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ICSA 411: Week 2 Data Transmission

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Title: ICSA 411: Week 2 Data Transmission


1
ICSA 411 Week 2Data Transmission
  • Elizabeth Lane Lawley, Instructor

2
Electromagnetic Signals
  • Function of time
  • Analog (varies smoothly over time)
  • Digital (constant level over time, followed by a
    change to another level)
  • Function of frequency (more important)
  • Spectrum (range of frequencies)
  • Bandwidth (width of the spectrum)

3
Periodic Signal Characteristics
  • Amplitude (A) signal value, measured in volts
  • Frequency (f) repetition rate, cycles per second
    or Hertz
  • Period (T) amount of time it takes for one
    repetition, T1/f
  • Phase (F) relative position in time, measured in
    degrees

4
Bandwidth
  • Width of the spectrum of frequencies that can be
    transmitted
  • if spectrum300 to 3400Hz, bandwidth3100Hz
  • Greater bandwidth leads to greater costs
  • Limited bandwidth leads to distortion

5
Why Study Analog in a Data Comm Class?
  • Much of our data begins in analog form must
    understand it in order to properly convert it
  • Telephone system is primarily analog rather than
    digital (designed to carry voice signals)
  • Low-cost, ubiquitous transmission medium
  • If we can convert digital information (1s and 0s)
    to analog form (audible tone), it can be
    transmitted inexpensively

6
Data vs Signals
  • Analog data
  • Voice
  • Images
  • Digital data
  • Text
  • Digitized voice or images

7
Analog Signaling
  • represented by sine waves

phase difference
1 cycle
amplitude (volts)
time
(sec)
frequency (hertz)
cycles per second
8
Voice/Audio Analog Signals
  • Easily converted from sound frequencies (measured
    in loudness/db) to electromagnetic frequencies,
    measured in voltage
  • Human voice has frequency components ranging from
    20Hz to 20kHz
  • For practical purposes, the telephone system has
    a narrower bandwidth than human voice, from 300
    to 3400Hz

9
Image/Video Analog Data to Analog Signals
  • Image is scanned in lines each line is displayed
    with varying levels of intensity
  • Requires approximately 4Mhz of analog bandwidth
  • Since multiple signals can be sent via the same
    channel, guardbands are necessary, raising
    bandwidth requirements to 6Mhz per signal

10
Data Analog Signals
  • Requires conversion from digital data to analog
    signal
  • Discussed in more detail later tonight

11
Digital Signaling
  • represented by square waves or pulses

1 cycle
amplitude (volts)
time
(sec)
frequency (hertz)
cycles per second
12
Digital Text Signals
  • Transmission of electronic pulses representing
    the binary digits 1 and 0
  • How do we represent letters, numbers, characters
    in binary form?
  • Earliest example Morse code (dots and dashes)
  • Most common current form ASCII

13
ASCII Character Codes
  • Used to represent alphanumeric characters
  • Use 7 bits of data to transmit one character
  • 7 bits have 128 possible outcomes (0 to 127)
  • Most characters are stored and transmitted using
    8 bits
  • In communication, the eighth bit is used as a
    parity bit for error correction
  • In applications, use of an eighth bit allows
    high-order bit characters, such as diacritics
    and symbols

14
Digital Image Signals
  • Analog facsimile
  • similar to video scanning
  • Digital facsimile, bitmapped graphics
  • uses pixelization
  • Object-oriented graphics
  • image represented using library of objects
  • e.g. Postscript, TIFF

15
Pixelization and Binary Representation
  • Used in digital fax, bitmapped graphics

1-bit code 00000000 00111100 01110110 0111
1110 01111000 01111110 00111100 00000000
16
Transmission Media
  • the physical path between transmitter and
    receiver (channel)
  • design factors affecting data rate
  • bandwidth
  • physical environment
  • number of receivers
  • impairments

17
Electromagnetic Spectrum for Transmission Media
18
Impairments and Capacity
  • Impairments exist in all forms of data
    transmission
  • Analog signal impairments result in random
    modifications that impair signal quality
  • Digital signal impairments result in bit errors
    (1s and 0s transposed)

19
Transmission Impairments
  • Attenuation
  • loss of signal strength over distance
  • Attenuation Distortion
  • different losses at different frequencies
  • Delay Distortion
  • different speeds for different frequencies
  • occurs only in guided media
  • Noise
  • distortions of signal caused by interference

