Mobile IP: Quality-of-Service

1. Mobile IP: Quality-of-Service Reference:“Domain based approach for QoS provisioning in mobile IP”; Ki-Il Kim; Sang-Ha Kim; Proc. IEEE Global Telecommunications Conference (GLOBECOM), 2001; pp. 2230 –2234. (MobileIPQoS-4.pdf)

2. ISA Concept • Integrated Services Architecture • Intended to provide QoS transport support over IP-based internets, RFC 1633 • Two broad categories of traffic on internet • Elastic Traffic • File transfer (FTP) , Email (SMTP), Remote Logon (TELNET), Network management (SNMP), Web access (HTTP) • Inelastic Traffic • Real-time traffic • Throughput, Delay, Jitter, Packet loss Background

3. ISA Approach • Traditional (IP) Router mechanisms • Routing algorithm • Packet discard • ISA Enhancements: the concept of flow • Admission control: RSVP • Routing algorithm: QoS-based OSPF • Queuing discipline: For differing requirements of different flow • Discard policy: for managing congestion and meeting QoS guarantees Background

4. ISA Components ISA Implemented in Router Background

5. 2-Level ISA Services • 1. General categories of service • Guaranteed • Assured capacity/data rate • Specified upper bound on the queuing delay • No queuing loss • Controlled Load • Best effort • 2. Service for a particular flow • Traffic specification (TSpec): Token Bucket • QoS Background

6. Token Bucket Scheme Background

7. Queuing Discipline No priority; Larger mean delay Greedy TCP connections crowd out altruistic ones Weighted Fair Queuing (WFQ) Background

8. Resource ReSerVationProtocol • Characteristics • Unicast and Multicast • Simplex • Receiver-initiated reservation • Maintaining soft state in the internet • Providing different reservation styles • Transparent operation through non-RSVP routers • Support for IPv4 and IPv6 • Type-of-Service in IPv4 • Flow Label in IPv6 Background

9. RSVP Design Characteristics • Receiver-initiated reservation • Sender • Provide the routers with the traffic characteristics of the transmission (data rate, variability) • Receiver • Specify the desired QoS • Router • Aggregate multicast resource reservations for the shared path segments along the distribution tree • Soft State Background

10. RSVP Data Flows • Flow descriptor • flowspec: desired QoS • filterspec: defines the set of packets for the reservation Treatment of packets of one session at one router Background

11. RSVP Protocol Mechanisms • Two message types • Resv, Path Background

12. RSVP Operation Background

13. Differentiated Services (DS) • Goal (RFC 2475) • Provide a simple, easy-to-implement, low-overhead tool to support a range of network services (comparing with ISA) • Key characteristics • IP packets are labeled for differing QoS treatment using the existing IPv4Type-of-Service octet or IPv6Traffic Class octet. Thus, no change is required to IP Background

14. Differentiated Service (cont) • A service level agreement (SLA) is established between the service provider (internet domain) and the customer prior to the use of DS • All traffic with the same DS octet is treated the same by the network service • Routers deal with each packet individually and do not have to save state information on packet flows Background

15. DS Octet • Packets are labeled for service handling by means of the DS octet • Placed in the Type of Service field of an IPv4 header, or the Traffic Class field of the IPv6 header • RFC 2474: The leftmost 6 bits form a DS codepoint • The DS codepoint is the DS label used to classify packets for differentiated services Background

16. DS Codepoint (6 bits) • xxxxx0 • Reserved for assignment as standards • 000000: default packet class, i.e. best-effort • xxx000: reserved to provide backward compatibility with the IPv4 precedence service • xxxx11 • Reserved for experimental or local use • xxxx01 • Reserved for experimental or local use, but may be allocated for future standards action as needed Background

17. DS Domain • Within a domain, the interpretation of DS codepoints is uniform, consistent service is provided Background

18. Routers in DS Domain • Interior nodes (per-hop behavior: PHB) • Queuing discipline to give preferential treatment depending on codepoint value • Packet-dropping rules to dictate which packets should be dropped first in the event of buffer saturation • Boundary nodes • PHB mechanisms • Traffic conditioning functions • metering, marking, shaping, dropping Background

19. DS Traffic Conditioner Background

20. DS Traffic Conditioner (cont) • Classifier • Separates submitted packets into different classes • Based on the DS codepoint or on multiple fields within the packet header • Meter • Measures submitted traffic for conformance to a profile • Determines whether a given packet stream class is within or exceeds the service level guaranteed for that class Background

