Data and Computer Communications Eighth Edition by William Stallings Lecture slides by Lawrie Brown Chapter 8 – Multiplexing.

Slides:



Advertisements
Similar presentations
Ch. 8 Multiplexing.
Advertisements

Chapter 8 Multiplexing Frequency-Division Multiplexing
Data Communications and Networking
1/28 Chapter 8 Multiplexing. 2/28 Multiplexing  To make efficient use of high-speed telecommunications lines, some form of multiplexing is used  Multiplexing.
Note Bandwidth utilization is the wise use of available bandwidth to achieve specific goals. Efficiency can be achieved by multiplexing; privacy and.
Sistem Broadband Pertemuan 13 Matakuliah: H0122 / Dasar Telekomunikasi Tahun: 2008.
William Stallings Data and Computer Communications 7 th Edition Chapter 8 Multiplexing.
Data and Computer Communications
Chapter 4 Circuit-Switching Networks 4.1 Multiplexing 4.2 SONET Transport Networks Circuit Switches The Telephone Network Signaling Traffic and Overload.
Spring 2006Data Communications, Kwangwoon University9-1 Chapter 9. High-Speed Digital Access 1.DSL Technology 2.Cable Modem 3.SONET.
FIT 1005 Networks & Data Communications Lecture 7 – Multiplexing Reference: Chapter 8 Data and Computer Communications Eighth Edition.
Ch. 8 Multiplexing.
Date Network Support Content 1. Integrated Services Digital Network (ISDN) 2. Asymmetric Digital Subscriber Line (ADSL) 3. X.25 and Frame Relay 4. Asynchronous.
William Stallings Data and Computer Communications 7 th Edition (Selected slides used for lectures at Bina Nusantara University) Multiplexing.
6.1 Chapter 6 Bandwidth Utilization: Multiplexing and Spreading Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
COE 341: Data & Computer Communications (T062) Dr. Marwan Abu-Amara
1 K. Salah Module 3.3: Multiplexing WDM FDM TDM T-1 ADSL.
ECS 152A 6. Multiplexing.
Data Communications Multiplexing.
EIE325: Telecommunication TechnologiesM aciej J. Ogorzałek, PolyU, EIE Telecommunication Technologies Week 10 Interfacing.
Multiplexing 3/9/2009.
Chapter 10: Transmission Efficiency Business Data Communications, 4e.
Multiplexing Lecture 4 Paul Flynn. Multiplexing Frequency Division Multiplexing zFDM zUseful bandwidth of medium exceeds required bandwidth of channel.
CS335 Networking & Network Administration Wednesday, April 14, 2010.
Chapter 8: Multiplexing COE 341: Data & Computer Communications (T061) Dr. Radwan E. Abdel-Aal.
Module 2.2: ADSL, ISDN, SONET
COE 342: Data & Computer Communications (T042) Dr. Marwan Abu-Amara Chapter 8: Multiplexing.
Computer Networks Set 7 Multiplexing.
COE 341: Data & Computer Communications (T061) Dr. Marwan Abu-Amara Chapter 8: Multiplexing.
Digital to analogue conversion. 1 DIGITAL-TO-ANALOG CONVERSION Digital-to-analog conversion is the process of changing one of the characteristics (A,
Technique for assuring that a transmitting entity does not overwhelm a receiving entity with data Necessary when data is being sent faster than it.
Multiplexing multiple links on 1 physical line common on long-haul, high capacity links have FDM, TDM, CDM and WDM.
1 Topic 4: Physical Layer - Chapter 10: Transmission Efficiency Business Data Communications, 4e.
Data and Computer Communications Chapter 8 – Multiplexing
Chapter 17: Data Link Control and Multiplexing
Network Technology CSE3020 Week 5
10/10/ DSL, CM, SONET - Lin 1 CPET/ECET High Speed Access Digital: DSL, Cable Modem, SONET Data Communications and Networking Fall 2004 Professor.
EEL4930University of FloridaFall EEL4930 Computer Networks Dr. George Stallings – Chapter 8 Multiplexing NOTE: Many figures and other materials.
1 William Stallings Data and Computer Communications 7 th Edition Chapter 8 Multiplexing.
Chapter 17: Data Link Control and Multiplexing Business Data Communications, 5e.
Chapter 10: Transmission Efficiency Business Data Communications, 4e.
Chapter 11 - Long-Distance Digital Connection Technologies Introduction Digital telephony Digitizing voice Example Sampling parameters Synchronous communication.
Multiplexing Multiplexing: Combining multiple data (voice) channels for transmission on a common medium. Multiple devices sharing one physical link. Demultiplexing:
CSCI 465 D ata Communications and Networks Lecture 12 Martin van Bommel CSCI 465 Data Communications & Networks 1.
William Stallings Data and Computer Communications 7 th Edition Chapter 8 Multiplexing.
Data and Computer Communications
Physical Layer Dr. Sanjay P. Ahuja, Ph.D. Fidelity National Financial Distinguished Professor of CIS School of Computing, UNF.
1 William Stallings Data and Computer Communications 7 th Edition Chapter 8 Multiplexing.
Komunikasi Data Multiplexing Ir. Hary Nugroho MT..
Data and Computer Communications 8 th & 9 th Edition by William Stallings Chapter 8 – Multiplexing.
TUNALIData Communication1 Chapter 8 Multiplexing.
1 SONET/SDH. 2 T1/E1 Time division multiplexing Allows a link to be utilized simultaneously by many users.
Aegis School of Telecommunication Chapter 8 Multiplexing Telecom Systems I by Dr. M. G. Sharma, Phd. IIT Kharagpur.
Multiplexing Rong Wang CGS3285 Spring Based on Data Communications and Networking, 3rd EditionBehrouz A. Forouzan, © McGraw-Hill Companies, Inc.,
Multiplexing.
Making Connections Efficient: Multiplexing and Compression Data Communications and Computer Networks: A Business User’s Approach Seventh Edition.
Chapter 9. High-Speed Digital Access: DSL, Cable Modems, and SONET
Data and Computer Communications by William Stallings Eighth Edition Networks and Communication Department 1 Multiplexing Click to edit Master subtitle.
Chapter 9 Using Telephone and Cable Networks for Data Transmission.
Chapter 9 Using Telephone and Cable Networks for Data Transmission.
Prof. Reuven Aviv Dept. of Computer Science Computer Networks Improved Usage of Bandwidth.
Bandwidth Utilization: Multiplexing and Spreading
Data and Computer Communications
Data and Computer Communications
William Stallings Data and Computer Communications
CPEG514 Advanced Computer Networks
UNIT I – FRAME RELAY AND ISDN
Chapter 8. Multiplexing Frequency-Division Multiplexing
Multiplexing Networks and Communication Department Chapter 8.
Presentation transcript:

