DVB-T

List of digital television broadcast standards
DVB standards (countries)
DVB-T (terrestrial) DVB-T2 DVB-S (satellite) DVB-S2 DVB-S2X DVB-C (cable) DVB-C2 DVB-H (handheld) DVB-NGH DVB-SH (satellite)
ATSC standards (countries)
ATSC (terrestrial/cable) ATSC 2.0 ATSC 3.0 ATSC-M/H (mobile/handheld)
ISDB standards (countries)
ISDB-T (terrestrial) ISDB-T International SBTVD/ISDB-Tb (Brazil) ISDB-S (satellite) ISDB-C (cable) 1seg (handheld)
DTMB standards (countries)
DTMB (terrestrial) CMMB (handheld)
DMB standard (countries)
T-DMB (terrestrial) S-DMB (satellite)
Codecs
Video HEVC H.262/MPEG-2 Part 2 H.264/MPEG-4 AVC AVS VC-1 Audio MP2 MP3 AC-3 E-AC-3 AAC HE-AAC
Frequency bands
VHF UHF SHF

DVB-T is an abbreviation for "Digital Video Broadcasting — Terrestrial"; it is the DVB European-based consortium standard for the broadcast transmission of digital terrestrial television that was first published in 1997^[1] and first broadcast in the UK in 1998.^[1] This system transmits compressed digital audio, digital video and other data in an MPEG transport stream, using coded orthogonal frequency-division multiplexing (COFDM or OFDM) modulation. It is also the format widely used worldwide (including North America) for Electronic News Gathering for transmission of video and audio from a mobile newsgathering vehicle to a central receive point.

Basics

Rather than carrying one data carrier on a single radio frequency (RF) channel, COFDM works by splitting the digital data stream into a large number of slower digital streams, each of which digitally modulates a set of closely spaced adjacent sub-carrier frequencies. In the case of DVB-T, there are two choices for the number of carriers known as 2K-mode or 8K-mode. These are actually 1,705 or 6,817 sub-carriers that are approximately 4 kHz or 1 kHz apart.

DVB-T offers three different modulation schemes (QPSK, 16QAM, 64QAM).

DVB-T has been adopted or proposed for digital television broadcasting by many countries (see map), using mainly VHF 7 MHz and UHF 8 MHz channels whereas Taiwan, Colombia, Panama and Trinidad and Tobago use 6 MHz channels. Examples include the UK's Freeview.

The DVB-T Standard is published as EN 300 744, Framing structure, channel coding and modulation for digital terrestrial television. This is available from the ETSI website, as is ETSI TS 101 154, Specification for the use of Video and Audio Coding in Broadcasting Applications based on the MPEG-2 Transport Stream, which gives details of the DVB use of source coding methods for MPEG-2 and, more recently, H.264/MPEG-4 AVC as well as audio encoding systems. Many countries that have adopted DVB-T have published standards for their implementation. These include the D-book in the UK, the Italian DGTVi,^[2] the ETSI E-Book and Scandivia NorDig.

DVB-T has been further developed into newer standards such as DVB-H (Handheld), which was a commercial failure and is no longer in operation, and DVB-T2, which was initially finalised in August 2011.

DVB-T as a digital transmission delivers data in a series of discrete blocks at the symbol rate. DVB-T is a COFDM transmission technique which includes the use of a Guard Interval. It allows the receiver to cope with strong multipath situations. Within a geographical area, DVB-T also allows single-frequency network (SFN) operation, where two or more transmitters carrying the same data operate on the same frequency. In such cases the signals from each transmitter in the SFN needs to be accurately time-aligned, which is done by sync information in the stream and timing at each transmitter referenced to GPS.

The length of the Guard Interval can be chosen. It is a trade off between data rate and SFN capability. The longer the guard interval the larger is the potential SFN area without creating intersymbol interference (ISI). It is possible to operate SFNs which do not fulfill the guard interval condition if the self-interference is properly planned and monitored.

