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Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Chapter 8 TCP/IP Performance over Optical Networks.

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Presentation on theme: "Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Chapter 8 TCP/IP Performance over Optical Networks."— Presentation transcript:

1 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Chapter 8 TCP/IP Performance over Optical Networks

2 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Objectives  Gain an overview of optical networks  Learn transport architectures for carrying TCP/IP traffic over optical networks  Understand specific performance issues when TCP/IP traffic is transported over optical networks  Design optical packet switches which maximize TCP performance

3 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Contents  Optical networks  Multiprotocol label switching  Optical switching  TCP Performance issues

4 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Optical Networks

5 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Evolution of Optical Networks  First optic transmission system in early 70s  Optical switching emerged in last few years  Coherent optical transmission based on DWDM  Optical transparent networks  No optical to electrical conversion  All functions performed in optics

6 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain IP over DWDM  Overlay approach  Low efficiency  High costs for network management  IP over SONET  Carrying IP packets directly over SONET  Without SONET layer (PPP/HDLC)

7 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain IP over DWDM (Cont.)  Optical layer accessible through optical UNI (O-UNI)  Integrated approach  Integrate IP control plane with the optical control plane  Functions of optical adaptation layer shifted into higher layers (similar to MPLS)

8 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain MPLS

9 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain MPLS  Connection-oriented (as opposed to IP)  Partition network layer function into two basic components:  Control: responsible for routing  Forwarding : responsible for processing packets  Enable high speed processing

10 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain MP S  Integrate MPLS with all-optical networks  LSPs are mapped into wavelengths  Support end-to-end networking of optical channel paths between access points  Creates point-to-point optical channels  OXCs  Wavelengths

11 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Optical Switching

12 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Optical Burst Switching  A middle term solution towards all optical packet switching  Establish optical connections  Optical burst determination  Routing  Wavelength assignment  Resource reservation  End-to-end connection setup

13 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Optical Packet Switching  Optimize the exploitation of DWDM channels  Transparent optical packet routers carrying TCP/IP traffic  Minimum electro-optical conversion  Packet label/header converted from optical to electrical  Payload is switched optically

14 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain TCP Performance Issues

15 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain DWDM Optical Router  Fig. 8.3  Functional blocks  Input-output interfaces  Optical space switch  Delay line buffer  Electronic control

16 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Congestion Resolution  Queuing  Time domain  Achieved by delay lines (coils of fibers)  Wavelength multiplexing  Wavelength domain  Wavelength circuit (WC)  Wavelength packet (WP)

17 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain TCP Performance over Optical Networks  Latency has significant impacts on TCP window evolution  Fixed latency with overlay approach and MP S  Variable latency with optical burst/packet switching

18 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain End-to-End Delay  Consists of three components  Interface delay GPacketization delay GTransmission delay  Node delay GHeader processing GSwitching matrix setup Gqueuing delay in fiber delay lines  Propagation delay

19 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Mapping TCP in Optical Packets  Why map TCP in optical packets  High data rate  Large bandwidth-delay product  Share an optical pipe among many TCP connections  Fill optical packets with TCP segments

20 Prentice HallHigh Performance TCP/IP Networking, Hassan-Jain Optical Packet Design in TCP/IP Environment  Packetization efficiency  Fig. 8.7  Optimal value increases as the time-out increases  Packetization Delay  Congestion Window

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