Basic Communications Systems Class 9

1. Basic Communications Systems Class 9

2. Today’s Class Topics • WAN Data Services • DSL • Cable Modems • T1 Access Lines • Frame Relay • Voice Processing • Voice Call Control • Business Services • Key Systems, PBX and Centrex

3. What can you do with a copper subscriber loop? • Modems • Can provide up to 52 Kbps downstream over subscriber loop. • Integrated Services Digital Networks (ISDN) • Provides 144 Kbps over copper telephone line. • Digital Subscriber Line (DSL) Technologies • Can provide up to 52 Mbps over short copper loop.

4. Name Data Rate Distance V.32 V.34 Voice Band Modems 9600 - 28,800 bps Any Voice Line Service V.90 56K Modem 24 - 52 Kbps down 33.6 Kbps up Any Voice Line IDSL ISDN DSL 144 Kbps 18,000-24,000 feet SDSL Single-Pair DSL Up to 1.544 Mbps 12,000 feet HDSL High Speed DSL 1.544 Mbps 12,000-18,000 feet ADSL Asymmetric DSL Up to 7 Mbps down Up to 640 Kbps up 12,000 – 18,000 feet ADSL Lite Up to 1.5 Mbps down Up to 512 Kbps up 12,000 – 18,000 feet VDSL Very High-speed DSL 13 Mbps down 4,500 feet 25.82 Mbps down 3,000 feet 52 Mbps down 1,000 feet Data over Copper Loop

5. Digital Subscriber Lines • Problems • Loop Qualification • The condition of many copper loops is unknown. • Testing and removal of load coils takes time. • Distance • DSL does not work over 18,000 feet • More than 20% of subscriber loops in U.S. are longer than 18,000 feet. • Crosstalk • Some types of ADSL and VDSL can interfere with data signals on adjacent pairs (crosstalk)

6. ADSL • Provides • 1.5 Mbps – 7 Mbps downstream, depending on equipment and distance • 16 Kbps – 640 Kbps upstream, depending on equipment and distance • 4 KHz analog voice channel • Currently being aggressively deployed by CLECs and LECs for Internet access and other applications

7. ADSL Lite • A simpler version of ADSL (G.lite) designed to be installed without any Telco visit to the home. • G.Lite modems will be sold directly to consumers • Usually provides • 1.5 Mbps downstream • 384 Kbps upstream • No analog channel (splitterless) • May allow faster deployment due to simplified installation

8. Voice over ADSL • “Voice over ADSL” products are now being deployed. • Allow customer to dynamically allocate multiple voice channels on ADSL data channel • Voice allocation choices: • static 24 x DS0 allocation as with T1 (i.e. 4 voice channels and 20x64K = 1.28 Mbps of data) • packetized voice over DSL data channel • Voice/data over ATM over DSL

9. VDSL • Very High Speed data channel over short copper loops • Provides access to Fiber-to-the Curb installations • Carrier provides fiber to building basement or to neighborhood Optical Networking Unit (ONU) • VDSL provides data access to ONU • Can provide high-speed LAN-to-LAN interconnection at up to 52 Mbps

10. CATV Telephony • CATV advantages: • Coaxial cable offers much greater bandwidth than copper pair • Cable is already installed to ~70% of U.S. homes • CATV problems: • Coax systems may need to be upgraded • Hybrid Fiber Coax (HFC) • 2-way amplifiers • Cost of telephony equipment is large • Return signals are very noisy • Not a great perception of reliability

11. Cable TV Plant From: Videon Cable Modem Technology Primer

12. Hybrid Fiber / Coax From: Videon Cable Modem Technology Primer

13. Cable Modem Standards • Data Over Cable Service Interface Specification (DOCSIS): • Components: • Cable Modem Termination System • Hybrid Fiber Coax Network • Cable Modem • Connection is achieved through 10 / 100 Mbps Ethernet connector • Downstream speed: 27 Mbps or 40 Mbps.

14. T-Carrier Systems

15. The T1 System • T1 was the first T-carrier system deployed by the Bell System (in 1962) • Bit Rate: 1.544 Mbps: • Digital Information: 1.536 Mbps • Framing Bits: 8 Kbps • Originally run over 4-wire (2 pair) copper wire with regenerators every 6000 feet. Can also be sent over fiber.

