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Mod 4 Cable Testing

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Differentiate between sine waves ... Baseband transmission ... This usage pertains to a baseband network such as Ethernet and token ring local area networks. ... – PowerPoint PPT presentation

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Title: Mod 4 Cable Testing


1
Mod 4 Cable Testing
  • CCNA 1 version 3.0
  • Rick Graziani
  • Cabrillo College

2
Overview
  • Students completing this module should be able
    to
  • Differentiate between sine waves and square
    waves.
  • Define and calculate exponents and logarithms.
  • Define and calculate decibels.
  • Define basic terminology related to time,
    frequency, and noise.
  • Differentiate between digital bandwidth and
    analog bandwidth.
  • Compare and contrast noise levels on various
    types of cabling.
  • Define and describe the affects of attenuation
    and impedance mismatch.
  • Define crosstalk, near-end crosstalk, far-end
    crosstalk, and power sum near-end crosstalk.
  • Describe how crosstalk and twisted pairs help
    reduce noise.
  • Describe the ten copper cable tests defined in
    TIA/EIA-568-B.
  • Describe the difference between Category 5 and
    Category 6 cable.

3
Background for Studying Frequency-Based Cable
Testing
  • Differentiate between sine waves and square
    waves.
  • Define and calculate exponents and logarithms.
  • Define and calculate decibels.
  • Define basic terminology related to time,
    frequency, and noise.
  • Differentiate between digital bandwidth and
    analog bandwidth.

4
Amplitude and Frequency
5
Analog Signal
6
Other information
  • For the next several slides we will explain
    analog signals from information from the
    following sources

7
Digital and Analog Bandwidth
  • Bandwidth The width or carrying capacity of a
    communications circuit.
  • Digital bandwidth the number of bits per second
    (bps) the circuit can carry
  • used in digital communications such as T-1 or DDS
  • measure in bps
  • T-1 -gt 1.544 Mbps
  • Analog bandwidth the range of frequencies the
    circuit can carry
  • used in analog communications such as voice
    (telephones)
  • measured in Hertz (Hz), cycles per second
  • voice-grade telephone lines have a 3,100 Hz
    bandwidth

8
Digital and Analog Bandwidth
  • Available at http//www.thinkgeek.com

9
Digital and Analog Bandwidth
  • Digital Signals
  • digital signal a signal whose state consists of
    discrete elements such as high or low, on or off
  • Analog Signals
  • analog signal a signal which is analogous to
    sound waves
  • telephone lines are designed to carry analog
    signals

10
Sound Waves
11
Analog Signals, Modulation and Modem Standards
  • A perfect or steady tone makes a wave with
    consistent height (amplitude) and pitch
    (frequency) which looks like a sine wave. (Figure
    4-15)
  • A cycle or one complete cycle of the wave
  • The frequency (the number of cycles) of the wave
    is measured in Hertz
  • Hertz (Hz) the number of cycles per second

12
Transmission Terminology (whatis.com)
  • Broadband transmission
  • In general, broadband refers to telecommunication
    in which a wide band of frequencies is available
    to transmit information.
  • Because a wide band of frequencies is available,
    information can be multiplexed and sent on many
    different frequencies or channels within the band
    concurrently, allowing more information to be
    transmitted in a given amount of time (much as
    more lanes on a highway allow more cars to travel
    on it at the same time).
  • Baseband transmission
  • 1) Describing a telecommunication system in which
    information is carried in digital (or analog)
    form on a single unmultiplexed signal channel on
    the transmission medium. This usage pertains to a
    baseband network such as Ethernet and token ring
    local area networks.
  • Narrowband transmission
  • Generally, narrowband describes telecommunication
    that carries voice information in a narrow band
    of frequencies.
  • More specifically, the term has been used to
    describe a specific frequency range set aside by
    the U.S. Fcc for mobile or radio services,
    including paging systems, from 50 cps to 64 Kbps.

13
Carrier Signal
  • Carrier Signal or Analog Wave An electronic
    signal used to modulate data in broadband
    transmission, usually a sine wave.

