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Layer 2 LAN Technologies & Media Access Methods ( II )

Layer 2 LAN Technologies & Media Access Methods ( II ). Minimum Ethernet Frame Size. To ensure that no node may completely receive a frame before the transmitting node has finished sending it, Ethernet defines a minimum frame size (i.e. no frame may have less than 46 bytes of payload).

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Layer 2 LAN Technologies & Media Access Methods ( II )

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  1. Layer 2 LAN Technologies & Media Access Methods(II)

  2. Minimum Ethernet Frame Size • To ensure that no node may completely receive a frame before the transmitting node has finished sending it, Ethernet defines a minimum frame size (i.e. no frame may have less than 46 bytes of payload). • The minimum frame size is related to the distance which the network spans, the type of media being used and the number of repeaters which the signal may have to pass through to reach the furthest part of the LAN. • Together these define a value known as the Ethernet Slot Time, corresponding to 512 bit times at 10 Mbps.

  3. Minimum Ethernet Frame Size • The longest time between starting to transmit a frame and receiving the first bit of a jam sequence is twice the propagation delay from one end of the cable to the other. • This means that a frame must have enough bits to last twice the propagation delay. • The 802.3 CSMA/CD Bus LAN transmits data at the standard rate of r = 10Mbps. • The speed of signal propagation is about v = 2108m/s.

  4. IEEE 802.3: Minimum Frame Length In order to calculate the minimum frame length, we must first work out the propagation delay from one end of the cable to the other.

  5. IEEE 802.3: Minimum Frame Length Example #1: Cable = 400m, transm. speed = 10 Mbit/sec, propagation speed = 2*108 m/sec Propagation delay time: The round-trip propagation delay is, of course, twice this. Thus the round trip delay is With a data rate of each bit has duration

  6. IEEE 802.3: Minimum Frame Length Example #1 – cont. The number of bits we can fit into a round-trip propagation delay is The minimum frame length is thus 40 bits (5 bytes). A margin of error is usually added to this (often to make it a power of 2) so we might use 64 bits (8 bytes).

  7. IEEE 802.3: Minimum Frame Length Example # 2 Two nodes are communicating using CSMA/CD protocol. Speed transmission is 100 Mbits/sec and frame size is 1500 bytes. The propagation speed is 3*10**8 m/sec. Calculate the distance between the nodes such that the time to transmit the frame = time to recognize that the collision have occurred.

  8. The standard frame length is at least 512 bits (64 bytes) long, which is much longer than our minimum requirement of 64 bits (8 bytes). We only have to start worrying when the LAN reaches lengths of more than 2.5km. 802.3 CSMA/CD bus LANs longer than 500m are usually composed of multiple segments joined by in-line passive repeaters, which output on one cable the signals received on another cable. When we work out the minimum frame length for these longer LANs, we also have to take the delays caused by the passive repeaters (about 2.5sec each) into account as well. IEEE 802.3: Minimum Frame Length

  9. Shortest Ethernet Frame Why specify a shortest frame of 64byte? 64 bytes sent at 10Mbps  51.2sec 500m/segment, 4 repeaters between nodes 2500m25 sec propagation delay The frame should be longer enough for sender to detect the collision(2x25 or about 50 sec ) Node A R1 R2 R3 R4 Node B 500m 25 sec propagation delay

  10. IEEE 802.3: Non-Deterministic The 802.3 CSMA/CD bus LAN is said to be a non-deterministic network. This means that no host is guaranteed to be able to send its frame within a reasonable time (just a good probability of doing so). When the network is busy, the number of collisions rises dramatically and it may become very difficult for any hosts to transmit their frames. A real-time computing application (such as an assembly line) will demand that data is transmitted within a specified time period. Since the 802.3 bus LAN cannot guarantee this, its use for real-time applications may not only be undesirable but potentially dangerous in some situations.

