Telecommunication Network - PowerPoint PPT Presentation

1 / 62
About This Presentation
Title:

Telecommunication Network

Description:

Univ of Strathclyde (Electronics & Electrical) ,UK, 1985 ... Dialing system: decadic and DTMF. Subscriber and group switching. Analog and digital switching. ... – PowerPoint PPT presentation

Number of Views:1511
Avg rating:5.0/5.0
Slides: 63
Provided by: michael347
Category:

less

Transcript and Presenter's Notes

Title: Telecommunication Network


1
TelecommunicationNetwork
  • Course Details
  • Semester 1, 2006

2
Prof. Madya Dr Mahamod Ismail
  • Lecturer in UKM since 1987.
  • Diploma - UTM (Electrical Communication), 1981
  • BSc. Univ of Strathclyde (Electronics
    Electrical) ,UK, 1985
  • MSc UMIST, Manchester (Communication Eng.
    Digital Electronics), 1987
  • PhD Univ of Bradford, Mobile Communication,
    1996
  • Research Area Mobile Communication Wireless
    Networking
  • Team Engineer, Tiungsat, 1997-98, Uni. of Surrey,
    U.K.
  • Guest Professor, University Duisburg Essen,
    Germany , 2002
  • Currently Coordinator UKM Mercator Office, Fac.
    of Eng. UKM
  • Email mahamod_at_eng.ukm.my, dr_mbi_at_yahoo.com
  • Telephone 019-3275425, 03-89216191/6322

3
Syllabus Program Booklet
KT6123 TELECOMMUNICATION NETWORK Switching
system engineering Types of public switched
network. Switching system circuit, store and
forward, packet. Numbering, routing system and
charging. Subscriber function. Telephone system
basic requirement. Telephone equipment
characteristics. Local circuit and hybrid
transformation. Dialing system decadic and DTMF.
Subscriber and group switching. Analog and
digital switching. Switching Strowger, cross-bar
and time and space. Digital analysis. Controlling
sections. Stored Programmable Controlled
exchange. Signaling subscriber, line and
register. Transmission system FDM and PCM 30/32
channel. CCITT, CCIR function in switching
planning. Digital Network ISDN, SDH. Teletraffic
Engineering telephone traffic performance.
Teletraffic and queuing theory. Delay and loss
system, Grade of service. Erlang and Bernoulli
distribution. Broadband network ATM and B-ISDN.
Intelligent network.
4
Course Outline
  • Introduction
  • Transmission
  • Multiplexing and Hierarchy
  • Switching
  • Telecommunication Traffics
  • Switching Network
  • Signaling
  • Services

5
References
1. J.E.Flood, Telecommunications Switching,
Traffic and Networks, Prentice Hall, 1994 2. E.H.
Jolley, Introduction to Telephony and Teleplay,
Pittman Publication. 3. Schwartz, M.,
Telecommunication Networks Protocols, Modelling
Analysis, Addison-Wesley 4. Clarke, M.P., Network
Telecommunications Design Operation, Wiley
6
Evaluation
  • 2 Assignments 30
  • Midterm exam 20
  • Quiz 10
  • Final exam 40

7
Assignment 1
  • Report
  • Format 1
  • Content 5
  • Discussion/Conclusion 2
  • References 2
  • Presentation 5

8
TelecommunicationNetwork
  • Introduction
  • Semester 1, 2006

9
Introduction
  • Tele/communications
  • The process of transmitting a message between two
    remote locations.
  • Message - could be Voice, Music, Textual,
    Pictorial (graph, diagram, image, etc.) or moving
    image (video).
  • Recently we have a better proportion of data
    communications links and speech is being
    converted into digital forms as well as data
    will eventually be conveyed more naturally in
    these digital forms.
  • The purpose of telecommunications is to convey
    information from one location to another.
  • Data Precise communication
  • Voice More convenient to convey information,
    thats why voice communication has predominated
    for over a century
  • The telephone network, until the last decade, was
    almost entirely analog

10
Introduction
11
Introduction
  • Broadband
  • is a technique where the data to be transmitted
    is sent using a carrier signal, such as a
    sinusoidal wave. Many different frequency
    carrier signal can be transmitted simultaneously,
    more than one signal can be sent on the same
    wire.
  • Baseband
  • a single data signal is transmitted directly on a
    wire. The data is transmitted directly on the
    wire using positive and negative voltages.
    RS-232 interface is an example of baseband
    transmission.
  • A baseband signal
  • is an information signal that has not undergone
    the modulation process.
  • represents voice, data, or video information
    signal.
  • must be band-limited before being used to
    modulate a carrier signal.