14
Carrier Signal
  • Three parts of any analog wave are
  • 1. amplitude - the height of the wave
  • 2. frequency - the pitch of the wave
  • 3. phase - the shift or position of the wave
  • These are the three parts we can modulate or
    change the carrier signal or wave!
  • Modulate Change
  • More in a moment.

15
Telephone Lines, Modems, and PSTN
  • Voice grade telephone lines and equipment are
    designed to transmit tones between 300 and 3,400
    Hertz
  • bandwidth 3,100 Hz or 3.1 KHz
  • most of our human voice falls into this range
  • Economics dictated the size of this bandwidth
  • (Keyboard example)
  • The maximum number of cycles (highest
    frequency) of an analog signal over voice grade
    telephone lines is 3,400 Hz (cycles per second)

16
Telephone Lines, Modems, and PSTN
  • Modem
  • MOdulator/DEModulator
  • converts analog signals to digital and digital
    signals to analog
  • used for transmitting digital information between
    computers over voice-grade telephone lines
  • Computers use transmission interface standards
    such as RS-232-C using positive and negative
    voltages which form square waves, whereas the
    PSTN is designed to carry analog signals (sine
    waves)

17
Modulation
  • modulation
  • 1. the process of varying the characteristic of
    an electrical carrier wave (analog, sine wave) as
    the information on that wave varies
  • Three types of modulation
  • 1. amplitude modulation
  • 2. frequency modulation
  • 3. phase modulation
  • 2. the process of converting digital signals to
    analog

18
Amplitude Modulation
  • Amplitude Modulation (AM)
  • a modulation technique to vary the height the
    electrical signal (the sine wave or carrier wave
    with modems) to transmit ones and zeroes, while
    the frequency of the wave remains constant
  • different amplitudes for 0s and 1s
  • a.k.a. amplitude shift keying, ASK
  • Figure 4-22
  • frequency for each bit remains constant
  • volume amplitude

19
Amplitude Modulation
  • Different amplitudes for 0s and 1s, while the
    frequency of the wave remains constant
  • Full duplex
  • different amplitudes and frequencies are used for
    different directions
  • Disadvantage
  • Voice-grade telephone lines are susceptible to
    distortions which affect amplitudes, as volume
    fades, the amplitude lowers
  • Amplitude modulation only effective for low speed
    transmissions

20
Frequency Modulation
  • Frequency Modulation
  • a modulation technique to vary the frequency of
    the sine wave (or carrier wave) to transmit ones
    and zeroes, while the amplitude remains constant
  • different frequencies for 0s and 1s
  • a.k.a. frequency shift keying, FSK
  • Figure 4-23
  • two separate frequencies for ones and zeroes

21
Frequency Modulation
  • Full Duplex
  • requires a minimum of four frequencies, two
    frequencies for each direction
  • i.e. CCITT V.21 for 300 baud modems
  • Originating Sending
  • Modem Modem
  • 1270 Hz 1 2225 Hz
  • 1070 Hz 0 2025 Hz
  • loss of amplitude will not cause errors in
    transmission

22
Frequency Modulation
  • Conceptually
  • If voice-grade telephone lines can transmit a
    maximum of 3,400 Hz (cycles per second),
    between 300 Hz and 3,400 Hz,
  • AND
  • If one cycle 1 bit,
  • Then a maximum of 3,400 bits per second can be
    transmitted over voice grade telephone lines?
    (Hold that thought!)

23
Phase Modulation
  • Phase Modulation (PM)
  • a modulation technique to vary the phase of the
    sine wave (or carrier wave) to transmit ones and
    zeroes, while the amplitude and the frequency
    remains constant
  • sine waves repeat themselves indefinitely
  • shifting the wave breaks the wave abruptly and
    starts it again a few degrees forward or backward
  • A different phase shift, 0 to 360 degrees, is
    used to transmit one or more bits

24
Phase Modulation
  • A different phase shift, 0 to 360 degrees, is
    used to transmit one or more bits
  • Full Duplex
  • requires a minimum of two frequencies, one
    frequency for each direction

25
Bits per second vs. Baud and High-speed modems
  • So far, discussed transmission of one bit at a
    time, via high or low amplitude, high or low
    frequency, phase shift or no phase shift
  • older modems sent only one bit per signal change,
    bps baud
  • baud rate the number of these signal changes
    per second
  • What if we could transmit more than one bit with
    each signal change (baud), amplitude, frequency
    of phase shift?
  • Remember, voice-grade phone lines limit
    transmission to 3,400 Hz or 3,400 bps with 1
    cycle per bit

