Comparison of IP Micromobility Protocol

1. Comparison of IP Micromobility Protocol Wireless/Mobile Network Lab 이 진 우

2. Contents • Introduction • Classification of protocols • A Generic Model • Simulation Model • Handoff Quality • Route Control Messaging • Improved Handoff Schemes • Conclusion

3. Introduction • Micormobility protocols • Motivation • Predominance of pico-cellular environment in the future – small cell size, large number of access points • Efficiency problem of Mobile IP for real-time application within a single domain : high handoff latency, high signaling overhead and transient packet loss • No paing capability in Mobile IP • Main functions • Path setup mechanism, Fast handoff mechanism, Paging mechanism • Presentation • Performance comparison of CIP(Cellular IP), Hawaii, Hierarchical Mobile IP(HMIP) based on the Columbia IP Micromobility Software(CIMS) ns-2 extension

4. Classification of protocols • Hierarchical Tunnel-based Approach • Location database is maintained in a distributed form by set of FAs in the access network • Tunneling corresponding to FA toward MH’s AP • BCMP, IDMP, 3G UMTS/CDMA2000, HMIP • Mobile-Specific Routing Approach • Avoidance of the overhead introduced by decapsulation and reencapsulation schemes without tunneling and address conversion • Use home address and co-located COA in access network • Cellular IP, Hawaii

5. Figure 1. Two approach Hierarchical Tunneling Approach Mobile-Specific Routing Approach

6. A Generic Model (Cont.) • The use of MRP (mobile routing point) • MSR to refer to nodes that participate in the procedure • Each MSR contains a list of hosts whose data path traverses the MSR • Figure 2-a • Data packet addressed to MH0 are forwarded by using “IP-in IP” encapsulation • Use Hierarchical tunneling such as HMIP • Figure 2-b • Internal address (MH0’s identifier) remain unchanged while external address (the next MRP’s address) is replaced by each MRP • IP Packets are encapsulated in L2 frames such as CIP and Hawaii Figure 2 : a) A network of mobile routing points ; b) a full network with intermediate nodes

7. A Generic Model <Mapping of micromobility protocols to the generic micormobility model based on MRPs> <Micromobility protocols grouped by the MPR protocol layer>

8. Simulation Model • CIMS ( Columbia IP Micromobility Software) • Micromobility extension for the ns-2 network simulator • Support separate models for CIP, Hawaii, HMIP • CIP : Hard and semisoft handoff, Paging and security • Hawaii : UNF (unicast nonforwarding) and MSF (multiple stream forwarding) handoff • Hawaii • BaseStatioinNode object instead of AP • Hawaii router are implemented in special HawaiiAgent object • HMIP • Use a GFAAgent object to implement a single GFA and FAs in each AP Figure 3. The simulated network topology

9. Handoff Quality (Cont.) • UDP • MH moves periodically between neighboring AP at a speed of 20 m/s • Use UDP probing traffic between CH and MH and count the average number of packet loss during handoff • Results of Figure 4 • CIP hard handoff and Hawaii UNF are very similar and handoff delay is related to the packet delay between the APs and the cross-over node • HMIP cannot benefit from crossover distance Figure 4. UDP packet loss at handoff

10. Handoff Quality • TCP • At 14.75s into the simulation a CIP hard handoff occurs • Packet loss caused by the handoff results in a TCP timeout Figure 5. TCP sequence numbers at the time of CIP hard handoff

11. Route Control Messaging • According to Tree topologies • CIP and Hawaii are similar for tree topologies • Difference for non-tree topologies • Suboptimal in Hawaii • Optimal in CIP • Trade-off of suboptimal routing • Cause performance bottleneck and signaling load at the common section • Discard update message at crossover MRP

12. Improved Handoff Schemes (Cont.) • Packet loss reduction techniques • Bi-casting techniques of CIP • Semisoft handoff by allowing a MH to set up routing to new AP prior to handoff • Delay device for a fixed period amount of time (Tss) before transmission • Buffering and forwarding techniques of Hawaii • MSF operates after handoff • Old AP forwards packet to new AP during handoff • Store all packet received for a certain period (Tmsf) • HMIP • Operate along similar lines, bi-casting and buffering and forwarding

13. Improved Handoff Schemes (Cont.) CIP semisoft handoff Hawaii MSF handoff Figure 8. UDP packet loss and duplication ; this is for packet interarrival times of 5 ms and 10 ms

14. Improved Handoff Schemes (Cont.) semi-soft handoff (Tss = 50 ms) semi-soft handoff (Tss = 100 ms) Figure 9. TCP sequence numbers at the time of a Cellular IP

15. Improved Handoff Schemes • Difference between CIP and Hawaii • Packet reordering • TCP protocol reacts adversely to Hawaii MSF • NewReno congestion control • Applying NewReno congestion control represents a different approach to improving handoff performance • NewReno can be advatageous in case of batch losses due to radio fading Figure 6. Application level TCP throughput in periodic handoffs

16. Conclusion • Open issue • Support the delivery of a variety of traffic including best effort and real-time traffic • Work on a suitable QoS model for micromobility • Working group • IETF Mobile IP WG • IETF Seamoby WG • Low-latency handoff, IP paging