Technical description of a DVB-T transmitter

Scheme of a DVB-T transmission system

With reference to the figure, a short description of the signal processing blocks follows.

Source coding and MPEG-2 multiplexing (MUX): Compressed video, compressed audio, and data streams are multiplexed into MPEG program streams (MPEG-PS's). One or more MPEG-PS's are joined together into an MPEG transport stream (MPEG-TS); this is the basic digital stream which is being transmitted and received by TV sets or home Set Top Boxes (STB). Allowed bitrates for the transported data depend on a number of coding and modulation parameters: it can range from about 5 to about 32 Mbit/s (see the bottom figure for a complete listing).
Splitter: Two different MPEG-TSs can be transmitted at the same time, using a technique called Hierarchical Transmission. It may be used to transmit, for example a standard definition SDTV signal and a high definition HDTV signal on the same carrier. Generally, the SDTV signal is more robust than the HDTV one. At the receiver, depending on the quality of the received signal, the STB may be able to decode the HDTV stream or, if signal strength lacks, it can switch to the SDTV one (in this way, all receivers that are in proximity of the transmission site can lock the HDTV signal, whereas all the other ones, even the farthest, may still be able to receive and decode an SDTV signal).
MUX adaptation and energy dispersal: The MPEG-TS is identified as a sequence of data packets, of fixed length (188 bytes). With a technique called energy dispersal, the byte sequence is decorrelated.
External encoder: A first level of error correction is applied to the transmitted data, using a non-binary block code, a Reed-Solomon RS (204, 188) code, allowing the correction of up to a maximum of 8 wrong bytes for each 188-byte packet.
External interleaver: Convolutional interleaving is used to rearrange the transmitted data sequence, in such a way that it becomes more rugged to long sequences of errors.
Internal encoder: A second level of error correction is given by a punctured convolutional code, which is often denoted in STBs menus as FEC (Forward error correction). There are five valid coding rates: 1/2, 2/3, 3/4, 5/6, and 7/8.
Internal interleaver: Data sequence is rearranged again, aiming to reduce the influence of burst errors. This time, a block interleaving technique is adopted, with a pseudo-random assignment scheme (this is really done by two separate interleaving processes, one operating on bits and another one operating on groups of bits).
Mapper: The digital bit sequence is mapped into a base band modulated sequence of complex symbols. There are three valid modulation schemes: QPSK, 16-QAM, 64-QAM.
Frame adaptation: the complex symbols are grouped in blocks of constant length (1512, 3024, or 6048 symbols per block). A frame is generated, 68 blocks long, and a superframe is built by 4 frames.
Pilot and TPS signals: In order to simplify the reception of the signal being transmitted on the terrestrial radio channel, additional signals are inserted in each block. Pilot signals are used during the synchronization and equalization phase, while TPS signals (Transmission Parameters Signalling) send the parameters of the transmitted signal and to unequivocally identify the transmission cell. The receiver must be able to synchronize, equalize, and decode the signal to gain access to the information held by the TPS pilots. Thus, the receiver must know this information beforehand, and the TPS data is only used in special cases, such as changes in the parameters, resynchronizations, etc.

Spectrum of a DVB-T signal in 8k mode (note the flat-top characteristics)

OFDM Modulation: The sequence of blocks is modulated according to the OFDM technique, using 1705 or 6817 carriers (2k or 8k mode, respectively). Increasing the number of carriers does not modify the payload bit rate, which remains constant.
Guard interval insertion: to decrease receiver complexity, every OFDM block is extended, copying in front of it its own end (cyclic prefix). The width of such guard interval can be 1/32, 1/16, 1/8, or 1/4 that of the original block length. Cyclic prefix is required to operate single frequency networks, where there may exist an ineliminable interference coming from several sites transmitting the same program on the same carrier frequency.
DAC and front-end: The digital signal is transformed into an analogue signal, with a digital-to-analog converter (DAC), and then modulated to radio frequency (VHF, UHF) by the RF front end. The occupied bandwidth is designed to accommodate each single DVB-T signal into 5, 6, 7, or 8 MHz wide channels. The base band sample rate provided at the DAC input depends on the channel bandwidth: it is $f_{s}={\frac {8}{7}}B$ samples/s, where $B$ is the channel bandwidth expressed in Hz.

