1. Chapter 11.4 END-TO-END ISSUES

2. Optical Internet Optical technology Protocol translates availability of gigabit bandwidth in user-perceived QoS

3. WDM network architecture WDM wide/metropolitan area network As an Internet backbone Access network Ex: campus network Domain border gateway High-speed IP router

4. WDM network architecture

5. Open issue Access network Packet loss and delay due to congestion Optical backbones High transmission rates Extremely low bit error rates Bridging the gap between access and backbone network is an issue

6. End-to-end TCP It is not practical, the reasons is below TCP slow-start algorithm constrains very large bandwidth available in the lightpath until the steady state is reached Socket buffer is not enough congestion and flow control features needed in access network

7. Split TCP connection models (1/2) It is an evolutionary approach to the TCP end-to-end model to adapt to the specific characteristics of each of the network segment It is not an efficient solution for optical networks due to the wavelength speed EX: 10-Gbps wavelength bandwidth 10-ms propagation delay bandwidth delay product (BDP)=25MB File sizes in the Internet are smaller than such BDP Because of different round-trip delays, it is difficult to optimize TCP windows to achieve transmission efficiency

8. Split TCP connection models(2/2) Most TCP features( congestion and flow control) unnecessary in optical network Extremely low loss rate in the optical network makes retransmission unlikely to happen The optical network can operate in a burst- switched mode in the optical layer, so there are no intermediate queues in which overflow occurs

9. 11.4.1 TCP for High-Speed and Split TCP Connection First approach to solving the adaptation problem between access and backbone TCP connection can be split in the optical backbone edges TCP extensions for high speed a larger transmission window no slow start

10. Files over lightpaths (FOL) Files are encapsulated in an optical burst in order to be transmitted across the optical network.

11. Simulation Topology An optical channel(1Gbps) which connects several access routers located at the boundaries of optical networks Network parameters Namely, link capacities, propagation delay, and loss probability Performance metric Connection throughput

12. Simulation

14. Simulation Result For small file sizes The connection duration is dominated by setup time and slow start, which does not allow the window size to reach a steady-state value For large file sizes The TCP reach steady state and the throughput is equal to window size divided by roundtrip time. Such behavior is expected in a large BDP network, in which connections are RTT- limited rather than bandwidth-limited

15. 11.4.2 Performance Evaluation of File Transfer (WWW) Services over WDM Networks(1/2) 11.4.1 is in error-free condition Ex: a first-generation WDM network (static lightpath between routers) second-generation WDM network suffer blocking probability Limited number of wavelengths Burst dropping due to limited queueing space in photonic packet switchs Split TCP becomes inefficient

16. Performance Evaluation of File Transfer (WWW) Services over WDM Networks(2/2) In FOL, files are encapsulated in an optical bursts through the optical backbone using a simple stop-and-wait protocol for error control. Assuming the setup of an optical burst takes RTT/2

17. Simulation Result

18. TCP congestion avoidance limits transfer efficiency This serve to illustrate that the throughput penalty imposed by the TCP congestion control mechanism is rather significant

19. The main difference between a simple FOL protocol and TCP is in interpreting congestion TCP considers loss is produced by queueing overflow FOL is aware that loss is due to blocking