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9.1 Chapter 9 Using Telephone and Cable Networks for Data Transmission Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction.

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Presentation on theme: "9.1 Chapter 9 Using Telephone and Cable Networks for Data Transmission Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction."— Presentation transcript:

1 9.1 Chapter 9 Using Telephone and Cable Networks for Data Transmission Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

2 9.2 9-1 TELEPHONE NETWORK Telephone networks use circuit switching. The telephone network had its beginnings in the late 1800s. The entire network, which is referred to as the plain old telephone system (POTS), was originally an analog system using analog signals to transmit voice. Major Components LATAs: Local Access Transport Areas Signaling Services Provided by Telephone Networks Topics discussed in this section:

3 9.3 Figure 9.1 A telephone system

4 9.4 Intra-LATA services are provided by local exchange carriers. Since 1996, there are two types of LECs: incumbent local exchange carriers and competitive local exchange carriers.

5 9.5 Service between LATAs are handled by Ineterexchange carriers (IXC) services are provided by long distance company. POP; Point of presence: Each IXC that wants to provide inter-LATA services in a LATA must have a POP in that LATA The local exchange carrier that provides services in that LATA must provide all its customers connections to access all POPs

6 9.6 Figure 9.2 Switching offices in a LATA

7 9.7 Figure 9.3 Point of presences (POPs)

8 9.8 The tasks of data transfer and signaling are separated in modern telephone networks: data transfer is done by one network, signaling by another. SS7: Signaling System Seven is the protocol used in the signaling network Note

9 9.9 Figure 9.4 Data transfer and signaling networks

10 9.10 Figure 9.5 Layers in SS7

11 9.11 9-2 DIAL-UP MODEMS Traditional telephone lines can carry frequencies between 300 and 3300 Hz, giving them a bandwidth of 3000 Hz. All this range is used for transmitting voice, where a great deal of interference and distortion can be accepted without loss of intelligibility. Modem Standards Topics discussed in this section:

12 9.12 Figure 9.6 Telephone line bandwidth

13 9.13 Modem stands for modulator/demodulator. V.32, V.32bis, V90, V.92: ITU-T standards V.32: 14,400 bps (7 bits with 1 bit for error at a rate of 2400 baud V.90: also called 56K modems( 8bits with 1 bit for error at a rate of 8000): Upload has a max of 33.3kbps Download has a max of 56kbps V.92: Upload at 48Kbps with features such a call-waiting.

14 9.14 Figure 9.7 Modulation/demodulation

15 9.15 Figure 9.8 The V.32 and V.32bis constellation and bandwidth

16 9.16 Figure 9.9 Uploading and downloading in 56K modems

17 9.17 9-3 DIGITAL SUBSCRIBER LINE After traditional modems reached their peak data rate, telephone companies developed another technology, DSL, to provide higher-speed access to the Internet. Digital subscriber line (DSL) technology is one of the most promising for supporting high-speed digital communication over the existing local loops. ADSL ADSL Lite HDSL SDSL VDSL Topics discussed in this section:

18 9.18 ADSL is an asymmetric communication technology designed for residential users; it is not suitable for businesses.

19 9.19 The existing local loops can handle bandwidths up to 1.1 MHz with a filter( 4Khz bandwidth) for voice devices Note

20 9.20 ADSL is an adaptive technology. The system uses a data rate based on the condition of the local loop line. Note

21 9.21 Figure 9.10 ADSL Modulation: Discrete multitone technique

22 9.22 Upstream: Uses 25 channels (6 to 30), 1 signal, 24 data. 24 x 4000 x 15 = 1.44Mbps. Practically some channels are not used: only 500Kbps, Downstream: 225 channels (31-255), 1 for control 224 x 4000x 15 = 13.4Mbps Practically: 8Mbps

23 9.23 Figure 9.11 Bandwidth division in ADSL

24 9.24 Figure 9.12 ADSL modem

25 9.25 Figure 9.13 DSLAM

26 9.26 Table 9.2 Summary of DSL technologies

27 9.27 9-4 CABLE TV NETWORKS The cable TV network started as a video service provider, but it has moved to the business of Internet access. In this section, we discuss cable TV networks per se; in Section 9.5 we discuss how this network can be used to provide high-speed access to the Internet. Traditional Cable Networks Hybrid Fiber-Coaxial (HFC) Network Topics discussed in this section:

28 9.28 Figure 9.14 Traditional cable TV network

29 9.29 Communication in the traditional cable TV network is unidirectional. Note

30 9.30 Figure 9.15 Hybrid fiber-coaxial (HFC) network

31 9.31 Communication in an HFC cable TV network can be bidirectional. Note

32 9.32 9-5 CABLE TV FOR DATA TRANSFER Cable companies are now competing with telephone companies for the residential customer who wants high-speed data transfer. In this section, we briefly discuss this technology. Bandwidth Sharing CM and CMTS Data Transmission Schemes: DOCSIS Topics discussed in this section:

33 9.33 Competing to provide high speed data transfer. Downstream: 30Mbps (5 bits/HZ x6MHz) Upstream: 12Mbps (2bits/Hz x 6Mhz) Shared Media: Timesharing : One channel per group of subscriber ( for downstream, use of multicasting)

34 9.34 Figure 9.16 Division of coaxial cable band by CATV

35 9.35 Downstream data are modulated using the 64-QAM modulation technique. Note

36 9.36 The theoretical downstream data rate is 30 Mbps. Note

37 9.37 Upstream data are modulated using the QPSK modulation technique. Note

38 9.38 The theoretical upstream data rate is 12 Mbps. Note

39 9.39 Figure 9.17 Cable modem (CM)

40 9.40 Figure 9.18 Cable modem transmission system (CMTS)


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