16. T1 System Uses • T1 Carrier Trunk • Telecommunications companies use T1 trunks between switching offices • T1 Access Circuit • Business customers use T1s as: • PBX - CO trunks (24 digital trunks on 1 cable) • Data access lines (1 data channel running at 1.536 Mbps)

17. Channelized? • Channelized T-1 Circuit • T-1 is utilized as 24 DS0 channels of 64 Kbps each. • Each DS0 can be allocated to carry any single service, such as CO trunk, DID trunk, WATS, FX, 56K data, switched 56K, etc. • Unchannelized T-1 • T-1 is utilized as a single 1.536 Mbps data circuit.

18. Fractional T1 (Channelized) • A customer may request a leased Fractional T1, which means: • Customer only sends data on an agreed subset of the DS0s (example: DS0s 1-6) • Carrier only forwards these particular DS0s to the far-end • Customer pays less than full T1 fee • Example: 256 Kbps fractional T1 (4 x DS0) from Chicago-NY could be ~$2500/month

19. UnChannelized T1:1.536 Mbps Leased Data Service

20. T1 Details • Bipolar Representation • T1 uses Bipolar Coding to represent 1 and 0 bits • ‘1’ bit represented by alternating +3 volt, -3 volt pulses • ‘0’ bits represented by no voltage • Framed Format • T1 transmits 8000 frames per second, 193 bits per frame (8000 * 193 = 1,544,000).

21. Bipolar Representation

22. T1 Frame Format • Each DS0 called a time slot • 8000 frames/sec * 8 bits/slot = 64 Kbps • 24 * 8 + 1 = 193 bits/frame • 8000 frames/sec * 193 bits/frame = 1.544 Mbps • 8000 Framing bits sent per second

23. T1 Framing Bits • D4 T1 lines (1972): • Allow receiver to find the start-of-frame (frame synchronization). • Group sets of 12 frames into superframes • Indicate that frames 1 and 6 contain signaling bits (to specify if channel is in use or not) • D5 (ESF) T1 lines (1983): • Provide error checking (CRC) (ESF T1) • Provide Facilities Data Link channel to transmit network management messages (ESF T1)

24. D4 Frame Format • Frames 1-5, 7-11: • Frames 6, 12:

25. T1 Framing Bits (ESF Frame) • D5 Framing - Extended Superframe T1 (1983) • F-bit pattern marks 24-frame extendedsuperframes • F-bit pattern: • Odd frames: Facilities Data Link • Every 4th frame: 001011 (Framing pattern) • Every 4th frame: CRC for previous ESF

26. ESF Frame Advantages • Facilities Data Link • Network diagnostics and management messages sent between carrier equipment • Cyclic Redundancy Check (CRC) • Allows error detection on T1 lines • Carrier can offer Automatic Protection Switching service to customer (switches to another T1 line if errors detected)

27. Data over T1 • A T1 carries 24 DS0 channels • A DS0 may carry a maximum of 56 Kbps or 64 Kbps of data • A restricted T1 can carry up to 24 x 56 Kbps = 1.344 Mbps. • A clear-channel T1 can carry up to 24 x 64 Kbps = 1.536 Mbps.

28. T1 Data – 56K or 64K ? • T1 capacity depends on: • Line Coding • An AMI T1 carries 56 Kbps per DS0 • A B8ZS T1 carries 64 Kbps per DS0 • Signaling • A T1 using robbed bit signaling is limited to 56 Kbps per DS0 for data (to avoid signal bits) • A leased-line T1 (no signaling) or a T1 on a Signaling System 7 (SS7) network does not need robbed bit signaling.

29. Frame Relay • Telecommunications carriers maintain networks of Frame Relay switches • Customer get access line to nearest switch to get Frame Relay service • Higher data rates than X.25 • Lower delays, higher throughputs and better security than the Internet

30. Frame Relay Basics • Data is sent over pre-established Virtual Circuits, like X.25. • Frame Assembler/Disassemblers (FRADs) can be used to connect internal devices to the frame relay network • FRADs generate Frame Relay headers/trailers and send data frames into the network

31. Frame Relay Basics • Data only sent over Permanent Virtual Circuits (PVCs), which are set up by the carrier, not customer - always available • Customer can access network at data rates from 56 Kbps to 45 Mbps • No error control done by network switches (error control is responsibility of customer)

32. Frame Relay Basics • Fixed monthly cost based on • “Line charge” for access line between user site and frame relay carrier location • “Port charge” for each connection into carrier equipment • “PVC charge” for each PVC defined between ports • Frame Relay is a layer 2 protocol, so any layer 3 protocol (like IP, for example) can be carried over a Frame Relay network