Data and Computer Communications Eighth Edition by William Stallings Lecture slides by Lawrie Brown Chapter 8 – Multiplexing

Multiplexing It was impossible to get a conversation going, everybody was talking too much.   Yogi Berra

Multiplexing  multiple links on 1 physical line  common on long-haul, high capacity, links  have FDM, TDM, STDM alternatives

Frequency Division Multiplexing

FDM System Overview

FDM Voiceband Example

Analog Carrier Systems  long-distance links use an FDM hierarchy  AT&T (USA) and ITU-T (International) variants  Group 12 voice channels (4kHz each) = 48kHz 12 voice channels (4kHz each) = 48kHz in range 60kHz to 108kHz in range 60kHz to 108kHz  Supergroup FDM of 5 group signals supports 60 channels FDM of 5 group signals supports 60 channels on carriers between 420kHz and 612 kHz on carriers between 420kHz and 612 kHz  Mastergroup FDM of 10 supergroups supports 600 channels FDM of 10 supergroups supports 600 channels  so original signal can be modulated many times

Wavelength Division Multiplexing  FDM with multiple beams of light at different freq  carried over optical fiber links commercial systems with 160 channels of 10 Gbps commercial systems with 160 channels of 10 Gbps lab demo of 256 channels 39.8 Gbps lab demo of 256 channels 39.8 Gbps  architecture similar to other FDM systems multiplexer consolidates laser sources (1550nm) for transmission over single fiber multiplexer consolidates laser sources (1550nm) for transmission over single fiber Optical amplifiers amplify all wavelengths Optical amplifiers amplify all wavelengths Demux separates channels at the destination Demux separates channels at the destination  also have Dense Wavelength Division Multiplexing (DWDM)

Synchronous Time Division Multiplexing

TDM System Overview Interleaving at the bit level or in blocks of bytes

TDM Link Control  no headers and trailers  data link control protocols not needed  flow control data rate of multiplexed line is fixed data rate of multiplexed line is fixed if one channel receiver can not receive data, the others must carry on if one channel receiver can not receive data, the others must carry on corresponding source must be quenched corresponding source must be quenched leaving empty slots leaving empty slots  error control errors detected & handled on individual channel errors detected & handled on individual channel

