TDM and WDM - PowerPoint PPT Presentation

1 / 26
About This Presentation
Title:

TDM and WDM

Description:

TDM and WDM Time Division Multiplexing Type of digital or (rarely) analog multiplexing in which two or more signals or bit streams are transferred apparently ... – PowerPoint PPT presentation

Number of Views:449
Avg rating:3.0/5.0
Slides: 27
Provided by: markandey
Category:
Tags: tdm | wdm | beam | laser | welding

less

Transcript and Presenter's Notes

Title: TDM and WDM


1
TDM and WDM
2
Time Division Multiplexing
  • Type of digital or (rarely) analog multiplexing
    in which two or more signals or bit streams are
    transferred apparently simultaneously as
    sub-channels in one communication channel
  • The time domain is divided into several recurrent
    timeslots of fixed length, one for each
    sub-channel.
  • A sample byte or data block of sub-channel 1 is
    transmitted during timeslot 1, sub-channel 2
    during timeslot 2, etc.

3
Technology Trends TDM,DWDM
Optical
Electrical
Time Division Multiplexing (TDM)
Optical
Electrical
Dense Wavelength Division Multiplexing (DWDM)
4
Transmission using TDM
  • In circuit switched networks such as the public
    switched telephone network (PSTN) there exists
    the need to transmit multiple subscribers calls
    along the same transmission medium.
  • TDM allows switches to create channels, also
    known as tributaries, within a transmission
    stream.
  • A standard DS0 voice signal has a data bit rate
    of 64 kbit/s, determined using Nyquists sampling
    criterion.
  • TDM takes frames of the voice signals and
    multiplexes them into a TDM frame which runs at a
    higher bandwidth.
  • If the TDM frame consists of n voice frames, the
    bandwidth will be n64 kbit/s.
  • Each voice sample timeslot in the TDM frame is
    called a channel

5
Transmission using TDM
  • In European systems, TDM frames contain 30
    digital voice channels.(2.048 Mbps )
  • In American systems, TDM frames contain 24
    channels.(1.544 Mbps)
  • Both standards also contain extra bits (or bit
    timeslots) for signalling and synchronization
    bits.
  • Multiplexing more than 24 or 30 digital voice
    channels is called higher order multiplexing.
  • Higher order multiplexing is accomplished by
    multiplexing the standard TDM frames.
  • For example, a European 120 channel TDM frame is
    formed by multiplexing four standard 30 channel
    TDM frames.
  • At each higher order multiplex, four TDM frames
    from the immediate lower order are combined,
    creating multiplexes with a bandwidth of n x 64
    kbit/s, where n 120, 480, 1920, etc.

6
T1 Frame
7
E1 Frame
8
Digital transmission hierarchy
9
North American Digital Hierarchy
European Digital Hierarchy
10
(No Transcript)
11
SONET/SDH hierarchy.
Optical Carrier SONET/SDH Signal Bit Rate Capacity
OC-1 STS-1 51.84 Mbps 28 DS1s or 1 DS3
OC-3 STS-3/STM-1 155.52 Mbps 84 DS1s or 3 DS3s
OC-12 STS-12/STM-4 622.08 Mbps 336 DS1s or 12 DS3s
OC-48 STS-48/STM-16 2488.32 Mbps 1344 DS1s or 48 DS3s
OC-192 STS-192/STM-64 9953.28 Mbps 5379 DS1s or 192 DS3s
12
SONET/SDH
  • SDH also performs some switching functions
  • SDH Crossconnect
  • The SDH Crossconnect is the SDH version of a
    Time-Space-Time crosspoint switch.
  • It connects any channel on any of its inputs to
    any channel on any of its outputs.
  • SDH Add-Drop Multiplexer
  • The SDH Add-Drop Multiplexer (ADM) can add or
    remove any multiplexed frame down to 1.544Mb.

