1. Ethernet Frame PreambleDestination Address Source Address Length/ Type LLC/ Data Frame Check Sequence

2. Ethernet Addresses n 48 bit n normally shown in HEX n e.g.: 02-60-8C-44-59-E0 n first 24 bits are obtained from IEEE by hardware manufacturers n one bit is used to distinguish unicast from multicast addresses n one bit is used to distinguish locally assigned addresses(rare) from globally assigned addresses (typical)

3. Transmission Types n Unicast - intended for one specific station n Broadcast - intended for all stations n Multicast - intended for a group of stations

4. CSMA/CD n Carrier Sense, Multiple Access with Collision Detection n Carrier sense - don't transmit if there is already a signal n Collision detection - if a collision is detected jam, wait, and retransmit

6. No Carrier

7. Transmission

9. End of Transmission

10. Transmission

11. Second Transmission

12. Collision

13. Collision detected

14. Wait

15. Ethernet HUB (repeater) Layer 1 device Repeat signal on all ports Enforce collision on all segments (jam) Restore amplitude of the signal Retime the signal Single speed May mix media

16. Repeater Hub

17. one station transmits

18. Repeater Hub signal repeated on all other ports

19. Repeater Hub signal repeated on all other ports

20. Repeater Hub end of transmission

21. Repeater Hub

24. Matrix Module

25. Collision Domain Devices connected by hubs Only one device can transmit at a time Collisions detected by all devices in the domain

26. Hub One Collision Domain

32. Broadcast Domain Devices connected by switches Can contain multiple collision domains One transmission in each collision domain Collisions do not propagate between collision domains Broadcast frames do propagate to all collision domains Can be full duplex if only two devices in collision domain and both devices are full duplex cabable

33. Switch Hub Three Collision Domains One Broadcast Domain

34. H – Ethernet Hub S – Ethernet Switch R – IP Router W – Workstation _____ Ethernet Segment R S H W S S H H W W H WW W WW W

35. H – Ethernet Hub S – Ethernet Switch R – IP Router W – Workstation _____ Ethernet Segment R S H W S S H H W W H WW W WW W

36. H – Ethernet Hub S – Ethernet Switch R – IP Router W – Workstation _____ Ethernet Segment R S H W S S H H W W H WW W WW W

37. H – Ethernet Hub S – Ethernet Switch R – IP Router W – Workstation _____ Ethernet Segment R S H W S S H H W W H WW W WW W

38. Ethernet switch Function (old name) “bridge” Forwards or Filters unicasts Floods (forwards to all ports) all broadcasts Learns address locations Can be full duplex if only two devices in collision domain and both devices are full duplex cabable Can mix speeds and media

40. switch Hub E1 E2 E3 E4 E5 E6 12 3 DASAAction FFE2 E3 E2 FFE5 E6 E5 E4E1 ADDRESSPORT

41. Switch Light Videos Switch Lights(3.5 MB)Switch Lights Switch Lights – more(5.9 MB)Switch Lights – more

42. Cut-Through Mode and Store and Forward Mode Cut-through mode –Switching mode in which switch reads a frame’s header and decides where to forward the data before it receives the entire packet –Can detect runts, or packet fragments Store and forward mode –Switching mode in which switch reads the entire data frame into its memory and checks it for accuracy before transmitting it

43. Using Switches to Create VLANs Virtual local area networks (VLANs) –Means by which a switch can logically group a number of ports into a broadcast domain Broadcast domain –Combination of ports that make up a Layer 2 segment and must be connected to a Layer 3 device FIGURE 6-24 Simple VLAN design

44. Trunk Aggregation

45. Resilient Links

46. Higher-Layer Switches Switch capable of interpreting Layer 3 is called a Layer 3 switch Switch capable of interpreting Layer 4 is called a Layer 4 switch Higher-layer switches may also be called routing switches or application switches

47. Routers Multiport device Can connect dissimilar LANs and WANs running at different transmission speeds and using a variety of protocols

48. Router Features and Functions Filter out broadcast transmission to alleviate network congestion Prevent certain types of traffic from getting to a network Support simultaneous local and remote activity Provide high network fault tolerance through redundant components Monitor network traffic and report statistics to a MIB Diagnose internal or other connectivity problems and trigger alarms

49. Routers FIGURE 6-26 Placement of routers on a LAN

50. Routing Protocols Means by which routers communicate with each other about network status –Convergence time The time it takes for a router to recognize a best path in the event of a change or outage –Bandwidth overhead Burden placed on an underlying network to support the routing protocol

51. Routing Protocols RIP (Routing Information Protocol) for IP and IPX OSPF (Open Shortest Path First) for IP –Best path refers to the most efficient route from one node on a network to another EIGRP (Enhanced Interior Gateway Routing Protocol) for IP, IPX, and AppleTalk BGP (Border Gateway Protocol) for IP

52. Gateways Combination of networking hardware and software that connects two dissimilar kinds of networks –E-mail gateway –IBM host gateway –Internet gateway –LAN gateway