Enhancing QoS Support for Vertical Handoffs Using Implicit/Explicit Handoff Notifications

1. Enhancing QoS Support forVertical Handoffs Using Implicit/Explicit Handoff Notifications Ling-Jyh Chen, Guang Yang, Tony Sun,M. Y. Sanadidi and Mario Gerla Computer Science DepartmentUniversity of California, Los Angeles QShine 2005, Orlando, Florida

2. QoS Enhancement for Vertical Handoffs • Goal: Providing highly agile system for mobile applications. QShine 2005, Orlando, Florida

3. Related Work • Conventional adaptive method: AIMD • TCP, RAP, … • TEAR, TFRC, … • They DO NOT perform well in vertical handoffs[Gurtov et al, MC2R ’04]. • Our solution: • Handoff Notifications: Implicit Handoff Notification and Explicit Handoff Notification • Enhanced Service Agility Schemes: Fast Rate Adaptation and Early Rate Reduction QShine 2005, Orlando, Florida

4. Implicit Handoff Notification • Vertical handoffs usually result in drastic changes in the link capacity. • By monitoring the end-to-end capacity, one can identify the occurrence of a vertical handoff. • Passive capacity monitoring tools:TFRC Probe & TCP Probe (CapProbe based) QShine 2005, Orlando, Florida

5. 20Mbps 10Mbps 5Mbps 10Mbps 20Mbps 8Mbps T1 Narrowest Link T2 T3 T3 T3 T3 Background on CapProbe Capacity = (Packet Size) / (Dispersion) QShine 2005, Orlando, Florida

6. TFRC: TCP Friendly Rate Control • TFRC is an equation based unicast protocol. • TFRC mimics the TCP long-term throughput by utilizing the function: • The receiver is responsible for calculating the loss event rate p and sending it back to the sender once per round-trip time. • The sender is responsible for adjusting its sending rate Tactual to be close to T. QShine 2005, Orlando, Florida

7. TFRC Probe • Embed CapProbe algorithm within TFRC by sending two packets back-to-back every n packets • TFRC Probe was assessed in [E2EMON’04]. QShine 2005, Orlando, Florida

8. CapProbe: Delayed Ack TCP Probe: TCP Probe • TCP Probe was assessed in [GI’05]. QShine 2005, Orlando, Florida

9. Implicit Handoff Notification • TCP/TFRC Probe continuously estimate the link capacity, using 50 samples per estimate. • A vertical handoff can be identified when a dramatic capacity change is observed. • An IHN is generated when • Cnew > αCpre or • Cnew < βCpre where α =5 and β=0.2. QShine 2005, Orlando, Florida

10. Enhancing QoS using IHN • Fast Rate Adaptation (FRA) • FRA monitors the capacity. • When vertical handoff from LOW to HIGH is observed, FRA changes ssthresh of TCP/TFRC. • TCP/TFRC enter slow start, instead of staying in congestion avoidance. • FRA+IHN is end-to-end. • However, IHN does not work with HIGH to LOW handoff. • Decreasing ssthresh does not change TCP/TFRC behavior. QShine 2005, Orlando, Florida

11. Explicit Handoff Notification • Need an “Intelligent Handoff Manager”. • EHN is generated prior tothe occurrence of handoff. • Smart Decision Model QShine 2005, Orlando, Florida

12. Enhancing QoS using EHN • LOW-to-HIGH: • Fast Rate Adaptation (FRA) • HIGH-to-LOW: • Early Rate Reduction (ERR):Reduce rate in advance to prevent bulk packet losses. QShine 2005, Orlando, Florida

13. Evaluation • Simulation Scenario (NS-2) • Vertical handoff between 802.11b (5.5Mbps) and 1xRTT (150kbps). QShine 2005, Orlando, Florida

14. Evaluation • TFRC: vertical handoff from LOW to HIGH QShine 2005, Orlando, Florida

15. Evaluation • TCP: vertical handoff from LOW to HIGH QShine 2005, Orlando, Florida

16. Evaluation • TFRC: vertical handoff from HIGH to LOW • EHN (a): EHN when the handoff occurs • EHN (b): EHN one OWD before the handoff QShine 2005, Orlando, Florida

17. Evaluation • TFRC: vertical handoff from HIGH to LOW QShine 2005, Orlando, Florida

18. Summary • We have proposed IHN and EHN to notify the sender about the occurrence of vertical handoff. • We have proposed FRA (for IHN) and ERR (for IHN/EHN) for better QoS for vertical handoff. QShine 2005, Orlando, Florida

19. Thank you • Questions are welcome. • For more info, please visit our web athttp://www.cs.ucla.edu/NRL/ QShine 2005, Orlando, Florida