1. Virtual-Circuit Networks:
Chapter 18
Virtual-Circuit Networks:
Frame Relay and ATM
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2. Topics discussed in this section:
FRAME RELAY
Frame Relay is a virtual-circuit wide-area network that was designed in response to demands for a new type of WAN in the late 1980s and early 1990s.
Topics discussed in this section:
Architecture Frame Relay Layers
Extended Address
FRADs
VOFR
LMI

3. Frame Relay
Prior to frame relay X.25 were used as a virtual-circuit switching network.
- X.25 has a low 64-kbps data rate.
- X.25 has extensive flow and error control at both the data link layer and the network layer.

4. Frame Relay
T1 or T3 leased lines for private WAN from public service providers.
- Excessive lines (for many branches)
- T1 and T3 lines assume that the user has fixed-rate data all the time (1.544 Mbps). So it is not suitable for Bursty data.

5. Frame Relay Frame Relay Features:
- Frame Relay operates at higher speed (1.544 Mbps up to Mbps).
- FR operates in just the physical and Data-link layers. It can be used as a backbone network.
- FR allows bursty data.
- FR allows a frame size of 9000 bytes.
- FR is less expensive than other traditional WANs.
- FR has error detection at the data link layer only.

6. Architecture Permanent Virtual Circuits and Switched Virtual Circuits.
The frame relay WAN is used as one link in the global Internet (figure 18.1).
Frame Relay is a virtual circuit network.
A virtual circuit in Frame Relay is identified by a number called a data link connection identifier (DLCI).

7. Figure 18.1 Frame Relay network

8. VCIs in Frame Relay are called DLCIs.
Note
VCIs in Frame Relay are called DLCIs.

9. Permanent Vs. Switched Virtual Circuits
Permanent Virtual Circuits:
The connection setup is simple.
Table entry is recorded for all switches by the administrator. An outgoing DLCI is given to the source, and an incoming DLCI is given to the destination.
- Drawbacks: Costly , each source needs several PVC for several connections.

10. Permanent Vs. Switched Virtual Circuits
The connection is created temporary.
Short connection that exists only when data are being transferred between source and destination.
- Drawbacks: Requires establishing and terminating phases.

11. Switches
Each switch in a Frame Relay network has a table to route frames.
The table matches an incoming port-DLCI combination with an outgoing port-DLCI combination.

12. Figure 18.2 Frame Relay layers

13. Frame Relay operates only at the physical and data link layers.
Note
Frame Relay operates only at the physical and data link layers.

14. Figure 18.3 Frame Relay frame

15. by the upper-layer protocols.
Note
Frame Relay does not provide flow or error control; they must be provided
by the upper-layer protocols.

16. Figure 18.4 Three address formats

17. Figure FRAD

18. Topics discussed in this section:
ATM
Asynchronous Transfer Mode (ATM) is the cell relay protocol designed by the ATM Forum and adopted by the ITU-T.
Topics discussed in this section:
Design Goals Problems Architecture
Switching
ATM Layers

19. Figure 18.6 Multiplexing using different frame sizes

20. A cell network uses the cell as the basic unit of data exchange.
Note
A cell network uses the cell as the basic unit of data exchange.
A cell is defined as a small, fixed-size block of information.

21. Figure 18.7 Multiplexing using cells

22. Figure 18.8 ATM multiplexing

23. Figure 18.9 Architecture of an ATM network

24. Figure TP, VPs, and VCs

25. Figure 18.11 Example of VPs and VCs

26. Note
Note that a virtual connection is defined by a pair of numbers: the VPI and the VCI.

27. Figure 18.12 Connection identifiers

28. Figure 18.13 Virtual connection identifiers in UNIs and NNIs

29. Figure An ATM cell

30. Figure 18.15 Routing with a switch

31. Figure ATM layers

32. Figure 18.17 ATM layers in endpoint devices and switches

33. Figure ATM layer

34. Figure ATM headers

35. Figure AAL1

36. Figure AAL2

37. Figure AAL3/4

38. Figure AAL5

39. Topics discussed in this section:
ATM LANs
ATM is mainly a wide-area network (WAN ATM); however, the technology can be adapted to local-area networks (ATM LANs). The high data rate of the technology has attracted the attention of designers who are looking for greater and greater speeds in LANs.
Topics discussed in this section:
ATM LAN Architecture LAN Emulation (LANE)
Client/Server Model
Mixed Architecture with Client/Server

40. Figure ATM LANs

41. Figure Pure ATM LAN

42. Figure Legacy ATM LAN

43. Figure 18.27 Mixed architecture ATM LAN

44. Figure 18.28 Client and servers in a LANE

45. Figure 18.29 Client and servers in a LANE