pdh
TRANSCRIPT
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Multiplexing.
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Used when the total medium transmission capacity exceeds the channel’s one. Channels are multiplexed for a better use of medium. Useful for long-haul communications; trunks are fiber, coaxial, microwave high capacity links. Higher data rate transmission Better cost-effective transmissions for a given application over a given distance.
Multiplexing
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Under the simplest conditions, a medium can carry only one signal at any moment in time.
For multiple signals to share one medium, the medium must somehow be divided, giving each signal a portion of the total bandwidth.
The current techniques that can accomplish this include time division multiplexing, frequency division multiplexing, and wavelength division multiplexing.
Multiplexing (Conti…)
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Techniques
TDM : Time Division MultiplexingTime Division Multiplexing
synchronous
statistical
FDM : Frequency Division MultiplexingFrequency Division Multiplexing
WDM : Wavelength Division MultiplexingWavelength Division Multiplexing – for optical transmissions
CDM : Code Division Multiplexing
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Time Division Multiplexing Sharing of the signal is accomplished by dividing available transmission time on a medium among users.
Digital signaling is used exclusively.
Time division multiplexing comes in two basic forms:
1. Synchronous time division multiplexing, and
2. Statistical, or asynchronous time division multiplexing.
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Synchronous Time Division Multiplexing
The original time division multiplexing.
The multiplexer accepts input from attached devices in a round-robin fashion and transmit the data in a never ending pattern.
T-1 and ISDN telephone lines are common examples of synchronous time division multiplexing.
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Synchronous Time Division Multiplexing (Conti….)
If one device generates data at a faster rate than other devices, then the multiplexer must either sample the incoming data stream from that device more often than it samples the other devices, or buffer the faster incoming stream.
If a device has nothing to transmit, the multiplexer must still insert a piece of data from that device into the multiplexed stream.
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Statistical Time Division Multiplexing
A statistical multiplexer transmits only the data from active workstations.
If a workstation is not active, no space is wasted on the multiplexed stream.
A statistical multiplexer accepts the incoming data streams and creates a frame containing only the data to be transmitted.
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Frequency Division Multiplexing (FDM)
A number of signals carried simultaneously, each signal modulated onto a different carrier frequency, which are separated for avoiding signals bandwidths to overlap (use of guard bands).
Input signals are analog or digital, converted to analog, multiplexed onto an analog composite signal.
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Frequency Division Multiplexing (conti..)
Assignment of non-overlapping frequency ranges to each “user” or signal on a medium. Thus, all signals are transmitted at the same time, each using different frequencies.
A multiplexer accepts inputs and assigns frequencies to each device.
The multiplexer is attached to a high-speed communications line.
A corresponding multiplexer, or demultiplexer, is on the end of the high-speed line and separates the multiplexed signals.
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Wavelength Division Multiplexing Wavelength division multiplexing multiplexes multiple data streams onto a single fiber optic line.
Different lasers transmit multiple signals at different wavelengths.
Each signal carried on the fiber can be transmitted at a different rate from the other signals.
Dense wavelength division multiplexing combines many wavelengths (30, 40, 50, 60, more?) onto one fiber.
Coarse wavelength division multiplexing combines only a few wavelengths.
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Code Division MultiplexingCode Division Multiplexing
CDM allows signals from a series of independent sources to be transmitted at the same time over the same frequency band.
This is accomplished by using orthogonal codes to spread each signal over a large, common frequency band.
The technique used is Spread Spectrum
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PLESIOCHRONOUS DIGITAL HIERARCHY
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IntroductionIntroduction
• Plesiochronous is a Greek word meaning Plesiochronous is a Greek word meaning Almost Almost SynchronousSynchronous , but not fully synchronous. , but not fully synchronous.
• In Plesiochronous system every equipment is generating In Plesiochronous system every equipment is generating its own clock for synchronization.its own clock for synchronization.
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Generation Of PCM Signal(Digital Signal)
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DS0 Signal Derivation DS0 Signal Derivation
PCM Line SamplingPCM Line Sampling
Each sample is 8 bits wide: the resulting signal rate will be8 bits x 8,000 samples/second = 64,000 bits/second, hence
• Sampling rate = 8,000 samples/second – how?