20
Types of Noise
  • Thermal (aka white noise)
  • Uniformly distributed, cannot be eliminated
  • Intermodulation
  • When different frequencies collide (creating
    harmonics)
  • Crosstalk
  • Overlap of signals
  • Impulse noise
  • Irregular spikes, less predictable

21
Classes of Transmission Media
  • Conducted or guided media
  • use a conductor such as a wire or a fiber optic
    cable to move the signal from sender to receiver
  • Wireless or unguided media
  • use radio waves of different frequencies and do
    not need a wire or cable conductor to transmit
    signals

22
Guided Transmission Media
  • Transmission capacity depends on the distance and
    on whether the medium is point-to-point or
    multipoint
  • Examples
  • twisted pair wires
  • coaxial cables
  • optical fiber

23
Twisted Pair Wires
  • Consists of two insulated copper wires arranged
    in a regular spiral pattern to minimize the
    electromagnetic interference between adjacent
    pairs
  • Often used at customer facilities and also over
    distances to carry voice as well as data
    communications
  • Low frequency transmission medium

24
Types of Twisted Pair
  • STP (shielded twisted pair)
  • the pair is wrapped with metallic foil or braid
    to insulate the pair from electromagnetic
    interference
  • UTP (unshielded twisted pair)
  • each wire is insulated with plastic wrap, but the
    pair is encased in an outer covering

25
Ratings of Twisted Pair
  • Category 3 UTP
  • data rates of up to 16mbps are achievable
  • Category 5 UTP
  • data rates of up to 100mbps are achievable
  • more tightly twisted than Category 3 cables
  • more expensive, but better performance
  • STP
  • More expensive, harder to work with

26
Twisted Pair Advantages
  • Inexpensive and readily available
  • Flexible and light weight
  • Easy to work with and install

27
Twisted Pair Disadvantages
  • Susceptibility to interference and noise
  • Attenuation problem
  • For analog, repeaters needed every 5-6km
  • For digital, repeaters needed every 2-3km
  • Relatively low bandwidth (3000Hz)

28
Coaxial Cable (or Coax)
  • Used for cable television, LANs, telephony
  • Has an inner conductor surrounded by a braided
    mesh
  • Both conductors share a common center axial,
    hence the term co-axial

29
Coax Layers
outer jacket (polyethylene)
shield(braided wire)
insulating material
copper or aluminum conductor
30
Coax Advantages
  • Higher bandwidth
  • 400 to 600Mhz
  • up to 10,800 voice conversations
  • Can be tapped easily (pros and cons)
  • Much less susceptible to interference than
    twisted pair

31
Coax Disadvantages
  • High attenuation rate makes it expensive over
    long distance
  • Bulky

32
Fiber Optic Cable
  • Relatively new transmission medium used by
    telephone companies in place of long-distance
    trunk lines
  • Also used by private companies in implementing
    local data communications networks
  • Require a light source with injection laser diode
    (ILD) or light-emitting diodes (LED)

33
Fiber Optic Layers
  • consists of three concentric sections

34
Fiber Optic Types
  • multimode step-index fiber
  • the reflective walls of the fiber move the light
    pulses to the receiver
  • multimode graded-index fiber
  • acts to refract the light toward the center of
    the fiber by variations in the density
  • single mode fiber
  • the light is guided down the center of an
    extremely narrow core

35
Fiber Optic Signals
fiber optic multimode step-index
fiber optic multimode graded-index
fiber optic single mode
36
Fiber Optic Advantages
  • greater capacity (bandwidth of up to 2 Gbps)
  • smaller size and lighter weight
  • lower attenuation
  • immunity to environmental interference
  • highly secure due to tap difficulty and lack of
    signal radiation

37
Fiber Optic Disadvantages
  • expensive over short distance
  • requires highly skilled installers
  • adding additional nodes is difficult

38
Wireless (Unguided Media) Transmission
  • transmission and reception are achieved by means
    of an antenna
  • directional
  • transmitting antenna puts out focused beam
  • transmitter and receiver must be aligned
  • omnidirectional
  • signal spreads out in all directions
  • can be received by many antennas

39
Wireless Examples
  • terrestrial microwave transmission
  • satellite transmission
  • broadcast radio
  • infrared

40
Terrestrial Microwave Transmission
  • uses the radio frequency spectrum, commonly from
    2 to 40 Ghz
  • transmitter is a parabolic dish, mounted as high
    as possible
  • used by common carriers as well as by private
    networks
  • requires unobstructed line of sight between
    source and receiver
  • curvature of the earth requires stations (called
    repeaters) to be 30 miles apart