21. DS Traffic Conditioner (cont) • Marker • Polices traffic by re-marking packets with a different codepoint as needed • Shaper • Polices traffic by delaying packets as necessary so that the packet stream in a given class does not exceed the traffic rate specified in the profile for that class • Dropper • Drops packets when the rate of packets of a given class exceeds that specified in the profile for that class Background

22. ISA (IntServ) vs. DS (DiffServ) Background

23. Introduction • Tunneling mechanism in MIP causes serious problems in adapting to the Internet QoS architecture • Integrated Service and Differentiated Service • IntServ and DiffServ Identify the end-to-end service session by address field of IP header and port field of transport layer header • Different sessions over tunneling section must be defined • Mapping the new section over IP tunnel to the end-to-end service session must be defined

24. Related Work • 1. New RSVP session over IP tunneling section is created and is mapped to the end-to-end RSVP session using IntServ semantics • Scalability problem remains • As the number of mobile host is increased, the session information per flow must be maintained • Implementation difficulties on existing network

25. Related Work (cont) • 2. The edge router located on the tunneling entry point remarks the DSCP in the IP header to reflect settled service level agreement • DSCP: Differentiated Service Code Point • Only qualitative QoS can be guaranteed, quantitative QoS may not be guaranteed sometimes • Implementation difficulties on existing network

26. Related Work (cont) • 3. The entire RSVP requests are aggregated over tunneling • Additional control message and state information is needed (compared to the 2nd mechanism) • Be able to guarantee not only quantitative QoS but also qualitative QoS • Flow aggregation makes the number of the state information small, the scalability problem can be removed • The paper is based on this mechanism

27. Two types of Mobility • Micro mobility • Macro mobility • MIP • The authors proposed the macro level QoS guarantee mechanism • The domain level agents and aggregate RSVP signaling between them are defined for the macro level QoS

28. Two issues on MIP QoS • 1. How to guarantee QoS over a tunneling section? • Ref. [3]: The tunneling section is defined as the new RSVP session from the ingress point to the egress point • Ref. [4] (based on [3]): The mobile host moves to another FA. The HA sends the new RSVP Path message to the FA in order to create the new RSVP session over IP tunnel when the periodical RSVP Update message arrived

29. Two issues on MIP QoS (cont) • 2. How to guarantee seamless real-time service regardless of handoff of a mobile host? • MRSVP (Ref. [5]): To minimize the effect of host mobility, MRSVP reserve resources in advance according to expected location, where mobile hosts is expected to move

30. Example Configuration Gateway router

31. Proposed Mechanism • At least one aggregate RSVP session must be created between the gateway routers • One gateway router must maintain the state information as many as at least the number of border gateway routers • Since the domain number is limited as a constant number, the scalability problem does not occur • The small flows, which come from the access network, must be mapped to several aggregate flows between gateways • Domain agent performs the functionality of aggregating router or de-aggregating router

32. Proposed Mechanism (cont) • In order to guarantee QoS for mobile hosts • Each aggregated RSVP session between each domain level agent reserves more bandwidth (l) than the bandwidth actually being used now for the further use • Each HA checks periodically the bandwidth amount of l. If l is lower than the initial amount, the HA can detect that the new mobile host moves within its own domain and the previously reserved bandwidth is used. Then the HA sends the RSVP Path message to the FA in order to reserve the bandwidth as much as the currently used bandwidth + l

33. Dealing with mobility

34. Micro Level QoS • 1. Applying the RSVP • The end-to-end RSVP session consists of several RSVP sessions • From the sender to HA • From HA to FA • From FA to mobile host • See the figure on next slide

35. Applying the RSVP in micro level Individual Path/Resv Aggregate Path/Resv Individual Path/Resv

36. Micro Level QoS (cont) • 2. Applying the DiffServ in Micro level QoS • The FA must decide the DSCP according the QoS requirement received in the registration request message • The FA must perform the functionality of Bandwidth Broker (BB) in DiffServ

37. Feature Comparison

38. Simulation Topology

39. Simulation Parameters

40. Simulation Result: Uncontrolled flow5 flow2 flow1 flow3 flow4

41. Simulation Result: Proposed flow5 flow2 flow3 flow1 flow4

42. Simulation Result: Comparison Delay_flow5 flow5 flow1 flow4

43. Conclusion • Proposed scheme • Macro level QoS • Aggregation of RSVP flow • Reserve more bandwidth in advance