• Nyquist Theorem: sampling rate = 2 x highest audible frequency (4,000 Hz)
2 x 4,000 = 8,000 samples/second
1 DS0 = 64 Kb/s1 DS0 = 64 Kb/s1 DS0 = 64 Kb/s1 DS0 = 64 Kb/s
Analog Signal
tt
fftt
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PDH Bit RatesPDH Bit Rates
North AmericaEurope Japan
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DS1 FrameDS1 Frame
FF CH 1CH 1 CH 2CH 2 CH 19CH 19 CH 20CH 20 CH 21CH 21 CH 22CH 22 CH 23CH 23 CH 24CH 24
192 Bits of Encoded Voice (24 Channels)192 Bits of Encoded Voice (24 Channels)FramingFramingBitBit
Total bits per DS1 frame = 192 + 1 = 193 bitsTotal bits per DS1 frame = 192 + 1 = 193 bitsSampling rate = 8,000 samples/secondSampling rate = 8,000 samples/second
DS1 RateDS1 Rate = 193 bits x 8,000 samples/second = 193 bits x 8,000 samples/second = = 1.544 Mb/s1.544 Mb/s
DS1Signal DerivationDS1Signal Derivation
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DS3 SignalDS3 Signal
Higher Rate signal
1 DS3 = 28 DS1s / 672 DS0s
Line Rate
1 DS3 = 28 * (Line rate of DS1s) + overhead and framing bits
= 44.736 Mbps
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LevelLevel
VF(DS0)DS1DS1CDS2DS3Proprietary
64 Kb/s1.544 Mb/s3.152 Mb/s6.312 Mb/s
44.736 Mb/s~ 565 Mb/s
Line RateLine Rate CapacityCapacity
1 voice circuit24 voice circuits2 x DS1 = 48 VF4 x DS1 = 96 VF
28 x DS1 = 672 VF12 x DS3 = 8,064 VF
Physical MediaPhysical Media
Copper wireCopper wireCopper (screened)Copper, µwave, fiberµwave, fiberSingle-mode fiber
North American HierarchyNorth American Hierarchy
Hierarchy breaks down above the DS3 level
Asynchronous bit-stuffing penalties mount
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OC-11
OC-n1
x n
Is equivalent to
Electrical (sync) Optical (sync)
STS-11
x n
STS-n1
DS11 VT1.5/C111
DS31 STS-1/C31
x 28 x 28
Maps into
Maps into
Asynchronous Synchronous (SONET/SDH)
Is equivalent to
Signal EquivalenceSignal Equivalence
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Async. - HierarchyAsync. - Hierarchy
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Bit StuffingBit Stuffing
Pleisochronous MultiplexingPleisochronous Multiplexing
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HIGHER ORDER MUX
MUX
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Bit-Interleaved Multiplexing Bit-Interleaved Multiplexing
•It is TDM
•One bit will be taken from all Tributaries.
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TYPICAL OPTICAL LINK• PDH
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o TERMINAL EQUIPMENT
MUX
OLTE
o REGENERATOR
PDH NETWORK ELEMENTS
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U-Links
AlarmsAlarms
Switch
PWR & ALM Unit
Channel Unit
Interface Unit
MUX
MUX BLOCK (INSTALLED IN THE MUX RACK)
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2 Mbps
M13 MUX2 Mbps
2 Mbps
2 Mbps
34 Mbps
JUMP MUX
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Laser Shut Off
Laser ON
Error Major
Error Minor
LSOD LOF
LOS
AIS
Power On(Green always)
Error major
Error Minor
Optical Adapter
Switch
Alarm Monitor
Power & Alarm Unit
Tx Unit Rx Unit
OLTE(Optical Line Terminating Equipment)
(INSTALLED IN THE OLTE RACK)OLTE BLOCK
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COMPRISES OF MUX & OPTICAL UNITS
OPTIMUX
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(ACCOMODATES BOTH - OLTE & MUX) MIX RACK
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REG RACK
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Limitations Of PDHLimitations Of PDH
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PDH Frame start
start
start
start
start
Identifying exact location of frame is difficult.
LimitationsLimitations
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Multiplexing / Demultiplexing is time consuming
Limitations (contd..)Limitations (contd..)