26
Dibit Modulation
Dibit Amplitude modulation
  • Dibit Modulation
  • 2 bits per baud, per cycle
  • Two bits or dibit modulation
  • 00, 01, 10, 11
  • Using Amplitude Modulation
  • use four different amplitudes (wave heights)
  • Using Frequency Modulation
  • use four different frequencies
  • Using Phase Modulation
  • use four different phases

27
Summary of Modulations
  • Amplitude Modulation (AM)
  • Frequency Modulation (FM)
  • Phase Shift Keying (PSK)

28
Back to Cisco Curriculum.
29
Digital Signals
  • Square waves, like sine waves, are periodic.
  • However, square wave graphs do not continuously
    vary with time.
  • The wave holds one value for some time, and then
    suddenly changes to a different value.
  • This value is held for some time, and then
    quickly changes back to the original value.
  • Square waves represent digital signals, or
    pulses. Like all waves, square waves can be
    described in terms of amplitude, period, and
    frequency.

30
Exponents and logarithms (Not testable)
  • Numbers with exponents are used to easily
    represent very large or very small numbers.
  • It is much easier and less error-prone to
    represent one billion numerically as 109 than as
    1000000000.
  • Many calculations involved in cable testing
    involve numbers that are very large, so exponents
    are the preferred format.
  • Exponents can be explored in the flash activity.

31
Exponents and logarithms (Not testable)
  • One way to work with the very large and very
    small numbers that occur in networking is to
    transform the numbers according to the rule, or
    mathematical function, known as the logarithm.
  • Logarithms are referenced to the base of the
    number system being used.
  • For example, base 10 logarithms are often
    abbreviated log.
  • To take the log of a number use a calculator or
    the flash activity.
  • For example, log (109) equals 9, log (10-3) -3.

32
Decibels
  • The decibel (dB) is a measurement unit important
    in describing networking signals.
  • The decibel is related to the exponents and
    logarithms described in prior sections.
  • There are two formulas for calculating decibels
  • dB 10 log10 (Pfinal / Pref)
  • dB 20 log10 (Vfinal / Vreference)

33
Decibels
  • There are two formulas for calculating decibels
  • dB 10 log10 (Pfinal / Pref)
  • dB 20 log10 (Vfinal / Vreference)
  • The variables represent the following values
  • dB measures the loss or gain of the power of a
    wave.
  • Decibels are usually negative numbers
    representing a loss in power as the wave travels,
    but can also be positive values representing a
    gain in power if the signal is amplified
  • log10 implies that the number in parenthesis will
    be transformed using the base 10 logarithm rule
  • Pfinal is the delivered power measured in Watts
  • Pref is the original power measured in Watts
  • Vfinal is the delivered voltage measured in Volts
  • Vreference is the original voltage measured in
    Volts

34
Decibels (Not testable)
  • The first formula describes decibels in terms of
    power (P), and the second in terms of voltage
    (V).
  • Typically, light waves on optical fiber and radio
    waves in the air are measured using the power
    formula.
  • Electromagnetic waves on copper cables are
    measured using the voltage formula.

35
Decibels (Not testable)
  • Enter values for dB and Pref to discover the
    correct power.
  • This formula could be used to see how much power
    is left in a radio wave after it has traveled
    over a distance through different materials, and
    through various stages of electronic systems such
    as a radio.

36
Viewing signals in time and frequency
  • An oscilloscope is an important electronic device
    used to view electrical signals such as voltage
    waves and pulses.
  • The x-axis on the display represents time, and
    the y-axis represents voltage or current.
  • There are usually two y-axis inputs, so two waves
    can be observed and measured at the same time.
  • Analyzing signals using an oscilloscope is called
    time-domain analysis, because the x-axis or
    domain of the mathematical function represents
    time.

37
Viewing signals in time and frequency
  • Engineers also use frequency-domain analysis to
    study signals.
  • In frequency-domain analysis, the x-axis
    represents frequency.
  • An electronic device called a spectrum analyzer
    creates graphs for frequency-domain analysis.