Data Link Control on TDM

Framing  no flag or SYNC chars bracketing TDM frames  must still provide synchronizing mechanism between src and dest clocks  added digit framing one control bit added to each TDM frame one control bit added to each TDM frame identifiable bit pattern used on control channel identifiable bit pattern used on control channel eg. alternating …unlikely on a data channel eg. alternating …unlikely on a data channel compare incoming bit patterns on each channel with known sync pattern compare incoming bit patterns on each channel with known sync pattern

Pulse Stuffing  have problem of synchronizing data sources  with clocks in different sources drifting  also issue of data rates from different sources not related by simple rational number  Pulse Stuffing a common solution have outgoing data rate (excluding framing bits) higher than sum of incoming rates have outgoing data rate (excluding framing bits) higher than sum of incoming rates stuff extra dummy bits or pulses into each incoming signal until it matches local clock stuff extra dummy bits or pulses into each incoming signal until it matches local clock stuffed pulses inserted at fixed locations in frame and removed at demultiplexer stuffed pulses inserted at fixed locations in frame and removed at demultiplexer

TDM Example

Digital Carrier Systems  long-distance links use an TDM hierarchy  AT&T (USA) and ITU-T (International) variants  US system based on DS-1 format  can carry mixed voice and data signals  24 channels used for total data rate 1.544Mbps  each voice channel contains one word of digitized data (PCM, 8000 samples per sec)  same format for 56kbps digital data  can interleave DS-1 channels for higher rates DS-2 is four DS-1 at 6.312Mbps DS-2 is four DS-1 at 6.312Mbps

DS-1 Transmission Format

SONET/SDH  Synchronous Optical Network (ANSI)  Synchronous Digital Hierarchy (ITU-T)  have hierarchy of signal rates Synchronous Transport Signal level 1 (STS-1) or Optical Carrier level 1 (OC-1) is 51.84Mbps Synchronous Transport Signal level 1 (STS-1) or Optical Carrier level 1 (OC-1) is 51.84Mbps carries one DS-3 or multiple (DS1 DS1C DS2) plus ITU-T rates (eg Mbps) carries one DS-3 or multiple (DS1 DS1C DS2) plus ITU-T rates (eg Mbps) multiple STS-1 combine into STS-N signal multiple STS-1 combine into STS-N signal ITU-T lowest rate is Mbps (STM-1) (Synchronous Transport Module) ITU-T lowest rate is Mbps (STM-1) (Synchronous Transport Module)

SONET Frame Format

Statistical TDM  in Synch TDM many slots are wasted  Statistical TDM allocates time slots dynamically based on demand  multiplexer scans input lines and collects data until frame full  line data rate lower than aggregate input line rates  may have problems during peak periods must buffer inputs must buffer inputs

Statistical TDM Frame Format

Cable Modems  dedicate two cable TV channels to data transfer  each channel shared by number of subscribers, using statistical TDM  Downstream cable scheduler delivers data in small packets cable scheduler delivers data in small packets active subscribers share downstream capacity active subscribers share downstream capacity also allocates upstream time slots to subscribers also allocates upstream time slots to subscribers  Upstream user requests timeslots on shared upstream channel user requests timeslots on shared upstream channel Headend scheduler notifies subscriber of slots to use Headend scheduler notifies subscriber of slots to use

Cable Modem Scheme

Asymmetrical Digital Subscriber Line (ADSL)  link between subscriber and network  uses currently installed twisted pair cable  is Asymmetric - bigger downstream than up  uses Frequency division multiplexing reserve lowest 25kHz for voice (POTS) reserve lowest 25kHz for voice (POTS) uses echo cancellation or FDM to give two bands uses echo cancellation or FDM to give two bands  has a range of up to 5.5km

ADSL Channel Configuration

Discrete Multitone (DMT)  multiple carrier signals at different frequencies  divide into 4kHz subchannels  test and use subchannels with better SNR  256 downstream subchannels at 4kHz (60kbps) in theory 15.36Mbps, in practice 1.5-9Mbps in theory 15.36Mbps, in practice 1.5-9Mbps

DMT Transmitter

xDSL  High data rate DSL (HDSL) 2B1Q coding on dual twisted pairs 2B1Q coding on dual twisted pairs up to 2Mbps over 3.7km up to 2Mbps over 3.7km  Single line DSL 2B1Q coding on single twisted pair (residential) with echo cancelling 2B1Q coding on single twisted pair (residential) with echo cancelling up to 2Mbps over 3.7km up to 2Mbps over 3.7km  Very high data rate DSL DMT/QAM for very high data rates DMT/QAM for very high data rates over separate bands for separate services over separate bands for separate services

Summary  looked at multiplexing multiple channels on a single link  FDM  TDM  Statistical TDM  ADSL and xDSL