33. Replacing Leased Lines • Typically used to replace leased lines: • Customer gets one Frame Relay PVC to replace each leased line • Customer still gets guaranteed delay and throughput (CIR) similar to leased line • Customer uses one access line at each business location for all frame relay data • Customer saves money - PVCs cost less than leased lines

34. Leased Line Problem: Number of leased circuits (and cost!) grows very large as number of sites increases!!

35. The Frame Relay Solution: 1 Access Line for each site!!

36. Frame Relay Addressing • The carrier assigns each PVC a 10-bit Data Link Connection Identifier (DLCI). • Customer sets up a table in each access router that maps each possible destination to its DLCI. • Router puts correct DLCI into each frame header before sending frame into network.

37. Frame Relay Frame Format • Flag - Fixed bit pattern to start and end frame - set to 01111110 • Data Link Connection ID – PVC Address • Discard Eligible – Determines whether this frame can be discarded at network switches • CRC - Allows error detection • Some unused header bits not shown

39. CIR • For each PVC, customer specifies a Committed Information Rate (CIR): • CIR represents a guaranteed throughput for this PVC • Carrier also guarantees limited data delivery time if customer does not exceed CIR • Price of PVC is directly related to CIR • High CIR = high monthly price • Low CIR = lower monthly price

40. CIR • Example: • I have a T1 (1.536 Mbps) access line into the frame relay network in Chicago • I ask my carrier to create a PVC from Chicago to Dallas with CIR = 512 Kbps. • If I stay within my CIR (i.e., send less than 512,000 bps Chicago-Dallas, on average): • Carrier guarantees 99.99% traffic gets through • Carrier guarantees <= 20 ms. Network delay

41. Frame Relay PVCs with CIRs

42. Frame Relay Pricing • Example: • 4 sites, each with T1 access line • 6 PVCs providing connectivity between sites, with 56 Kbps CIR on each PVC • Monthly Costs: • 4 x (T1 access port cost) plus • 6 x (56 Kbps PVC cost)

43. What if I exceed my CIR? • Example: • I have a T1 (1.536 Mbps) access line into the frame relay network in Chicago • I ask my carrier to create a PVC from Chicago to Dallas with CIR = 512 Kbps. • Isn’t it possible for me to exceed my CIR (send more than 512 Kbps Chicago-Dallas)? • YES!!!!!

44. What if I exceed my CIR? • Most carriers will allow customers to exceed CIR up to a fixed Burst Rate (Br) for up to 2 seconds with no penalty. • If customer continues to exceed CIR beyond 2 seconds, carrier sets Discard Eligible (DE) bit in frame headers • If network congestion occurs, DE marked frames are discarded by network switches

45. The Tradeoff • Low CIR ==> Low cost, but your data may be discarded by the network • High CIR ==> High cost, but data throughput is guaranteed by carrier • Note: Many customer still choose to pay lowest cost by selecting a Zero CIR option that provides no delivery guarantees

46. Frame Relay vs. The Internet • Frame Relay advantages: • Guaranteed throughput and delay (ISPs generally give no guarantees) • Security (hackers cannot break into PVCs between corporate sites) • Frame Relay disadvantages • Price (more expensive than Internet service) • Inflexibility (can’t send data to another site unless PVC is already in place)

47. Network-to-Network Interfaces • Do you ever want to set up a PVC between sites connected to 2 different Frame Relay providers?? • YES!! • To connect between LEC networks • To set up an extranet with trading partner • To interconnect sites after company merger

48. Network-to-Network Interfaces • How do you set up an inter-carrier PVC? • The carriers need to set up a Frame Relay Network-to-Network Interface (NNI) which controls traffic between the networks

49. Network-to-Network Interfaces • Carriers don’t like NNIs!! • How do they split the fees ($$)?? • If the PVC goes down, who is to blame? • What are the end-to-end performance guarantees? • Coordinating PVC addresses (DLCIs) for both networks is a hassle

50. Network-to-Network Interfaces • NNIs: The bottom line: • Some carriers refuse to set up NNIs • If you have a big enough contract with them, perhaps you can convince them otherwise. • Alternatives • You can move all your FR sites to one carrier • You can set up your own router with connections to PVCs on both carrier networks • But this may cause traffic bottleneck at that router. • You can switch to a routed IP network service