GET/SET primitives [see Figure 63 of ISO/IEC 8802-11:1999(E)] • TGh handles measurement and control using MLME primitives.

  14. SME SME Measurement Policy MeasurementPolicy Channel Switch Decision MREQUEST /MREPORT MREQUEST /MREPORT CHANNEL SWITCH MEASURE MLME MLME Channel Switch Timing Measurement Processing Measurement Frames Measurement Frames MAC Timing PLME TGh layer management model • Extract from 802.11h-D2.1.32, which addresses some measurement extensions for DFS and TPC. Figure 26 – Layer Management Model

  15. Conclusion • The 802.11 architecture recognizes certain constraints and mechanisms. • Development of 802.11 RRM extensions are likely to proceed most quickly and smoothly if existing layer models and mechanisms can be used to deliver the desired functionality.

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