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Multiplexing and Switching
Multiplexing
Sharing the link among multiple users
Multiplexing
Time Division Multiplexing (TDM)
 Synchronous TDM
 Statistical TDM
Frequency Division Multiplexing (FDM)
Time Division Multiplexing
The Basic Idea:
 As the name suggest, Divide time amongst the
users
 Give each user some tim...
Time Division Multiplexing
MUX
12
1
3
23
123
THE TRANSMITTER
12 13 23 123
THE LINK
DEMUX
THE RECEIVER
There should be no Timing difference between
the
MUX and DEMUX
WARNING………!!!!!!!
DEMUX
Or else……..!!!!
Something like this will happen……!!!!!
Therefore, the two devices
should be synchronized……
And so it is called Synchronous TDM
The problem with Synchronous TDM
What if host2 has only one packet to send
and host3 has two packet to send……..
MUX
12
1
...
12 13 12
THE LINK
Time slots are being
wasted….!!
The solution is
Statistical TDM
Statistical TDM
Here Time slots are given on
demand……….rather than in round robin
fashion
Each User can get 2 or more co...
Frequency Division
Multiplexing
Frequency Division Multiplexing Diagram
FDM
Sharing is done by assigning each user a
specific frequency (Carrier Frequency)
Modulation equipment is used to move...
User 1
User 2
User 3
M
O
D
U
L
A
T
O
R
f1
f2
f3
All the users transmit their data simultaneously….
f1 f2 f3
The Received data at the Receiver
f1 f2 f3
f1 f2 f3
The Filter
The output
f1 f2 f3
fc
y(f)
Demodulate to get the original signal back
Switching
Switching Networks
A network is made up of end hosts and
intermediate switching nodes
Data is usually passed through a
n...
A
1
7
2
5
3
4
6
B
C
D
E
F
Switching Nodes
End Hosts
Some Notes…
 Some nodes only connect to other nodes
 Some nodes connect to end hosts also
 Usually the network is not f...
Two Technologies for Switching
Circuit Switching
Packet Switching
They differ in the way the nodes switch
information fr...
Circuit Switching
A dedicated communication path between the
hosts
A
1
7
2
5
3
4
6
B
C
D
E
F
Switching Nodes
End Hosts
Three Phases
 Circuit Establishment
• Host-B send a connection request towards Host-D
• Intermediate nodes route the requ...
Principles
• Circuit switching designed for voice
– Resources dedicated to a particular call
– Much of the time a data con...
Packet Switching
Problems in Circuit Switching
 Circuit Switching approach is inefficient
 Since data rate is constant, therefore the
dev...
Packet Switching…...A quick overview
 Data is transmitted in short packets
 If a source has larger message to send, the ...
Advantages
 Line efficiency is greater
 A packet switching network can perform data rate
conversion
 In Circuit Switchi...
Types of Packet Switching
Datagram Approach
Virtual Circuit Approach
Datagram Packet Switching
 Each packet is treated independently, with no reference to packets
that have gone before
 Eac...
A
B
Virtual Circuit Packet Switching
A preplanned route is established before
any packets are sent
All the packets follow th...
DisconnectData
Connect Accept
Packets will be received in order
However, packets can get lost on the way
Event Timing
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Multiplexing and switching(TDM ,FDM, Data gram, circuit switching)

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pls download for watching transition of bits
its include switching(data gram , circuit switching etc) and multiplexing and multiplexing (FDM AND TDM)

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Multiplexing and switching(TDM ,FDM, Data gram, circuit switching)

