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Thinnet (10Base2)

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Title: Thinnet (10Base2)


1
Thinnet (10Base2)
  • Characteristics (cont.)
  • Size and scalability
  • Allows a maximum of 185 m per network segment
    (see Figure 4-20)
  • Noise immunity
  • More resistant than twisted-pair wiring
  • Less resistant Thicknet

Figure 4-19 Thinnet BNC connectors
2
Thinnet (10Base2)
  • Signal bounce
  • Caused by improper termination on a bus network
  • Travels endlessly between two ends of network
  • Prevents new signals from getting through

Figure 4-20 A 10Base2 Ethernet network
3
Twisted-Pair (TP) Cable
  • Color-coded pairs of insulated copper wires
    twisted around each other and encased in plastic
    coating
  • Twists in wire help reduce effects of crosstalk
  • Number of twists per meter or foot known as twist
    ratio
  • Alien Crosstalk
  • When signals from adjacent cables interfere with
    another cables transmission

Figure 21 Twisted-pair cable
4
Shielded Twisted-Pair (STP)
  • STP cable consists of twisted wire pairs that are
    individually insulated and surrounded by
    shielding made of metallic substance

Figure 4-22 STP cable
5
Unshielded Twisted-Pair
  • Consists of one or more insulated wire pairs
    encased in a plastic sheath
  • Does not contain additional shielding

Figure 4-23 UTP cable
6
Unshielded Twisted-Pair
  • To manage network cabling, it is necessary to be
    familiar with standards used on modern networks,
    particularly Category 3 (CAT3) and Category 5
    (CAT5)

Figure 4-24 A CAT5 UTP cable
7
Unshielded Twisted-Pair
  • CAT1 2 wire pairs suitable for voice only
  • CAT2 4 wire pairs up to 4 Mbps throughput
  • CAT3 4 wire pairs up to 10 Mbps and 16 Mhz
    signal
  • CAT4 4 wire pairs up to 10 Mbps
  • CAT5 4 wire pairs up to 100 Mbps and 100 Mhz
    signal
  • CAT5e up to 200 Mhz signal
  • CAT6 additional foil insulation 6x throughput
    than CAT5
  • CAT7 unfinished standard up to 1Ghz

8
10BaseT
  • Popular Ethernet networking standard that
    replaced 10Base2 and 10Base5 technologies
  • T for twisted pair

Figure 4-25 A 10BaseT Ethernet network
9
10BaseT
  • Enterprise-wide network
  • Spans entire organization
  • Often services needs of many diverse users

Figure 4-26 Interconnected 10BaseT segments
10
100BaseT
  • Enables LANs to run at 100-Mbps data transfer
    rate
  • Also known as Fast Ethernet
  • Two 100BaseT specifications have competed for
    popularity as organizations move to 100-Mbps
    technology
  • 100BaseTX
  • 100BaseT4 (can use CAT3 cabling)

11
100BaseVG
  • Cousin of Ethernet 100 Mbps technologies
  • VG stands for voice grade
  • Also called 100VG-AnyLAN
  • Originally developed by Hewlett-Packard and ATT
  • Now governed by IEEE standard 802.12
  • Requires more sophisticated NICs and can reduce
    network performance

12
Comparing STP and UTP
  • Throughput
  • Both can transmit up to 100 Mbps
  • Cost
  • Typically, STP is more expensive
  • Connector
  • Both use RJ-45 connectors and data jacks
  • Noise immunity
  • STP is more noise-resistant
  • Size and scalability
  • Maximum segment length for both is 100 meters

13
Fiber-Optic Cable
  • Contains one or several glass fibers at its core
  • Surrounding the fibers is a layer of glass called
    cladding

Figure 4-28 A fiber-optic cable
14
Fiber-Optic Cable
  • Single-mode fiber
  • Carries light pulses along single path
  • Multimode fiber
  • Many pulses of light generated by LED travel at
    different angles

Figure 4-29 Single-mode and multimode
fiber-optic cables
15
Fiber-Optic Cable
  • Throughput
  • Reliable in transmitting up to 1 gigabit per
    second
  • Cost
  • Most expensive type of cable
  • Connector
  • You can use any of 10 different types of
    connectors

