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dvb

technical overview. http://www.dvb.org. Source. Transmitter. Television. 1 1 0 1 1 0 0 0 1 0 1 1 1 1. 1 1 0 1 1 0 0 0 1 0 1 1 1 1. Transmission medium. 1 1 0 1 1 0 0 0 1 0 1 1 1 1. Source. Television. MPEG-2 DVB Encoder. MPEG-2 DVB Decoder. Digital vs Analogue TV.

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dvb

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  1. technicaloverview http://www.dvb.org

  2. Source Transmitter Television 1 1 0 1 1 0 0 0 1 0 1 1 1 1 1 1 0 1 1 0 0 0 1 0 1 1 1 1 Transmission medium 1 1 0 1 1 0 0 0 1 0 1 1 1 1 Source Television MPEG-2 DVB Encoder MPEG-2 DVB Decoder Digital vs Analogue TV

  3. Why is Digital TV different? • Digital TV squeezes the information that the viewer can’t see or hear out of a standard analogue TV • DVB uses: • Video compression - MPEG-2 • Audio compression - MPEG Layer II • That means you can fit much more TV into the same channel capacity as analogue TV • A satellite transponder using DVB can contain 6-8 times more TV programmes than analogue TV • DVB is also completely digital, opening up the world of EPGs, Internet, data broadcasting, advanced interactive TV ……..

  4. Source video compressed Source audio compressed Data information prepared Video, Audio and Data streams multiplexed Transmission by cable / satellite / MMDS / terrestrial Demultiplexing Decoding View on TV 1 1 0 1 1 0 0 0 1 0 1 1 1 1 1 1 0 1 1 0 0 0 1 0 1 1 1 1 Transmission medium 1 1 0 1 1 0 0 0 1 0 1 1 1 1 Source Television MPEG-2 DVB Encoder MPEG-2 DVB Decoder The DVB System

  5. DVB-S Satellite Transmission MPEG-2 Transport Stream MPEG-2 TS MUX Adaption & Energy Dispersal Outer Reed - Solomon Coder I • Designed to cope witha range of transponder bandwidths (26MHz - 72 MHz) • Single carrier system • DVB-S is like an onion: • centre: payload • series of layers to ensure error protection • adapt the payload for broadcasting implemented satellite chain Inner Convolu- tional Coder Convolu- tional Interleaver Baseband Shaping Modulator Q IF RF Up Converter

  6. DVB-C Cable Transmission MPEG-2 Transport Stream MPEG-2 TS MUX Adaption & Energy Dispersal I • Same core as satellite system to facilitate interworking • No inner convolutional code • System based around 64 QAM, but higher and lower order systems possible • 8MHz channel, with 64 QAM can accommodate about 38.5 Mbits/s Convolu- tional Inter- leaver Outer Reed - Solomon Coder Baseband Shaping Modulator Tuner IF RF Q

  7. DVB-T terrestrial transmission Inner FEC Encoder Outer FEC Encoder l =12 Baseband Interface, Sync Separator Sync Inversion, Energy dispersal Inner Inter-leaver Symbol mapping, Modulator MPEG-2 Transport Stream Generation of reference symbols, pilots and TPS data Data Clock Adaptation of the trans-mission frame Digital to Analogue Transmitter Introduction of guard interval COFDM To Aerial (without hierarchical modulation)

  8. Common circuitry in the DVB Receiver RF & OFDM demod Terrestrial Signal Inner de-interleaver Epuncturing & inner Decoder Sync Decoder Satellite Signal RF & QPSK demod Matched Filter Cable Signal Matched Filter & equaliser RF & QAM demod Differential Decoder Carrier & clock sync recovery OUTPUT Reed- Solomon Decoder Sync inversion & Energy dispersal removal Data Convolutional de-interleaver Output interface Clock

  9. The COFDM signal

  10. Separation of data streams

  11. Multi-resolution QAM When reception conditions and C/N degrade, 16 points of the constellation of the 64 QAM can be used as one point in a QPSK constellation