12
Introduction
  • When data (or any other signal) is to be conveyed
    outside ones place, this involves the modulation
    of the broadband signal onto a carrier frequency,
    either by
  • Amplitude Shift Keying (ASK)
  • Frequency Shift Keying (FSK)
  • Phase Shift Keying (PSK)
  • or Combination of the ASK and PSK (QPSK, ?/4-PSK,
    DQPSK)
  • In baseband signal recently, speech is being
    conveyed by Pulse Code Modulation (PCM)
  • The standard digital voice channel that available
    in today has a capacity of 64 Kbps, or a
    multiplexed of 1.544Mbps T1, 2.048Mbps E1

13
Telecommunication System
Input Transducer Encoder Modulator Amplifier
Air, Free Space Copper Cable Optical Fiber
Output Transducer Decoder Demodulator Amplifier
14
Telecommunication System
Information signal output
Information signal input
Encoder
Decoder
Modulator/ Transmitter
Demodulator/ Receiver
Transmission Channel
Free-space loss Reflection Refraction scattering M
ultipath Diffraction Shadowing Noise Interference
15
Telecommunication System
  • Transducer transform one form of Energy into
    another
  • eg. Sound Electrical
  • Transmitter amplifies and processes the
    electrical replica of message for transmission
  • Receiver amplifies and processes the received
    elctrical signal in reverse manner to recover the
    original message
  • Transmission Channel a path connecting
    Transmitter Tx to Receiver Rx, which is
    characterized by attenuation
  • Factors involve in a communication system
  • Type of information (data, text, graphic, voice,
    music, multimedia, etc.)
  • Information format (analog, discrete, digital,
    random, deterministic, periodic etc.)
  • Transmission speed (low, medium, high, etc.)
  • Transmission medium (wired, wireless)
  • Transmission distance (short, medium, long)
  • Modulation techniques (AM, PM, ASK, PSK, GMSK,
    PCM, OFDM, etc.)
  • Error control (BCD, Gray, Morse, ASCII, FEC,
    cyclic, etc.)

16
Telecommunication System
17
Transmission Mode
  • Simplex transmission
  • Only one way communication
  • Half duplex transmission
  • Two ways communication, but one at a time not
    simultaneously
  • Full duplex transmission
  • Simultaneously in both directions
  • Unicast, Multicast, Anycast, Broadcast

18
Half Duplex versus Full-Duplex
19
Modes of transmission
  • Asynchronous
  • Each character is considered a unit of
    information
  • All timing and error checking is included within
    it
  • Synchronous
  • Information is sent as a block of data
  • Control and error checking information is added
    to each block

20
Asynchronous versus Synchronous
21
Asynchronous Transmission
  • Each character is sent independent of the next
    (or previous character sent)
  • Before each character is a START bit
  • Time between each character is not constant
  • Requires control bits for each character sent
    (for error checking)
  • At the end of each character is a STOP bit
  • At least 3 of 9 bits (for a 7 bit code) sent are
    not information but overhead. Hence this is
    inefficient

22
Synchronous Transmission
  • Information is transmitted in a block of bits
  • Each block is preceded by a sequence of bits
    called a preamble
  • Each block ends with a sequence of bits called a
    postamble
  • Control bits are added to allow error checking
  • The data plus preamble plus postamble plus
    control information is called a Frame.
  • Much more efficient as compared to Asynchronous
    transmission
  • More complex and expensive to implement than
    Asynchronous