140 Mbit/s
34 Mbit/s
565Mbit/s
8 Mbit/s
2 Mbit/s
140-
565
MU
X &
LTE
140-
565
MU
X &
LTE
34-1
40 M
UX
34-1
40 M
UX
8-34
MU
X
8-34
MU
X
2-8
MU
X
2-8
MU
X
Drop & Add
Pdh.exe
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SDH Transport SystemsSDH Transport Systems
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Synchronous Digital Hierarchy-The work Synchronous Digital Hierarchy-The work House of Telecommunication House of Telecommunication
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SYNCHRONIZATION OF DIGITAL SIGNAL :SYNCHRONIZATION OF DIGITAL SIGNAL :
In a set of Synchronous signals, the digital transitions in the signals occur at exactly the same rate. There may be a phase difference between the transitions of the two signals, and this would lie on specified limits.
In a synchronous network, all the clocks are traceable to one primary reference clock (PRC). The accuracy of the PRC is better than 0.1 in 1011 and is derived from a cesium atomic standard.
SYNCHRONOUS SIGNAL:
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SYNCHRONIZATION OF DIGITAL SIGNAL :SYNCHRONIZATION OF DIGITAL SIGNAL :
ASYNCHRONOUS SIGNAL:If two digital signals are Asynchronous then their transitions
occur at “entirely” different rate.
The two digital signals are out of phase
Which implies that all the digital signals are not synchronized to a common clock
If two digital signals are plesiochoronous then their transitions occur at “almost” the same rate, with any variation being constrained within tight limits. Although this clocks are extremely accurate, there is a difference between one clock and the other.
PLESIOCHRONOUS SIGNAL:
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Requirement Of Synchronous Digital Hierarchy ( SDH )Requirement Of Synchronous Digital Hierarchy ( SDH )
Need for extensive network management capability within the hierarchy.
Standard interfaces between equipment.
Need for inter-working between north American and European systems.
Facilities to add or drop tributaries directly from a high speed signal.
Standardization of equipment management process.
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Typical Example of SDH SystemTypical Example of SDH System
622.08Mbit/sSTM-4
155.52Mbit/sSTM-1
Bit RateSDH
STM-16STM-16 2488.32Mbit/s
STM-64 9957.28Mbit/s
Product
TN-1X
TN-4XE
TN-16X
TN-64X
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The Network Elements of SDH Network :
Regenerator (Reg.)
Terminal Multiplexer (TM)
Add/Drop Multiplexer (ADM)
Digital Cross Connect (DXC)
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STM-NSTM-N STM-NSTM-NRegeneratorRegenerator
Regenerator (Reg.)
It regenerates the clock and amplifies the incoming distorted and attenuated signal.
It derive the clock signal from the incoming data stream.
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RegeneratorRegenerator
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Terminal Terminal MultiplexerMultiplexer
STM-NSTM-NPDHPDHSDHSDH
Terminal Multiplexer (TM)
It combines the Plesionchronous and synchronous input signals into higher bit rate STM-N Signal.
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Terminal MultiplexerTerminal Multiplexer
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Add/Drop Multiplexer (ADM)
STM-NSTM-NSTM-NSTM-N
PDHPDH SDHSDH
Add / Drop Add / Drop MultiplexerMultiplexer
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Add/Drop MultiplexerAdd/Drop Multiplexer
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Extraction from & insertion into high speed SDH bit streams of Plesiochronous and lower bit rate synchronous signal.
ADM makes possibilities of
Ring structure of network which provides the advantage of automatic back-up path switching in the event of fault.
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STM-16STM-4STM-1
140 Mbit/s34 Mbit/s2 Mbit/s
STM-16STM-4STM-1
140 Mbit/s34 Mbit/s2 Mbit/s
Cross - Connect
Digital Cross Connect (DXC)
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Digital Cross Connect (DXC)
Digital Cross Connect:
A digital cross connect is an equipment which has the capability of interconnecting tributaries
An Agg to Agg connection, a trib to aggregate connection and a tributary to tributary connection is also possible in case of a Digital Cross Connect
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PDHATMIP
SDHSDHmultiplexermultiplexer
SDHSDH RegeneratorRegenerator
##Cross-Cross-
connectconnect
SDHSDHmultiplexermultiplexerSDH SDH SDH
PDHATMIP
Regenerator Section
Regenerator Section
Multiplex Section Multiplex Section
Path
TYPICAL LAYOUT OF SDH LAYER
General view of Path Section designations