38
Analog and digital signals in time and frequency
  • To understand the complexities of networking
    signals and cable testing, examine how analog
    signals vary with time and with frequency.
  • Imagine the combination of several sine waves.

39
Noise in time and frequency
  • Noise is an important concept in communications
    systems, including LANS.
  • While noise usually refers to undesirable sounds,
    noise related to communications refers to
    undesirable signals.
  • Noise can originate from natural and
    technological sources, and is added to the data
    signals in communications systems.
  • All communications systems have some amount of
    noise.
  • Even though noise cannot be eliminated, its
    effects can be minimized if the sources of the
    noise are understood. Laser noise at the
    transmitter or receiver of an optical signal

40
Noise in time and frequency
  • There are many possible sources of noise
  • Nearby cables which carry data signals
  • Radio frequency interference (RFI), which is
    noise from other signals being transmitted nearby
  • Electromagnetic interference (EMI), which is
    noise from nearby sources such as motors and
    lights

41
Bandwidth
  • Analog bandwidth typically refers to the
    frequency range of an analog electronic system.
  • Analog bandwidth could be used to describe the
    range of frequencies transmitted by a radio
    station or an electronic amplifier.
  • The units of measurement for analog bandwidth is
    Hertz, the same as the unit of frequency.
  • Example of analog bandwidth values are 3 kHz for
    telephony

42
Bandwidth
  • Digital bandwidth measures how much information
    can flow from one place to another in a given
    amount of time.
  • The fundamental unit of measurement for digital
    bandwidth is bits per second (bps).
  • Since LANs are capable of speeds of millions of
    bits per second, measurement is expressed in
    kilobits per second (Kbps) or megabits per second
    (Mbps).

43
Signals and Noise
  • Compare and contrast noise levels on various
    types of cabling.
  • Define and describe the affects of attenuation
    and impedance mismatch.
  • Define crosstalk, near-end crosstalk, far-end
    crosstalk, and power sum near-end crosstalk.
  • Describe how crosstalk and twisted pairs help
    reduce noise.
  • Describe the ten copper cable tests defined in
    TIA/EIA-568-B.
  • Describe the difference between Category 5 and
    Category 6 cable.

44
Signaling over copper and fiber optic cabling
  • In order for the LAN to operate properly, the
    receiving device must be able to accurately
    interpret the binary ones and zeros transmitted
    as voltage levels.
  • Since current Ethernet technology supports data
    rates of billions of bits per second, each bit
    must be recognized, even though duration of the
    bit is very small.
  • The voltage level cannot be amplified at the
    receiver, nor can the bit duration be extended in
    order to recognize the data.
  • This means that as much of the original signal
    strength must be retained, as the signal moves
    through the cable and passes through the
    connectors.
  • In anticipation of ever-faster Ethernet
    protocols, new cable installations should be made
    with the best available cable, connectors, and
    interconnect devices such as punch-down blocks
    and patch panels. 

45
Attenuation and insertion loss on copper media
  • Attenuation is the decrease in signal amplitude
    over the length of a link.
  • Long cable lengths and high signal frequencies
    contribute to greater signal attenuation.

46
Sources of noise on copper media
  • Crosstalk involves the transmission of signals
    from one wire to a nearby wire.
  • When voltages change on a wire, electromagnetic
    energy is generated.
  • This energy radiates outward from the
    transmitting wire like a radio signal from a
    transmitter.
  • Adjacent wires in the cable act like antennas,
    receiving the transmitted energy, which
    interferes with data on those wires.

47
Sources of noise on copper media
  • Twisted-pair cable is designed to take advantage
    of the effects of crosstalk in order to minimize
    noise.
  • In twisted-pair cable, a pair of wires is used to
    transmit one signal.
  • The wire pair is twisted so that each wire
    experiences similar crosstalk.
  • Because a noise signal on one wire will appear
    identically on the other wire, this noise be
    easily detected and filtered at the receiver. 

