Unit-2_Multiplexing.pdf

Transcript

What is Multiplexing?
Multiplexing is a technique used to combine and send multiple data streams over a single medium.
The process of combining the data streams is known as multiplexing and hardware used for
multiplexing is known as a multiplexer.

Multiplexing is achieved by using a device called a Multiplexer (MUX) that combines n input
lines to generate a single output line. Multiplexing follows many-to-one, i.e., n input lines and one
output line.

Demultiplexing is achieved by using a device called Demultiplexer (DEMUX) available at the
receiving end. DEMUX separates a signal into its component signals (one input and n outputs).
Therefore, we can say that demultiplexing follows the one-to-many approach.

History of Multiplexing

Multiplexing technique is widely used in telecommunications in which several telephone
calls are carried through a single wire.
Multiplexing originated in telegraphy in the early 1870s and is now widely used in
communication.
George Owen Squier developed the telephone carrier multiplexing in 1910.

Multiplexing Concept

The 'n' input lines are transmitted through a multiplexer and the multiplexer combines the
signals to form a composite signal.
The composite signal is passed through a Demultiplexer and the demultiplexer separates a
signal to component signals and transfers them to their respective destinations.

Advantages of Multiplexing:
More than one signal can be sent over a single medium.

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Assistant Professor (Computer Science)
 The bandwidth of a medium can be utilized effectively.

Multiplexing Techniques

Frequency-division Multiplexing (FDM)
It is an analogue technique.
Frequency Division Multiplexing is a technique in which the available bandwidth of a
single transmission medium is subdivided into several channels.

In the above diagram, a single transmission medium is subdivided into several frequency
channels, and each frequency channel is given to different devices. Device 1 has a
frequency channel range from 1 to 5.
The input signals are translated into frequency bands by using modulation techniques, and
they are combined by a multiplexer to form a composite signal.
The main aim of the FDM is to subdivide the available bandwidth into different frequency
channels and allocate them to different devices.
Using the modulation technique, the input signals are transmitted into frequency bands and
then combined to form a composite signal.

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Assistant Professor (Computer Science)
 The carriers which are used for modulating the signals are known as sub-carriers. They
are represented as f1, f2...fn.
FDM is mainly used in radio broadcasts and TV networks.

Advantages Of FDM:

FDM is used for analogue signals.
The FDM process is very simple and easy modulation.
A Large number of signals can be sent through an FDM simultaneously.
It does not require any synchronization between sender and receiver.

Disadvantages Of FDM:

FDM technique is used only when low-speed channels are required.
It suffers from the problem of crosstalk.
A Large number of modulators are required.
It requires a high bandwidth channel.

Applications Of FDM:

FDM is commonly used in TV networks.
It is used in FM and AM broadcasting. Each FM radio station has different frequencies,
and they are multiplexed to form a composite signal. The multiplexed signal is transmitted
in the air.

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Assistant Professor (Computer Science)
Wavelength Division Multiplexing (WDM)

Wavelength Division Multiplexing is the same as FDM except that the optical signals are
transmitted through the fibre optic cable.
WDM is used on fibre optics to increase the capacity of a single fibre.
It is used to utilize the high data rate capability of fibre optic cable.
It is an analogue multiplexing technique.
Optical signals from different sources are combined to form a wider band of light with the
help of a multiplexer.
At the receiving end, the demultiplexer separates the signals to transmit them to their
respective destinations.
Multiplexing and Demultiplexing can be achieved by using a prism.
Prism can perform the role of multiplexer by combining the various optical signals to form
a composite signal, and the composite signal is transmitted through a fibre optical cable.
Prism also performs a reverse operation, i.e., demultiplexing the signal.

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Assistant Professor (Computer Science)
Time Division Multiplexing
It is a digital technique.
In the Frequency Division Multiplexing Technique, all signals operate at the same time
with different frequencies, but in the case of the Time Division Multiplexing technique, all
signals operate at the same frequency with different times.
In the Time Division Multiplexing technique, the total time available in the channel is
distributed among different users. Therefore, each user is allocated with different time
interval known as a Time slot at which data is to be transmitted by the sender.
A user takes control of the channel for a fixed amount of time.
In the Time Division Multiplexing technique, data is not transmitted simultaneously rather
the data is transmitted one-by-one.
In TDM, the signal is transmitted in the form of frames. Frames contain a cycle of time
slots in which each frame contains one or more slots dedicated to each user.
It can be used to multiplex both digital and analogue signals but is mainly used to multiplex
digital signals.

Synchronous TDM
A Synchronous TDM is a technique in which a time slot is preassigned to every device.
In Synchronous TDM, each device is given some time slot irrespective of the fact that the
device contains the data or not.
If the device does not have any data, then the slot will remain empty.
In Synchronous TDM, signals are sent in the form of frames. Time slots are organized in
the form of frames. If a device does not have data for a particular time slot, then the empty
slot will be transmitted.
The most popular Synchronous TDM are T-1 multiplexing, ISDN multiplexing, and
SONET multiplexing.
If there are n devices, then there are n slots.

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Assistant Professor (Computer Science)
In the above figure, the Synchronous TDM technique is implemented. Each device is allocated
with some time slot. The time slots are transmitted irrespective of whether the sender has data to
send or not.

Disadvantages of Synchronous TDM:

The capacity of the channel is not fully utilized as the empty slots are also transmitted
which has no data. In the above figure, the first frame is filled, but in the last two frames,
some slots are empty. Therefore, we can say that the capacity of the channel is not utilized
efficiently.
The speed of the transmission medium should be greater than the total speed of the input
lines. An alternative approach to the Synchronous TDM is Asynchronous Time Division
Multiplexing.

Asynchronous TDM
An asynchronous TDM is also known as Statistical TDM.
An asynchronous TDM is a technique in which time slots are not fixed as in the case of
Synchronous TDM. Time slots are allocated to only those devices which have the data to

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Assistant Professor (Computer Science)
 send. Therefore, we can say that the Asynchronous Time Division multiplexor transmits
only the data from active workstations.
An asynchronous TDM technique dynamically allocates the time slots to the devices.
In Asynchronous TDM, the total speed of the input lines can be greater than the capacity
of the channel.
Asynchronous Time Division multiplexor accepts the incoming data streams and creates a
frame that contains only data with no empty slots.
In Asynchronous TDM, each slot contains an address part that identifies the source of the
data.

The difference between Asynchronous TDM and Synchronous TDM is that many slots in
Synchronous TDM are unutilized, but in Asynchronous TDM, slots are fully utilized. This
leads to a smaller transmission time and efficient utilization of the capacity of the channel.
In Synchronous TDM, if there are n sending devices, then there are n time slots. In
Asynchronous TDM, if there are n sending devices, then there are m time slots where m is
less than n (m