23
Serial versus Parallel Transmission
  • Serial mode
  • Message is sent one bit at a time
  • Parallel mode
  • Each character is sent over
  • a different wire, simultaneously
  • The size of messages depends on its context
  • Credit card authorization 1000 bits
  • One page typed memo 15000 bits
  • One second of digital voice 56000 bits
  • One second of Full motion video 100 million bits

24
Transmission Topology
25
Transmission Topology
26
Transmission Topology
As the area covered by a star network and the
number of stations served by it grow, line costs
increase and it then economic to divide the
network into several smaller network served by
its own exchange
27
PSTN Topology
28
PSTN
  • Transmission links/nodes
  • Customer nodes
  • Switching nodes
  • Transmission nodes
  • Service nodes
  • Subsystem
  • Transmission systems
  • Switching systems
  • Signalling system

29
Telecommunication Standard
30
Telecommunication Network
  • Bearer Service
  • provides a "transport system" for
    exchanging information
  • Tele-services
  • complete
  • includes functions for connection, and a
    uniform "language" for communication and for
    shaping the messages conveyed
  • Example two telephones talk to each
  • other via telephone
    network
  • Also, Voice/Data/Text/Image etc

31
Typical Network Services
  • PSTN(Public Switched Telephone Network)
  • PLMN(Public Land Mobile Network)
  • PSPDN(Packet Switched Public Data Network)
  • ISDN(Integrated Services Digital Network)
  • Frame Relay
  • Signaling Network(CAS/CCS)
  • Internet
  • IN(Intelligence Network)

32
Network Services
Teleservices depend on particular terminal
apparatus e.g. telephone, teleprinter Bearer
Services transmission capacity that can be used
for any desired function e.g. private circuit
33
Network Services
34
More About WANs
  • Virtual private networks (VPNs)
  • A private network configured within a public
    network
  • Can be built on top of the Internet
  • Service offered by the telephone companies and
    ISPs

35
  • Value added networks (VANs)
  • Public data networks that add value by
    transmitting data and by providing access to
    commercial databases and software
  • Use packet switching
  • Subscription based
  • Often used in electronic data interchange (EDI)
    systems

36
  • Public switched data network technologies (PSDN)
  • Data flows through a public network managed by a
    telecommunications carrier
  • Most common technologies
  • ISDN (integrated service digital network)
  • X.25
  • Frame relay
  • Asynchronous transfer mode (ATM)

37
(example of Frequency Modulation)
38
ASK/FSK/PSK
39
Sending Multiple Bits Simultaneously
  • Each of the three modulation techniques can be
    refined to send more than one bit at a time. It
    is possible to send two bits on one wave by
    defining four different amplitudes.
  • This technique could be further refined to send
    three bits at the same time by defining 8
    different amplitude levels or four bits by
    defining 16, etc. The same approach can be used
    for frequency and phase modulation.

40
Sending Multiple Bits Simultaneously
41
Hybrid Amplitude and Phase modulation
  • QAM Quadrature Amplitude Modulation
  • represents 4 bits per baud (I.e. V 16)

90o
8 phase changes 2 different amplitude
levels Therefore V 16
135o
45o
0o
180o
315o
225o
Used in ITU V.32 modems
270o
42
Digital Encoding of Analog Signals (PCM)
  • Concept
  • Take samples of analog signal. To each sample -
    assign a code. Then transmit that code (digital
    signal).
  • If we sample at the rate of twice the bandwidth
    of the channel then the resulting digital signal
    contains all the information in the original
    analog signal - Nyquists theorem (1924)

43
PCM - Pulse Code Modulation
Samples
time
Each is assigned a n bit binary code
44
PCM
  • Transmitting an analog signal over a digital
    network (eg. Voice on telephone n/w)
  • Each signal is sampled 8000 times per second
  • Each sample is converted to a 7 bit code
  • 1 bit is added for control information
  • there are 128 different such codes (27)
  • The digital signal is then transmitted at 64,000
    64 Kbps 88000