41
Microwave Transmission Applications
  • long-haul telecommunications service for both
    voice and television transmission
  • short point-to-point links between buildings for
    closed-circuit TV or a data link between LANs
  • bypass application

42
Microwave Transmission Advantages
  • no cabling needed between sites
  • wide bandwidth
  • multichannel transmissions

43
Microwave Transmission Disadvantages
  • line of sight requirement
  • expensive towers and repeaters
  • subject to interference such as passing airplanes
    and rain

44
Satellite Microwave Transmission
  • a microwave relay station in space
  • can relay signals over long distances
  • geostationary satellites
  • remain above the equator at a height of 22,300
    miles (geosynchronous orbit)
  • travel around the earth in exactly the time the
    earth takes to rotate

45
Satellite Transmission Links
  • earth stations communicate by sending signals to
    the satellite on an uplink
  • the satellite then repeats those signals on a
    downlink
  • the broadcast nature of the downlink makes it
    attractive for services such as the distribution
    of television programming

46
Satellite Transmission Process
satellite transponder
dish
dish
22,300 miles
uplink station
downlink station
47
Satellite Transmission Applications
  • television distribution
  • a network provides programming from a central
    location
  • direct broadcast satellite (DBS)
  • long-distance telephone transmission
  • high-usage international trunks
  • private business networks

48
Principal Satellite Transmission Bands
  • C band 4(downlink) - 6(uplink) GHz
  • the first to be designated
  • Ku band 12(downlink) -14(uplink) GHz
  • rain interference is the major problem
  • Ka band 19(downlink) - 29(uplink) GHz
  • equipment needed to use the band is still very
    expensive

49
Satellite Advantages
  • can reach a large geographical area
  • high bandwidth
  • cheaper over long distances

50
Satellite Disadvantages
  • high initial cost
  • susceptible to noise and interference
  • propagation delay

51
Three Components of Data Communication
  • Data
  • Analog Continuous value data (sound, light,
    temperature)
  • Digital Discrete value (text, integers, symbols)
  • Signal
  • Analog Continuously varying electromagnetic wave
  • Digital Series of voltage pulses (square wave)
  • Transmission
  • Analog Works the same for analog or digital
    signals
  • Digital Used only with digital signals

52
Analog Data?Signal Options
  • Analog data to analog signal
  • Inexpensive, easy conversion (eg telephone)
  • Data may be shifted to a different part of the
    available spectrum (multiplexing)
  • Used in traditional analog telephony
  • Analog data to digital signal
  • Requires a codec (encoder/decoder)
  • Allows use of digital telephony, voice mail

53
Digital Data?Signal Options
  • Digital data to analog signal
  • Requires modem (modulator/demodulator)
  • Allows use of PSTN to send data
  • Necessary when analog transmission is used
  • Digital data to digital signal
  • Requires CSU/DSU (channel service unit/data
    service unit)
  • Less expensive when large amounts of data are
    involved
  • More reliable because no conversion is involved

54
Transmission Choices
  • Analog transmission
  • only transmits analog signals, without regard for
    data content
  • attenuation overcome with amplifiers
  • signal is not evaluated or regenerated
  • Digital transmission
  • transmits analog or digital signals
  • uses repeaters rather than amplifiers
  • switching equipment evaluates and regenerates
    signal

55
Data, Signal, and Transmission Matrix
56
Advantages of Digital Transmission
  • The signal is exact
  • Signals can be checked for errors
  • Noise/interference are easily filtered out
  • A variety of services can be offered over one
    line
  • Higher utilization of bandwidth is possible with
    data compression

57
Why Use Analog Transmission?
  • Already in place
  • Significantly less expensive
  • Lower attentuation rates
  • Fully sufficient for transmission of voice signals

58
Analog Encoding of Digital Data
  • Data encoding and decoding technique to represent
    data using the properties of analog waves
  • Modulation the conversion of digital signals to
    analog form
  • Demodulation the conversion of analog data
    signals back to digital form

59
Modem
  • An acronym for modulator-demodulator
  • Uses a constant-frequency signal known as a
    carrier signal
  • Converts a series of binary voltage pulses into
    an analog signal by modulating the carrier signal
  • The receiving modem translates the analog signal
    back into digital data

