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Signaled Provisioning of the IP Network Resources Between the Media Gateways in Mobile Networks

Signaled Provisioning of the IP Network Resources Between the Media Gateways in Mobile Networks. Leena Siivola 10.12.2004. Problem Description.

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Signaled Provisioning of the IP Network Resources Between the Media Gateways in Mobile Networks

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  1. Signaled Provisioning of the IP Network Resources Between the Media Gateways in Mobile Networks Leena Siivola 10.12.2004

  2. Problem Description • For circuit switched (CS) traffic the delay and the jitter requirements are strict. That is why the amount of voice calls must be controlled not only from radio networks (RN) side but also from IP multiservice backbone’s point of view. • The backbone edge nodes, i.e. the Media Gateway, must have ways to control the amount of traffic injected to the network • This must make it possible to give some QoS guarantees for the voice calls • The network resources will be used more efficiently

  3. Objectives and Scope • The objective of this Thesis is to • describe the current Call Admission Control (CAC) mechanisms in the 3G IP multiservice backbone • to evaluate the suitability of the NSIS signaling protocol framework for the CAC solution.

  4. The functional architecture of the 3G network

  5. The Call Admission Control Mechanism

  6. Provisioning Methods in the IP Multiservice Backbone . . MBAC = Measurement Based Admission Control MPLS = Multiprotocol Label Switching

  7. Static Provisioning Methods in the Media Gateway

  8. Signaled Provisioning • Signaled provisioning is a tempting approach for CAC because it can give ’hard’ QoS guarantees for traffic flows and it can increase the network utilization. • Many QoS signaling protocols exist: • Tenet & ST-II • RSVP with its extensions • YESSIR (Yet another Sender Session Internet Reservations) • Boomerang • RSVP has been the most famous one • Has said to bee too complex and suffering scalability problems • -> also other simulation results exist! • The work with the NSIS signaling protocol framework was started, because there was a need for a more lightweight signaling protocol.

  9. The NSIS Signaling Framework NSLP = NSIS Signaling Application Level NTLP = NSIS Transport Level

  10. The NSIS Signaling for Quality of Service (QoS) • The NSIS QoS signaling framework is based on a two layered architecture: • NTLP (NSIS Transport Layer Protocol) • NSLP (NSIS Signaling Layer Protocol) • QoS Model that is being signalled (e.g. Intserv or RMD) • NSIS without QoS Model is only a framework with many optional features.

  11. Comparison Between the NSIS QoS Signaling and RSVP • NSIS can be both sender- and receiver-oriented • NSIS does not support multicast • Mobility support • Bi-directional reservation possible

  12. NSIS(RMD) Architecture • It is not possible to evaluate the NSIS signaling without taking the QoS model into account. The NSIS framework consists of several optional features that can be taken into use. • Resource Management in Diffserv (RMD) implemented with NSIS

  13. Resv(QSpec) Resv(E2E ignore, QSpec) Resv(LQSpec) Resv(LQSpec) Resv(LQSpec) Resv(QSpec) Response Response Response Successful Reservation Edge Receiver Initiator Interior Interior Edge

  14. One Possible Implementation of NSIS to the 3G

  15. Evaluation + NSIS framework is flexible and modular -> it can be used in different ways + There are several optional features that can be taken into use • The resulting QoS protocol is even more complex than RSVP -> what do we gain with the abstraction level?

  16. Evaluation: The NSIS(RMD) Implementation as an Example • Evaluation criteriors: • Per-hop Performance Metrics • Signaling message processing delay • Per-Reservation Performance Metrics • Signaling Bandwidth Overhead • Abortive Provisioning • Blocking Probability • Reservation Setup Time • Applicability of the NSIS(RMD) Signaling to the IP Multiservice Backbone SCALABILITY AND ROBUSTNESS

  17. Per-hop Performance Metrics: Signaling message processing delay • ts = signaling message processing delay • tS0 = the base parameter • fR = a component dependent of the session load (LR) • fT = a component dependent of the session (LR) and the signaling load (LT) Signaling message processing delay In the edge routers: proportional to the number of sessions In the core routers: a constant

  18. Per-Reservation Performance Metrics:Signaling Bandwidth Overhead

  19. Per-Reservation Performance Metrics:Abortive Provisioning

  20. Per-Reservation Performance Metrics:Blocking Probability

  21. Per-Reservation Performance Metrics:Reservation Setup Time

  22. Conclusions • The Intserv type (RSVP-like) per-flow end-to-end signaling brings nothing new when comparing to RSVP • The message processing times have been estimated to be approximately same (1 ms) • In the IP multiservice backbones some Intserv over DiffServ approach, such as RMD, could be the solution • The message processing time in the core routers is approximately 5 microsec. • The system bottleneck is the signaling load on the edge routers • There’s only approximately 0,9 msec time to process one reservation message in the edge router • The link utilization is the same than with per-flow reservations • The response time is lower because of the sender-oriented approach

  23. Conclusions (continued) • NSIS in itself has failed to meet its design criteria: • It is not simple and ligthweight -> It is too modular • There is a serious risk that NSIS will become only one signaling protocol amoung others • Too much politics involved in the protocol design work • The router vendors are not actively participating the work -> the possibility to implement NSIS in networks is dependent of the router implementation

  24. Future research • Router vendors’ interests • NSIS(RMD) / RSVP(RMD) with MPLS-tunnels • DCCP -> the adjustment of voice codecs with network congestion, ECN marking

  25. THANK YOU! • Any questions?

  26. ADDITIONAL INFORMATION

  27. Dynamic Provisioning Methods in the Media Gateway • Measurement Based Admission Control (MBAC) • + CAC is fast • + no extra signaling load • + implementation costs low • cannot guarantee anything • the measurement result arrives always too late • Probing • + no actual traffic will be lost • additional traffic -> the probe packets can overload the network • Setup delay • the routers do not support ? • Bandwidth Broker (BB) • + high utilization • - complex new node in the network

  28. RSVP vs. RMD Performance Source: A. Bader et al.:Presentation in the 11th International Telecommunications Network Strategy and Planning Symposium (Networks2004)

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