  1. 1. Multiplexing and Switching
  2. 2. Multiplexing Sharing the link among multiple users
  3. 3. Multiplexing Time Division Multiplexing (TDM)  Synchronous TDM  Statistical TDM Frequency Division Multiplexing (FDM)
  4. 4. Time Division Multiplexing The Basic Idea:  As the name suggest, Divide time amongst the users  Give each user some time to transmit his data  This process is periodic in a round robin fashion  The time given to a each user is referred to as Time Slot or Time Quantum
  5. 5. Time Division Multiplexing
  6. 6. MUX 12 1 3 23 123 THE TRANSMITTER
  7. 7. 12 13 23 123 THE LINK
  8. 8. DEMUX THE RECEIVER
  9. 9. There should be no Timing difference between the MUX and DEMUX WARNING………!!!!!!!
  10. 10. DEMUX Or else……..!!!! Something like this will happen……!!!!!
  11. 11. Therefore, the two devices should be synchronized…… And so it is called Synchronous TDM
  12. 12. The problem with Synchronous TDM What if host2 has only one packet to send and host3 has two packet to send…….. MUX 12 1 3 12
  13. 13. 12 13 12 THE LINK
  14. 14. Time slots are being wasted….!!
  15. 15. The solution is Statistical TDM
  16. 16. Statistical TDM Here Time slots are given on demand……….rather than in round robin fashion Each User can get 2 or more consecutive time slots If time slot is not required, it is not allocated Hence, not wasted
  17. 17. Frequency Division Multiplexing
  18. 18. Frequency Division Multiplexing Diagram
  19. 19. FDM Sharing is done by assigning each user a specific frequency (Carrier Frequency) Modulation equipment is used to move each signal to the required frequency band. Multiplexing equipment is needed to combine the modulated signal
  20. 20. User 1 User 2 User 3 M O D U L A T O R f1 f2 f3
  21. 21. All the users transmit their data simultaneously…. f1 f2 f3
  22. 22. The Received data at the Receiver f1 f2 f3 f1 f2 f3 The Filter The output f1 f2 f3
  23. 23. fc y(f) Demodulate to get the original signal back
  24. 24. Switching
  25. 25. Switching Networks A network is made up of end hosts and intermediate switching nodes Data is usually passed through a network of intermediate switching nodes The Switching nodes: Not concerned with the contents of the data; • Provide a switching facility that will move data from node to node until they reach their destination
  26. 26. A 1 7 2 5 3 4 6 B C D E F Switching Nodes End Hosts
  27. 27. Some Notes…  Some nodes only connect to other nodes  Some nodes connect to end hosts also  Usually the network is not fully connected; there is not a direct link between each pair of nodes  If there are more than one paths between any pair of nodes; this increases the reliability of the network  Node-Node links are usually multiplexed
  28. 28. Two Technologies for Switching Circuit Switching Packet Switching They differ in the way the nodes switch information from one link to another on the way from source to destination
  29. 29. Circuit Switching A dedicated communication path between the hosts
  30. 30. A 1 7 2 5 3 4 6 B C D E F Switching Nodes End Hosts
  31. 31. Three Phases  Circuit Establishment • Host-B send a connection request towards Host-D • Intermediate nodes route the request to Host-D based on measures of availability and cost • If ready, D accepts the connection and a dedicated path (generally full duplex) is established from B through the intermediate nodes to D  Data Transfer • The data (analog/digital) is carried on the dedicated path  Circuit Disconnect • Done by any one station • Signals are propagated to intermediate nodes to de- allocate the dedicated resources
  32. 32. Principles • Circuit switching designed for voice – Resources dedicated to a particular call – Much of the time a data connection is idle – Data rate is fixed • Both ends must operate at the same rate
  33. 33. Packet Switching
  34. 34. Problems in Circuit Switching  Circuit Switching approach is inefficient  Since data rate is constant, therefore the devices interconnected must transmit and receive at the same data rate, This limits the interconnection of variety of hosts  Further calls are blocked when all the lines are busy
  35. 35. Packet Switching…...A quick overview  Data is transmitted in short packets  If a source has larger message to send, the message is broken up into a series of packets  Each packet contains user’s data plus some control information (header)  The control information, at a minimum includes the information that the network requires to be able to route the packet through the network and deliver it to the intended destination  At each node the packet is received, stored briefly and passed on to the next node
  36. 36. Advantages  Line efficiency is greater  A packet switching network can perform data rate conversion  In Circuit Switching, calls are blocked whereas in P.S. packets are still accepted but delivery delay increases  Priorities can be used, thus a higher priority packet experiences less delay
  37. 37. Types of Packet Switching Datagram Approach Virtual Circuit Approach
  38. 38. Datagram Packet Switching  Each packet is treated independently, with no reference to packets that have gone before  Each packet contains the address of its destination  The packets with the same destination do not always follow the same route  Some packets can get late and some can get destroyed in the network  Therefore, packets can be received out of order at the destination  There must be some mechanism of re-ordering at the receiver  Each packet, treated independently, is referred to as datagram
  39. 39. A B
  40. 40. Virtual Circuit Packet Switching A preplanned route is established before any packets are sent All the packets follow that route Just like circuit switching, the route should be terminated after the transmission of data
  41. 41. DisconnectData Connect Accept
  42. 42. Packets will be received in order However, packets can get lost on the way
  43. 43. Event Timing

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