16
Fiber-Optic Cable
  • Two popular connectors used with fiber-optic
    cable
  • ST connectors
  • SC connectors

Figure 4-30 ST and SC fiber connectors
17
Fiber-Optic Cable
  • Noise immunity
  • Unaffected by either EMI or RFI
  • Size and scalability
  • Network segments made from fiber can span 100
    meters
  • Signals transmitted over fiber can experience
    optical loss

18
10BaseF and 100BaseFX
  • 10BaseF
  • Physical layer standard for networks specifying
    baseband transmission, multimode fiber cabling,
    and 10-Mbps throughput
  • 100BaseFX
  • Physical layer standard for networks specifying
    baseband transmission, multimode fiber cabling,
    and 100-Mbps throughput

19
Physical Layer Networking Standards
Table 4-3 Physical layer networking standards
20
Cable Design and Management
  • 1991 TIA/EIA released its joint 568 Commercial
    Building Wiring Standard
  • TIA Telecommunication Industry Assoc.
  • www.tiaonline.org
  • EIA Electronic Industries Assoc.
  • www.eia.org
  • T568A
  • T568B

21
Cable Design and Management
  • Cable plant
  • Hardware comprising enterprise-wide cabling
    system
  • Structured cabling
  • Method for uniform, enterprise-wide, multivendor
    cabling systems

Figure 4-31 TIA/EIA structured cabling subsystems
22
Cable Design and Management
  • Entrance facilities
  • Backbone wiring
  • Backbone cabling that provides vertical
    connections between floors of a building are
    called risers

Table 4-4 TIA/EIA specifications for backbone
cabling
23
Cable Design and Management
  • Equipment room
  • Telecommunication closet
  • Punch-down block is a panel of data receptors
  • Patch panel is a wall-mounted panel of data
    receptors

Figure 4-32 Patch panel (left) and punch-down
block (right)
24
Cable Design and Management
  • Horizontal wiring
  • Max distance is 100m

Figure 4-33 Horizontal wiring
25
Cable Design and Management
  • Work area
  • Patch cable is a relatively short section of
    twisted-pair cabling with connectors on both ends
    that connect network devices to data outlets

Figure 4-34 Standard TIA/EIA wall jack
26
Cable Design and Management
Figure 4-35 A structured cabling hierarchy
27
Installing Cable
Figure 4-36 A typical UTP cabling installation
28
Installing Cable
T568A Standard
Table 4-5 Pin numbers and color codes for an
RJ-45 connector
29
Installing Cable
  • Straight-through cable
  • Terminations at both ends are identical
  • Crossover cable
  • Terminations locations of transmit and receiver
    wires on one end of cable are reversed

Figure 4-37 RJ-45 terminations on a crossover
30
Installing Cable
  • Do not untwist twisted-pair cables more than
    one-half inch before inserting them
  • Do not strip off more than one inch of insulation
    from copper wire in twisted-pair cables
  • Watch bend radius limitations for cable being
    installed
  • Test each segment of cabling with cable tester
  • Use only cable ties to cinch groups of cable
    together

31
Installing Cable
  • Avoid laying cable across floor where it may
    sustain damage
  • Install cable at least three feet away from
    fluorescent lights or other sources of EMI
  • Always leave slack in cable runs
  • If running cable in plenum, area above ceiling
    tile or below subflooring, make sure cable sheath
    is plenum-rated
  • Pay attention to grounding requirements

32
Atmospheric Transmission Media
  • Infrared transmission
  • Infrared networks use infrared light signals to
    transmit data through space
  • Direct infrared transmission depends on
    transmitter and receiver remaining within line of
    sight
  • In indirect infrared transmission, signals can
    bounce off of walls, ceilings, and any other
    objects in their path

33
Atmospheric Transmission Media
  • RF transmission
  • Radio frequency (RF) transmission relies on
    signals broadcast over specific frequencies
  • Very susceptible to interference
  • Two most common RF technologies
  • Narrowband
  • Concentrates RF energy at a single frequency
  • Spread spectrum
  • Distributed over several frequencies
    simultaneously

34
Choosing the Right Transmission Media
  • Areas of high EMI or RFI
  • Corners and small spaces
  • Distance
  • Security
  • Existing infrastructure
  • Growth
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