13
TDM
  • Synchronous time division multiplexing
  • Uses fixed time slots
  • Asynchronous/Statistical time division
    multiplexing
  • Logically distribute bandwidth

14
Statistical TDM
  • STDM allows bandwidth to be split over 1 line.
  • Many college and corporate campuses use this type
    of TDM to logically distribute bandwidth.
  • A more common use however is to only grant the
    bandwidth when it is needed.
  • STDM does not reserve a time slot for each
    terminal, rather it assigns a slot when the
    terminal is requiring data to be sent or
    received.
  • This is also called asynchronous time-division
    multiplexing(ATDM)

15
Why WDM
  • SDH network functions are connected using
    high-speed optic fibre.
  • Optic fibre uses light pulses to transmit data
    and is therefore extremely fast.
  • Modern optic fibre transmission makes use of
    Wavelength Division Multiplexing (WDM) where
    signals transmitted across the fibre are
    transmitted at different wavelengths, creating
    additional channels for transmission.
  • This increases the speed and capacity of the
    link, which in turn reduces both unit and total
    costs

16
Why WDM?
  • Capacity upgrade of existing fiber networks
    (without adding fibers)
  • Transparency Each optical channel can carry any
    transmission format (different asynchronous bit
    rates, analog or digital)
  • Scalability Buy and install equipment for
    additional demand as needed
  • Wavelength routing and switching Wavelength is
    used as another dimension to time and space

17
(No Transcript)
18
Active Components Tunable Optical Filters,
Tunable Sources, Optical Amplifiers Passive
Components require no external control for their
operation, so have limited applicaiton
Typical WDM Link using a
variety of passive and active devices.
19
WDM, CWDM and DWDM
  • WDM technology uses multiple wavelengths to
    transmit information over a single fiber
  • Coarse WDM (CWDM) has wider channel spacing (20
    nm) low cost
  • Dense WDM (DWDM) has dense channel spacing (0.8
    nm) which allows simultaneous transmission of 16
    wavelengths high capacity

20
WDM
  • WDM SYSTEM

21
WDM SYSTEMS
  • Four kinds of WDM systems are available
  • Metro WDM (lt200 km)
  • Long-haul or regional WDM (200 km to 800 km)
  • Extended long-haul WDM (800 km to 2000 km)
  • Ultra-long-haul WDM (gt2000 km)

22
Coarse Wavelength-Division Multiplexing
  • The short-haul transport of data, voice, video,
    storage, and multimedia services
  • CWDM systems use lasers that have a bit rate of
    up to 2.5 Gbps (OC-48/STM-16) and can multiplex
    up to 18 wavelengths. This provides a maximum of
    45 Gbps over a single fiber.
  • Channel spacing of 20 nm or 2500 GHz as specified
    by the ITU standard G.694.2( 1270 nm to 1610 nm)

23
Dense Wavelength-Division Multiplexing
  • Metro or long-haul core where capacity demands
    are extremely high.
  • Typical DWDM systems use lasers that have a bit
    rate of up to 10 Gbps (OC-192/STM-64) and can
    multiplex up to 240 wavelengths. This provides a
    maximum of 2.4 Tbps over a single fiber.
  • Uses 100-GHz or 200-GHz frequency spacing.
  • ITU grid DWDM products operate in the C-band
    between 1530 and 1565 nm or L-band between 1565
    and 1625 nm

24
Optical frequency bands used with various WDM
systems
  • O-band (original) A range from 1260 nm to 1360
    nm
  • E-band (extended) A range from 1360 nm to 1460
    nm
  • S-band (short wavelength) A range from 1460 nm
    to 1530 nm
  • C-band (conventional) A range from 1530 nm to
    1565 nm
  • L-band (long wavelength) A range from 1565 nm to
    1625 nm
  • U-band (ultra-long wavelength) A range from 1625
    nm to 1675 nm

25
(No Transcript)
26
Applications
  • Consumer equipment Barcode scanner, printer,
    CD/DVD/, remote control devices
  • Telecommunications Optical fiber communications,
    Optical Down converter to Microwave
  • Medicine Correction of poor eyesight, laser
    surgery, surgical endoscopy, tattoo removal
  • Industrial manufacturing The use of lasers for
    welding, drilling, cutting, and various methods
    of surface modification
  • Construction Laser leveling, laser range
    finding, smart structures
  • Aviation
  • Military IR sensors, command and control,
    navigation, search and rescue, mine laying and
    detection
  • Entertainment Laser shows, beam effects
  • Information processing
  • Metrology Time and frequency measurements, range
    finding
  • Photonic computing clock distribution and
    communication between computers, circuit boards,
    optoelectronic integrated circuits
Write a Comment
User Comments (0)
About PowerShow.com