  11. Ethernet evolution through four generations

  12. 100 Mbps IEEE Standards • The most widely accepted Ethernet standard today is 100BaseT, which is also called fast Ethernet • The current IEEE standard for 100BaseT is 802.3u • Subcategories: • 100BaseTX: Two-pair Category 5 or higher UTP • 100BaseT4: Four-pair Category 3 or higher UTP • 100BaseFX: Two-strand fiber-optic cable • Because of its widespread use, the cable and equipment in fast Ethernet are inexpensive • Architecture of choice for all but heavily used servers and multimedia applications

  13. 100BaseTX • 100BaseTX is the standard that’s usually in mind when discussing 100 Mbps Ethernet • Requires two of the four pairs bundled in a Category 5 twisted-pair cable • Although three cable types are available for 100BaseT, 100BaseTX is the most widely accepted • Generally called fast Ethernet

  14. 100BaseT4 • 100BaseT4 Ethernet uses all four pairs of wires bundled in a UTP cable • Advantage: capability to run over Category 3 cable • One of the biggest expenses of building a network is cable installation, so many organizations with Category 3 cabling chose to get the higher speed with the existing cable plant by using 100BaseT4 instead of 100BaseTX

  15. 100BaseFX • 100BaseFX uses two strands of fiber-optic cable • Advantages: • Impervious to electrical noise and electronic eavesdropping • Can span much greater distances between devices • Disadvantage: far more expensive than twisted-pair • Rarely used as a complete 100BaseTX replacement • Used as backbone cabling between hubs or switches and to connect wiring closets between floors or buildings • Connect client or server computers to the network when immunity to noise and eavesdropping is required

  16. 100BaseT Design Considerations

  17. 100BaseT Design Considerations

  18. 10 Mbps IEEE Standards • Four major implementations of 10 Mbps Ethernet • 10Base5: Ethernet using thicknet coaxial cable • 10Base2: Ethernet using thinnet coaxial cable • 10BaseT: Ethernet over UTP cable • 10BaseF: Ethernet over fiber-optic cable • Of these 10 Mbps standards, only 10BaseT and 10BaseF are seen today • 10Base2 and 10Base5 are essentially obsolete

  19. 10BaseT

  20. 10BaseF

  21. Gigabit Ethernet: IEEE 802.3ab and 802.3z Standards • Gigabit Ethernet implementations • 802.3z-1998 covers 1000BaseX specifications, including the L (long wavelength laser/fiber-optic), S (short wavelength laser/fiber-optic), and C (copper jumper cables) • 802.3ab-1999 covers 1000BaseT specifications, which require four pairs of 100 ohm Category 5 or higher cable

  22. 1000BaseT

  23. 1000BaseLX

  24. 1000BaseSX

  25. 1000BaseCX

  26. 10 Gigabit Ethernet: 10 Gbps IEEE 802.3ae Standard • Defined to run only on fiber-optic cabling, both SMF and MMF, on a maximum distance of 40 km • Provides bandwidth that can transform how WAN speeds are thought of • Runs in full-duplex mode only • CSMA/CD is not necessary • Primary use: as network backbone • It also has its place in storage area networks (SANs) • Will be the interface for enterprise-level servers

  27. 10 Gigabit Ethernet: 10 Gbps IEEE 802.3ae Standard • Standards • 10GBASE-SR: Runs over short lengths (between 26 and 82 meters) over MMF • For high-speed servers, SANs, etc. • 10GBASE-LR: Runs up to 10 km on SMF • For campus backbones and MANs • 10GBASE-ER: Runs up to 40 km over SMF • Primary applications are for MANs • 10GBASE-SW: Uses MMF for distances up to 300 m • 10GBASE-LW: Uses SMF for distances up to 10 km • 10GBASE-EW: Uses SMF for distances up to 40 km

  28. Wireless Ethernet: IEEE 802.11b, a, and g • AP serves as the center of a star topology network • Stations can’t send and receive at the same time • CSMA/CA is used instead of CSMA/CD • 802.11b/a/g use handshaking before transmission • Station sends AP an RTS and it responds with CTS • Standards define a maximum transmission rate, but speeds might be dropped to increase reliability • No fixed segment length • Maximum of 300 feet without obstructions • Can be extended with large, high-quality antennas

  29. Broadband Technologies • Baseband systems use a digital encoding scheme at a single fixed frequency • Broadband systems use analog techniques to encode information across a continuous range of values • Signals move across the medium in the form of continuous electromagnetic or optical waves • Data flows one way only, so two channels are necessary for computers to send and receive data • E.g., cable TV

  30. Cable Modem Technology

  31. Digital Subscriber Line (DSL) • Competes with cable modem for Internet access • Broadband technology that uses existing phone lines to carry voice and data simultaneously • Most prominent variation for home Internet access is Asymmetric DSL (ADSL) • Splits phone line in two ranges: Frequencies below 4 KHz are used for voice transmission, and frequencies above 4 KHz are used to transmit data • Typical connection speeds for downloading data range from 256 Kbps to 8 Mbps; upload speeds are in the range of 16 Kbps to 640 Kbps

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