48
Types of crosstalk
  • There are three distinct types of crosstalk
  • Near-end Crosstalk (NEXT)
  • Far-end Crosstalk (FEXT)
  • Power Sum Near-end Crosstalk (PSNEXT)

49
Near-end Crosstalk (NEXT)
  • Near-end crosstalk (NEXT) is computed as the
    ratio of voltage amplitude between the test
    signal and the crosstalk signal when measured
    from the same end of the link.

50
Far-end Crosstalk (FEXT)
  • Due to attenuation, crosstalk occurring further
    away from the transmitter creates less noise on a
    cable than NEXT.
  • This is called far-end crosstalk, or FEXT.
  • The noise caused by FEXT still travels back to
    the source, but it is attenuated as it returns.
  • Thus, FEXT is not as significant a problem as
    NEXT.

51
Power Sum Near-end Crosstalk (PSNEXT)
  • Power Sum NEXT (PSNEXT) measures the cumulative
    effect of NEXT from all wire pairs in the cable.
  • PSNEXT is computed for each wire pair based on
    the NEXT effects of the other three pairs.
  • The combined effect of crosstalk from multiple
    simultaneous transmission sources can be very
    detrimental to the signal.

52
Cable testing standards
  • The ten primary test parameters that must be
    verified for a cable link to meet TIA/EIA
    standards are
  • Wire map
  • Insertion loss
  • Near-end crosstalk (NEXT)
  • Power sum near-end crosstalk (PSNEXT)
  • Equal-level far-end crosstalk (ELFEXT)
  • Power sum equal-level far-end crosstalk
    (PSELFEXT)
  • Return loss
  • Propagation delay
  • Cable length
  • Delay skew

53
Cable testing standards
  • The Ethernet standard specifies that each of the
    pins on an RJ-45 connector have a particular
    purpose.
  • A NIC transmits signals on pins 1 and 2, and it
    receives signals on pins 3 and 6.
  • The wires in UTP cable must be connected to the
    proper pins at each end of a cable.

54
Cable testing standards
  • The wire map test insures that no open or short
    circuits exist on the cable.
  • An open circuit occurs if the wire does not
    attach properly at the connector.
  • A short circuit occurs if two wires are connected
    to each other.

55
Cable testing standards
  • The wire map test also verifies that all eight
    wires are connected to the correct pins on both
    ends of the cable.
  • There are several different wiring faults that
    the wire map test can detect.

56
Other test parameters
  • Return loss is a measure in decibels of
    reflections that are caused by the impedance
    discontinuities at all locations along the link.
  • Recall that the main impact of return loss is not
    on loss of signal strength.
  • The significant problem is that signal echoes
    caused by the reflections from the impedance
    discontinuities will strike the receiver at
    different intervals causing signal jitter.

57
Time-based parameters
  • Testers measure the length of the wire based on
    the electrical delay as measured by a Time Domain
    Reflectometry (TDR) test, not by the physical
    length of the cable jacket.
  • Since the wires inside the cable are twisted,
    signals actually travel farther than the physical
    length of the cable.

58
Testing optical fiber
  • Fiber links are subject to the optical equivalent
    of UTP impedance discontinuities.
  • When light encounters an optical discontinuity,
    some of the light signal is reflected back in the
    opposite direction with only a fraction of the
    original light signal continuing down the fiber
    towards the receiver.
  • This results in a reduced amount of light energy
    arriving at the receiver, making signal
    recognition difficult.
  • Just as with UTP cable, improperly installed
    connectors are the main cause of light reflection
    and signal strength loss in optical fiber.

59
Testing optical fiber
  • Absence of electrical signals.
  • There are no crosstalk problems on fiber optic
    cable.
  • External electromagnetic interference or noise
    has no affect on fiber cabling.
  • Attenuation does occur on fiber links, but to a
    lesser extent than on copper cabling.

60
A new standard
  • On June 20, 2002, the Category 6 (or Cat 6)
    addition to the TIA-568 standard was published.
  • The official title of the standard is
    ANSI/TIA/EIA-568-B.2-1.
  • Although the Cat 6 tests are essentially the same
    as those specified by the Cat 5 standard, Cat 6
    cable must pass the tests with higher scores to
    be certified.
  • Cat6 cable must be capable of carrying
    frequencies up to 250 MHz and must have lower
    levels of crosstalk and return loss.

61
Summary
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