60
Methods of Modulation
  • Amplitude modulation (AM) or amplitude shift
    keying (ASK)
  • Frequency modulation (FM) or frequency shift
    keying (FSK)
  • Phase modulation or phase shift keying (PSK)

61
Amplitude Shift Keying (ASK)
  • In radio transmission, known as amplitude
    modulation (AM)
  • The amplitude (or height) of the sine wave varies
    to transmit the ones and zeros
  • Major disadvantage is that telephone lines are
    very susceptible to variations in transmission
    quality that can affect amplitude

62
ASK Illustration
1
0
0
1
63
Frequency Shift Keying (FSK)
  • In radio transmission, known as frequency
    modulation (FM)
  • Frequency of the carrier wave varies in
    accordance with the signal to be sent
  • Signal transmitted at constant amplitude
  • More resistant to noise than ASK
  • Less attractive because it requires more analog
    bandwidth than ASK

64
FSK Illustration
1
1
0
1
65
Phase Shift Keying (PSK)
  • Also known as phase modulation (PM)
  • Frequency and amplitude of the carrier signal are
    kept constant
  • The carrier signal is shifted in phase according
    to the input data stream
  • Each phase can have a constant value, or value
    can be based on whether or not phase changes
    (differential keying)

66
PSK Illustration
0
0
1
1
67
Differential Phase Shift Keying (DPSK)
0
0
1
1
68
Analog Channel Capacity BPS vs. Baud
  • Baud of signal changes per second
  • BPSbits per second
  • In early modems only, baudBPS
  • Each signal change can represent more than one
    bit, through complex modulation of amplitude,
    frequency, and/or phase
  • Increases information-carrying capacity of a
    channel without increasing bandwidth
  • Increased combinations also leads to increased
    likelihood of errors

69
Quadrature Amplitude Modulation (QAM)
  • Commonly used method for quadbit transfer
  • Combination of 8 different angles in phase
    modulation and two amplitudes of signal
  • Provides 16 different signals, each of which can
    represent 4 bits

70
Quadrature Amplitude Modulation Illustration
90
135
45
amplitude 1
0
180
amplitude 2
225
315
270
71
QAM Example CCITT V.22bis Modem
  • Uses QAM
  • "bis" qualifier is a French term for "duo" or
    "twice"
  • Supports transmission of full-duplex 2400 bps
    synchronous or asynchronous data over a switched,
    2-Wire, voice circuit
  • Modulation rate is 600 baud, with each baud
    representing four data bits

72
Trellis Coded Modulation (TCM)
  • Sophisticated mathematics are used to predict the
    best fit between the incoming signal and a large
    set of possible combinations of amplitude and
    phase changes
  • Forward Error Correcting (FEC)
  • Used in V.32 (9600 bps) and higher speed modems

73
CCITT V-Series Modem Recommendations
  • V.22 1200 bps duplex modem standardized for use
    in the PSTN and on leased circuits
  • V.29 9600 bps modem standardized for use on
    point-to-point 4-wire leased telephone circuits
  • V. 32 2-wire, duplex modems operating at data
    rate of up to 9600 bps for use on the PSTN and on
    leased circuits

74
V.32 bis Modems
  • Uses Trellis coding with QAM
  • Allows transport of data up to 14400 bps
  • Modulation rate is 2400 baud

75
V.34 Modems
  • Capable transmission up to 28.8 kbps
  • Modulation rate (baud rate) and carrier frequency
    can vary
  • Multi-dimensional Trellis-coding is employed

76
V.34 Modems
  • Data rate up to 33.6 kbps over dial-up circuits
  • Can achieve the above data rate only over
    extremely clean lines (see class handout from
    dbTechnology site)
  • Use a range of adaptive techniques that enable a
    modem to learn and adjust to line conditions.

77
56kbps Modems
  • Asymmetrical can download at 56kbps but upload
    at 33.6kbps only
  • Requires digital T-1 or ISDN PRI connection at
    central site or ISP, single hop between sender
    and receiver
  • Two incompatible systems, no official standard
  • U.S. Robotics (56K x2)
  • Rockwell (56K flex)

78
Digital Encoding of Analog Data
  • Primarily used in retransmission devices
  • The sampling theorem If a signal is sampled at
    regular intervals of time and at a rate higher
    than twice the significant signal frequency, the
    samples contain all the information of the
    original signal.
  • 8000 samples/sec sufficient for 4000hz

79
Converting Samples to Bits
  • Quantizing
  • Similar concept to pixelization
  • Breaks wave into pieces, assigns a value in a
    particular range
  • 8-bit range allows for 256 possible sample levels
  • More bits means greater detail, fewer bits means
    less detail

