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Physical Layer - Transmission Media

Physical Layer - Transmission Media. Transmission Media Magnetic Media Twisted Pair Coaxial Cable Fiber Optics Wireless Transmission. Magnetic Media (Sneaker Net). Floppy Disks Tape Hard Drives High-speed Transmission Media?

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Physical Layer - Transmission Media

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  1. Physical Layer - Transmission Media • Transmission Media • Magnetic Media • Twisted Pair • Coaxial Cable • Fiber Optics • Wireless Transmission

  2. Magnetic Media (Sneaker Net) • Floppy Disks • Tape • Hard Drives • High-speed Transmission Media? • A case of high-density tapes shipped overnight can transfer more bytes/second than any online connection. • Never underestimate the bandwidth of a station wagon full of tapes hurtling down the highway* - Tanenbaum

  3. Twisted Pair • Two insulated copper wires • twisting the wires reduces electrical interference • Used by the telephone system • Can run several miles without amplification • Analog or digital communication • digital (voltage determines one of two values (0 or 1)) • analog ( voltage determines continuous values) • Can achieve megabits/second transmission rates

  4. Analog signals can be modulated to convey digital information. • Three types of modulation: • Amplitude modulation • Frequency modulation • Phase modulation

  5. Types of Twisted Pair • UTP (Unshielded Twisted Pair) • Category 3 • Conventional Phone-grade line • Often used to provide 10 megabit/second Ethernet connections • Category 5 • More twists/cm than category 3 line • Teflon insulation • Often used to provide 100 megabit/second Ethernet connections

  6. Coaxial Cable • 1km cables provide 1-2 Gbps • Cables longer than 1km provide slower rates and require amplification

  7. Fiber Optic Networks • Very fast data transmission using light traveling through a fiber of glass • Pulse of light is 1 • Absence of light is 0 • May reach terabit/sec speeds in near future • terabit is 1000 gigabits • Components • light source, medium, detector

  8. Fiber Optic Networks (continued) • Uses lights source to send • Laser • High data rate, long distance, short life, expensive • Light Emitting Diode (LED) • Low data rate, short distance, long life, inexpensive • Uses Photo Diode on Receiving End • translates light to electrical impulse • currently the limiting factor in fiber optic networks • switching time is approximately 1 nanosecond

  9. Fiber Optic Ring with Active Repeaters • Two interface types • passive interface uses 2 taps (one led o laser, the other photo diode). • active interface regenerates signal at each point-to-point connection.

  10. Copper Repeaters needed every 5KM Familiar Technology Cheaper interfaces Already in place Fiber MUCH higher bandwidth Repeaters needed every 30KM Not affected by power surges or electromagnetic interference Not affected by corrosive chemicals in the air Much lighter than copper by about 80 to 1 with same bandwidth Harder to tap Copper vs Fiber

  11. The Future is Fiber • The theoretical data rates available with fiber are many orders of magnitude greater than those available from any other alternative technology.

  12. Sharing the Transmission Medium • Two Basic Methods • Frequency Division Multiplexing (FDM) • Different users get a portion of the available band • Works like radio broadcasting • Different channels (bands) carry simultaneous signals • Time Division Multiplexing (TDM) • Different users use the whole band in turn • Like time-sharing computers • The entire channel carries one signal for small intervals

  13. Time Division Multiplexing • Pulse Code Modulation • Sample the 4KHz telephone channel at 8000 8-bit cycles/second • T1 line (1.544 Mbps) • Can carry 24-time multiplexed voice channels • T2 line (6.312 Mbps) • Can carry traffic from 4 T1 lines • T3 line (44.736 Mbps) • Can carry traffic from 7 T2 lines • T4 line (274.176 Mbps) • Can carry traffic from 6 T3 lines

  14. Synchronous Optical NETwork (SONET) and Synchronous Digital Hierarchy (SDH) • Developed by Bellcore and then by CCITT • Goals • Interconnet different optical (fiber) carriers • Unify US, European, and Japanese digital systems • Multiplex multiple digital channels together • Support operations, administration, and maintenance (OAM)

  15. SONET • Uses Time Division Multiplexing • Synchronous (data sent at every clock)

  16. SONET/SDF Transmissions Speeds Synchronous Transport Signal (STS) is unscrambled Optical Carrier (OC).

  17. Switching • Three basic forms of switching • Circuit Switching • A physical connection is establish between source and destination • Message Switching • The message is sent in its entirety and then sent through a series of point-to-point transmissions • no limit on message size • Packet Switching • Messages are broken up into small pieces that are independently routed as packets.

  18. Circuit Switching is used by the telephone system.Most current computer networks use packet switching.

  19. Circuit Switching vs Packet Switching • Circuit switching uses a dedicated path through the network. • Circuit switching reserves part of the bandwidth. • Circuit switching requires a call setup. • Circuit switching can only encounter congestion during call setup, while packet switching can encounter congestion at any point in the transmission. • Circuit switched networks typically charge per minute fee, while packet switched networks typically charge per packet.

  20. The Telephone System Individual phone lines consist of two copper wires running from the home or business to an end office. End offices connect at toll offices, toll offices connect at primary offices,primary offices connect at sectional offices, and sectional offices connect at regional offices.

  21. Overview of AT&T Telephone Hierarchy • Connections are made at the lowest level possible • The first 3 digits of the number determine the end office • The copper connections at the lowest level are the major obstacle to high-speed service

  22. Modems modulate/demodulate an analog signal to transfer data over phone lines. Modulate Demodulate Computer Computer Modem Modem Digital Signal Analog Signal Digital Signal

  23. Analog signals can be modulated to convey digital information. Modems typically use phase modulation.

  24. Modems Typically encode several bits/baud • Baud - number of times per second that the signal changes its value (upper limit is 6000 Hz for analog phone lines). Constellation patterns for 3 bits/baud and 4 bits/baud modulation

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