  12. DVB-T 8k non-hierarchical modulation Useful data rate: 24.88 Mbit/s in a data container defined by 8MHz channel B/W and 64-QAM modulation Programme 1 Programme 2 code rates for inner FEC : 5/6 Programme 3 Programme 4 C/N needed at edge of coverage typically 20 dB (Ricean channel)

  13. DVB-T 8k (hierarchical modulation) Useful data rate: 21.57 Mbit/s within a data container of two levels of robustness Programme 1 64 QAM for ‘fragile’ part 16.59 Mbit/s Programme 2 QPSK for ‘robust’ part 4.98 Mbit/s Programme 3 Baseline Programme 4 With multiresolution QAM used code rates for inner FEC : 5/6, 1/2 C/N needed at edge of coverage (Ricean channel) 22.7 dB for ‘fragile’ part 7.1 dB for ‘robust’ part

  14. The Guard Interval Guard Interval Main Symbol Period TS TG e.g. for a national service Ts = 1ms, TG=0.25ms

  15. CurrentEuropean UHF Spectrum usage Number of transmitters per UHF channel 1400 1000 600 200 21 30 40 50 60 68 UHF channel No.

  16. Implementation Scenario • OFDM DVB-T signal fits between existing analogue UHF carriers sound sound sound sound vision vision vision vision

  17. DVB-T: key features • Same core as DVB-S and DVB-C systems • DVB-S punctured convolutional coding • OFDM based QPSK or QAM modulation very rugged against multipath fading • DVB-T offers a “2k” or and “8k” OFDM option • Two level hierarchical channel coding and modulation possible • Hierarchical MPEG-2 source coding not included • Possibility of national or regional signal frequency networks.

  18. Transmission frame for DVB-T f1 + 7.61 MHz f1 Frequency Carrier-position kmin (-0) Carrier-position kmax Symbol 67 Symbol 0 Symbol 1 Symbol 2 Symbol 3 Continual Pilot TPS-Pilot Continual Pilot 2k-mode: kmax - 1704 Continual Pilot Data 8k-mode: kmax - 6816 TPS-Pilot Scattered Pilot Carrier spacing in 2k-mode - 4464 Hz, in 8k-mode - 1116 Hz

  19. The DVB-T Guard Interval Main signal t Echo 1 t Echo 2 t Co-channel t received signalafter gaincorrection t Tg Twant Ts

  20. COFDM offers variable bit-rate System thresholds for 8-VSB and DVB-T COFDM 25 20 8-VSB 15 COFDM modes SNR (dB) 10 5 0 0 10 20 30 Bit Rate (Mbit/s)

  21. Digital TV is different! Compared with analogue: • digital TV requires less C/N • digital TV is more tolerant of interference BUT • digital systems fail more abruptly Clearly, expect to use new strategies in frequency planning

  22. DVB-T offers choice of strategies • COFDM in DVB-T tolerates multipath (echoes) • COFDM can also tolerate ‘artificial multipath’ of a single-frequency network (SFN) • new concept in spectrum planning • spectrally-efficient in right circumstances • multi-frequency networks (MFNs) • can interleave channels amongst analogue

  23. Choosing a strategy Every country has its own scenario ... • different history of broadcasting TV • different aspirations for the new digital service • different existing spectrum usage • different future spectrum availability • different neighbours ... so each country must find its best solution

  24. Single-frequency networks • SFNs can offer improved spectrum efficiency • examples for DAB, DVB-T • SFN requires an RF channel free over whole service area of network • reason why not chosen for UK DVB-T • best results with a dense network of lower-power transmitters

  25. Conclusions (i) • planning digital TV services is different from analogue TV • countries have different requirements • DVB-T permits choice of planning methods • single-frequency networks (SFNs) • multi-frequency networks (MFNs) thus uniquely able to satisfy different needs of all countries

  26. Conclusions (ii) • SFNs can give greater spectrum efficiency • MFNs can be interleaved amongst analogue • European administrations have done a great deal of work to enable DVB-T introduction • DVB-T is being introduced in Europe • firm plans in place in UK and Sweden for 1998 • other countries will follow

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