1. Computer Networks Module 2: Physical Layer Dr. Vikram Shete St. Francis Institute of Technology

2. Physical Layer and Tx. Medium

3. Medium Classification

4. Guided Media Guided media:Guided media: –Provide a conduit from one device to another –Eg. twisted-pair cable, coaxial cable, and fiber-optic cable

5. Guided Media (Twisted Pair Cable)

6. Effect of Noise (Parallel Lines)

7. Effect of Noise (Twisted Pair)

8. Commercial Unshielded Twisted Pair (UTP) Cable

9. UTP Cable

10. Shielded Twisted Pair (STP)

11. Coaxial Cable

12. Optical Fiber Cable

15. Multimode –Multiple beams from light source can travel through the core in different paths –Step index fiber: Core density is constant from center to edges At the edge there is a abrupt change due to lower density Step index is derived from this sudden change and causes distortion

16. Optical Fiber Cable Multimode –Graded index fiber Core density is highest at the center and gradually decreases toward the edges –Single mode (SM) Uses step index fiber A highly focused source limits beams to small range of angles close to the horizontal Diameter of SM fiber is very small with a substantially lower density

17. Optical Fiber Cable –Single mode (SM) Results in a critical angle close to 90 o resulting in horizontal beam propagation Propagation of beams is almost identical and hence delays are negligible All beams arrive at the same time

19. Optical Fiber Cable

20. Unguided Media Spectrum of wireless transmission waves

21. Unguided Media Propagation methods

22. Unguided Media Ground Propagation: –Radio waves travel through the lowest portion of the atmosphere –Waves emanate from antenna in all direction and follow earths curvature Sky Propagation: –Waves travel to the atmosphere and are reflected back. –Greater distance at lower power

23. Unguided Media Line of Sight Propagation: –Very high frequency signals transmitted in straight lines directly from antenna to antenna

24. Bands

25. Unguided Media

26. Radio Waves –3kHz - 1GHz –Omnidirectional Rx and Tx do not have to be aligned –Susceptible to interference –Radio waves in sky mode good candidate for longer distance (broadcasting - AM) –Radio waves and low frequencies can penetrate walls (its an advantage and disadvantage)

27. Unguided Media Microwaves –1GHz - 300 GHz –Unidirectional in nature and can be narrowly focussed –Rx and Tx have to be aligned –Line of sight propagation Curvature of earth and other blockages can interfere with communication –Cannot penetrate walls –Band is relatively wide and hence wider sub- bands and hence higher data rates

28. Unguided Media

29. Network Hardware Components Repeaters, Hubs, Bridges, Routers and Gateways

30. Network Components

31. Repeaters ( Physical Layer ) Repeaters appear at the Physical layer –Analog devices connected to 2 cable segments –Signal is amplified and forwarded –Do not read/understand frames, packets or headers –Eg: Classic ethernet allows 4 repeaters to extend length from 500 m to 2500 m

32. Hubs ( Physical Layer ) Hubs has many inputs. All are connected electrically –Frames arriving on one are sent on all –May result in collision –A hub forms a single collision domain –Hubs do not amplify –All input lines must operate at the same speed –Do not read/examine packets or frames

33. Bridges ( Data Link Layer ) Bridges connect two or more LANs –Extracts information from the frame –Identifies destination –Uses look-up tables and forwards to appropriate ports –Each line of a bridge is its own collision domain Discard if destination and source LANs are same Forward if dest. and src LANs are different If dest. LAN unknown, use flooding

34. Bridges Bridges are used to split large LANs These operate at the data link layer Reasons to have bridges 1.Goals of departments are different and yet interaction may be required 2.Cheaper to have individual LANs rather than one huge geographically spread network

35. Bridges 3.It’s better to split labs to keep workload local. Huge bandwidth required if a single LAN is used HubHub

36. Bridges –Total physical distance can be covered Insert bridges to split LANs instead of using ethernet cables to its limit (2.5 km) –“What happens in Vegas stays in Vegas” (Reliability) Bridges can isolate LANs A single berserk node will not bring down whole of the network –Admins can keep add security by inserting bridges at critical points. Bridges can be programmed to use discretion

37. Switches ( Data Link Layer ) Switches are similar to bridges –Switches connect individual computers

38. Switches ( Data Link Layer ) Each switch port is connected to single computer Switches have space for more line cards than bridges Each line card provides a buffer for frames Each port is its own collision domain and so switches never lose frames However switches may run out of buffer space due to which frames might be lost

39. Switches ( Data Link Layer ) This is due to higher data rates at arriving port To alleviate this modern switches use “cut- through approach” –Frames forwarded as soon as header received All modern switches and bridges have similar features making the difference a more of marketing gimmick

40. Routers ( Network Layer ) Routers isolate broadcast and collision domains –Strip off frame headers –Peek into the packet headers –Concerned with logical addressing –Do not care about the LAN from which a frame arrives