45
Differential PCM
  • Voice signals do not change extremely rapidly
  • Changes of more than /- 16 levels between
    samples is very rare
  • Hence use just 5 bits instead of 7 to represent
    each sample
  • If signal jumps very widely then several samples
    are needed to catch up

46
Delta Modulation
  • Voice signals do not change very rapidly
  • Transmit only one bit at each sample (indicating
    a 1 or -1) to indicate whether the signal is
    increasing or decreasing.
  • Amplitude of next sample differs from previous
    one by 1 unit (either 1 or -1).
  • If very rapid changes take place then the coding
    takes a while to catch up

47
Problems (Delta Modulation)
Samples cannot keep up with rapidly changing
signal
time
48
Predictive Encoding
  • Both sender and receiver extrapolate from the
    last few values received to predict what the next
    value would be.
  • The transmitter sends a value only if it were
    different from what is predicted

49
Data transfer in the presence of noise
  • Shannons Law
  • C B log2 (1 S/N) where
  • C achievable channel capacity
  • B Bandwidth of line (in Hz)
  • S Average signal power
  • N Average Noise power
  • S/N Signal to Noise Ratio
  • this is usually measured in decibels (dB)
  • where dB 10 log10 (S/N)

50
Telephone Channel Capacity
Voice Channel 0-4,000 Hz
Voice Bandwidth 300-3,300 Hz
Voltage
Guard Band
Guard Band
0
300
3,300
4,000
Frequency (Hertz)
51
  • Example Channel capacity of a telephone line
    (voice grade)
  • typical signal to noise ratio of a voice grade
    line
  • 30 decibels
  • i.e. 30 10 log10(S/N) gt S/N 1000
  • Bandwidth 3000 Hz
  • Thus C 3000 log2 (11000)
  • C 30, 894 bits per second 30 Kbps (approx)
  • This is the extreme limit though, hardly ever
    reached since ideal conditions are not present.

52
Converting Voice (analog) to digital
  • Use PCM
  • Sample 8000 times in each second
  • Time between each sample 1/8000 125 micro
    seconds (not perceptible to the human ear)
  • Voice signals lie between 300 - 3300 Hz hence we
    are sampling at twice the frequency
  • What does Nyquists theorem imply ?

53
Data Encoding
  • Data needs to be encoded in a format that
    computers can understand
  • ASCII (8 bits), 128 characters, 1 bit used for
    error detection
  • EBCDIC (8 bits), 256 characters
  • Baudot (5 bits)

54
Digital Signal Encoding
55
Transmitting Data
  • In order for data to be transmitted and received
    in a legible form
  • The receiver must know where
  • a character starts
  • a character ends
  • in the stream of bits that is received from a
    transmitter

56
  • Flow Control
  • Hardware flow control RTS/CTS
  • Software flow control XON/XOFF

57
Flow Control
  • Necessary when data is being sent faster than it
    can be processed by receiver
  • Computer to printer is typical setting
  • Can also be from computer to computer, when a
    processing program is limited in capacity

58
Stop-and-Wait Flow Control
  • Simplest form
  • Source may not send new frame until receiver
    acknowledges the frame already sent
  • Very inefficient, especially when a single
    message is broken into separate frames

59
Stop-and-Wait Flow Control
60
Basic data communications H/W
  • Modem - MOdulator/DEModulator
  • used to convert digital signals from a computer
    to analog signals via modulation so as to
    transmit over telephone networks

Old modem (voice-graded telephone line) - ASK
Modern modem FSKSophisticated modem - PSK
61
Modem Standards
  • V.22bis
  • transmission rate 2400 bps
  • baud rate 600 bauds
  • data compression V.42bis
  • Error correction V.42
  • Modulation method 4QAM and TCM

62
Modem Standards
  • V.32
  • transmission rate 9.6 Kbps
  • Baud rate 2400 bauds
  • Data compression/error correction same
  • Modulation method 4QAM and TCM
  • V.32bis
  • same as above except uses 6QAM and TCM
Write a Comment
User Comments (0)
About PowerShow.com