80
Codec
  • Coder/Decoder
  • Converts analog signals into a digital form and
    converts it back to analog signals
  • Where do we find codecs?
  • Sound cards
  • Scanners
  • Voice mail
  • Video capture/conferencing

81
Digital Encodingof Digital Data
  • Most common, easiest method is different voltage
    levels for the two binary digits
  • Typically, negative1 and positive0
  • Known as NRZ-L, or nonreturn-to-zero level,
    because signal never returns to zero, and the
    voltage during a bit transmission is level

82
Differential NRZ
  • Differential version is NRZI (NRZ, invert on
    ones)
  • Change1, no change0
  • Advantage of differential encoding is that it is
    more reliable to detect a change in polarity than
    it is to accurately detect a specific level

83
Problems With NRZ
  • Difficult to determine where one bit ends and the
    next begins
  • In NRZ-L, long strings of ones and zeroes would
    appear as constant voltage pulses
  • Timing is critical, because any drift results in
    lack of synchronization and incorrect bit values
    being transmitted

84
Biphase Alternatives to NRZ
  • Require at least one transition per bit time, and
    may even have two
  • Modulation rate is greater, so bandwidth
    requirements are higher
  • Advantages
  • Synchronization due to predictable transitions
  • Error detection based on absence of a transition

85
Manchester Code
  • Transition in the middle of each bit period
  • Transition provides clocking and data
  • Low-to-high1 , high-to-low0
  • Used in Ethernet

86
Differential Manchester
  • Midbit transition is only for clocking
  • Transition at beginning of bit period0
  • Transition absent at beginning1
  • Has added advantage of differential encoding
  • Used in token-ring

87
Digital Encoding Illustration
88
Telecommunications Standards
  • Where do they come from?
  • Standard setting bodies
  • Governments
  • Two types
  • Market-driven and voluntary
  • Government-regulated and mandatory

89
Advantages
  • Assures a large market, which encourages mass
    production and often lowers costs
  • Encourages vendors to enter market because
    investment is protected
  • Allows products from multiple vendors to
    communicate, providing consumers with wider
    selection

90
Disadvantages
  • Standards process can freeze technology too
    early, due to the length of the standards-setting
    process and the speed with which technology
    changes
  • Current process allows for multiple standards for
    the same thing

91
Institute of Electrical and Electronics Engineers
(IEEE)
  • The largest professional society in the world
  • Develops standards in the area of electrical
    engineering and computing
  • Publishes scores of journals and runs numerous
    conferences each year
  • e.g. IEEE 802.x network standards

92
American National Standards Institute (ANSI)
  • Non-governmental and nonprofit organization
  • Members are U.S. manufacturers and other interest
    groups
  • Sets a variety of a standards, not just
    computer-related
  • ANSI proposals are usually approved by ISO as
    international standards
  • e.g. 802.x, created by IEEE, approved by ANSI,
    passed on and approved by ISO

93
National Institute of Standards and Technology
(NIST)
  • Formerly known as the National Bureau of
    Standards (NBS)
  • Agency of the U.S. Dept.. of Commerce
  • Issues standards that are mandatory for purchases
    made by the U.S. Government except the Department
    of Defense

94
Industry Associations
  • Electronic Industries Association (EIA)
  • Telecommunication Industry Association (TIA)
  • e.g. EIA-232 (formerly RS-232-C)

95
Intl Telecommunications Union (ITU)
  • Formerly known as Consultative Committee on
    International Telegraph and Telephone (CCITT)
  • Standardize techniques and operations in the
    telecommunications field
  • e.g.
  • CCITT Group 3 Fax
  • CCITT V.x modem standards

96
ISO (International Standards Organization)
  • Founded in 1946
  • Issues standards on a vast number of subjects,
    ranging from nuts and bolts to telephone pole
    coatings
  • Has almost 200 Technical Committees
  • A member of ITU-T

97
Internet Engineering Task Force (IETF)
  • Part of the Internet Architecture Board (IAB)
  • IETF proposes and published Internet RFCs
  • IAB determines which RFCs become standards, based
    on IETF recommendations

98
RFC? Internet Standard
  • Stable and well-understood
  • Technically competent
  • Numerous independent and interoperable
    implementations in operation
  • Significant public support
  • Recognizably useful
  • Differs from other standards processes because of
    the emphasis on operational experience
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