Available bit rates (Mbit/s) for a DVB-T system in 8 MHz channels
Modulation	Coding rate	Guard interval
Modulation	Coding rate	1/4	1/8	1/16	1/32
QPSK	1/2	4.976	5.529	5.855	6.032
	2/3	6.635	7.373	7.806	8.043
	3/4	7.465	8.294	8.782	9.048
	5/6	8.294	9.216	9.758	10.053
	7/8	8.709	9.676	10.246	10.556
16-QAM	1/2	9.953	11.059	11.709	12.064
	2/3	13.271	14.745	15.612	16.086
	3/4	14.929	16.588	17.564	18.096
	5/6	16.588	18.431	19.516	20.107
	7/8	17.418	19.353	20.491	21.112
64-QAM	1/2	14.929	16.588	17.564	18.096
	2/3	19.906	22.118	23.419	24.128
	3/4	22.394	24.882	26.346	27.144
	5/6	24.882	27.647	29.273	30.160
	7/8	26.126	29.029	30.737	31.668

Technical description of the receiver

The receiving STB adopts techniques which are dual to those ones used in the transmission.

Front-end and ADC: the analogue RF signal is converted to base-band and transformed into a digital signal, using an analogue-to-digital converter (ADC).
Time and frequency synchronization: the digital base band signal is searched to identify the beginning of frames and blocks. Any problems with the frequency of the components of the signal are corrected, too. The property that the guard interval at the end of the symbol is placed also at the beginning is exploited to find the beginning of a new OFDM symbol. On the other hand, continual pilots (whose value and position is determined in the standard and thus known by the receiver) determine the frequency offset suffered by the signal. This frequency offset might have been caused by Doppler effect, inaccuracies in either the transmitter or receiver clock, and so on. Generally, synchronization is done in two steps, either before or after the FFT, in such way to resolve both coarse and fine frequency/timing errors. Pre-FFT steps involve the use of sliding correlation on the received time signal, whereas Post-FFT steps use correlation between the frequency signal and the pilot carriers sequence.
Guard interval disposal: the cyclic prefix is removed.
OFDM demodulation: this is achieved with an FFT.
Frequency equalization: the pilot signals are used to estimate the Channel Transfer Function (CTF) every three subcarriers. The CTF is derived in the remaining subcarriers via interpolation. The CTF is then used to equalize the received data in each subcarrier, generally using a Zero-Forcing method (multiplication by CTF inverse). The CTF is also used to weigh the reliability of the demapped data when they are provided to the Viterbi decoder.
Demapping: since there are Gray-encoded QAM constellations, demapping is done in a "soft" way using nonlinear laws that demap each bit in the received symbol to a more or less reliable fuzzy value between -1 and +1.
Internal deinterleaving
Internal decoding: uses the Viterbi algorithm, with a traceback length larger than that generally used for the basic 1/2 rate code, due to the presence of punctured ("erased") bits.
External deinterleaving
External decoding
MUX adaptation
MPEG-2 demultiplexing and source decoding

Countries and territories using DVB-T and/or DVB-T2

Digital terrestrial television systems worldwide. Countries using DVB-T or DVB-T2 are shown in blue.^[3]

Americas

Bermuda (decided on 10 July 2007)^[4]
Colombia (decided on 28 August 2008) ^[5] (Uses DVB-T/H.264/MPEG-4 for SD and HD. In 2011 is moving to DVB-T2/H.264/MPEG-4) ^[6]
French Guiana
Panama (decided on 12 May 2009) ^[7] (uses DVB-T/MPEG-2 for SD and DVB-T/H.264/MPEG-4 for HD transmissions.)
Haiti
Saint-Pierre and Miquelon
Trinidad and Tobago
Curacao (experimental DVB-T MPEG2)
Suriname (experimental ATSC)
Falkland Islands (In 2008 KTV Ltd. implemented DVB-T, 64QAM, 7/8, 1/32, MPEG2 for both SD and HD transmissions) ^[8]

Europe

Albania (uses MPEG-2 for SD and MPEG-4 AVC /H.264 for HD transmissions.
Andorra
Austria (being phased out end of 2016 in favour of DVB-T2)
Belgium (uses MPEG-2 for SD transmissions)
Belarus (uses DVB-T MPEG-4 AVC /H.264 for SD transmission and DVB-T2 for pay SD transmissions)
Bulgaria (MPEG-4 AVC, FEC=2/3, guard interval - 1/4, 64 QAM. Official simulcast started in March 2013, full switch has been done on 30 September 2013.)^[9]^[10]
Croatia (see DVB-T in Croatia)
Czech Republic (MPEG-2, MPEG-4 experimental in Prague and surroundings)
Cyprus (MPEG-4 video)
Denmark (uses MPEG-4 for SD and HD transmissions. See DVB-T in Denmark.)
Estonia (uses MPEG-4 video)
Faroe Islands
Finland
France (uses MPEG-2 for free SD and MPEG-4 for free HD, pay SD and pay HD transmissions.See Digital terrestrial television#France.)
Germany (usually MPEG-2, SD only, Überallfernsehen
Georgia
Greece (ERT Digital and Digital Union use MPEG-2 but will shift to H.264/MPEG-4 AVC. Digea, ERT / ERT HD and Digital Union (in Region of Thessalia) use H.264/MPEG-4 AVC)
Greenland (Nuuk TV)
Hungary (branded MinDigTV, uses H.264/MPEG-4 AVC video exclusively.)
Iceland^[11]
Ireland (uses MPEG-4 for HD and SD transmissions,see Saorview)
Italy (uses MPEG2 for SD, MPEG 4 AVC for HD)
Latvia (uses H.264/MPEG-4 AVC)
Lithuania (uses H.264/MPEG-4 AVC)
Luxembourg
Macedonia (DVB-T in Macedonia)
Malta
Moldova (uses MPEG-2. MPEG-4 is being tested.)
Montenegro
Netherlands (MPEG-2 SD, operated by Digitenne)
Norway (uses MPEG-4 for SD and HD transmissions)
Poland (uses MPEG-4/H.264 video for SD and HD transmissions; see DVB-T in Poland)
Portugal (uses MPEG-4/H.264 video;)
Romania DVB-T was only used experimentally in two cities, and is being phased out. The official terrestrial broadcasting standard in Romania is DVB-T2, and implementations started in 2015.
Russia (uses DVB-T2/MPEG-4^[12])
Serbia (uses DVB-T2 MPEG-4/H.264 ^[13])
Slovakia (uses MPEG-2 for SD and MPEG-4 for HD, testing DVB-T2/MPEG-4)
Slovenia (uses MPEG-4 video since 2007. See DVB-T in Slovenia)
Spain (uses DVB-T/MPEG-2 for SD and DVB-T/H.264/MPEG-4 for HD transmissions.)
Sweden (uses MPEG-2/MPEG-4) for SD and DVB-T2 with MPEG-4 for SD and HD transmissions. See DVB-T in Sweden.)
Switzerland
Turkey (experimental)
United Kingdom (uses DVB-T/MPEG-2 for SD and DVB-T2/H.264/MPEG-4 for HD transmissions. See DVB-T in United Kingdom.)
Ukraine (uses DVB-T2/MPEG-4 for all nationwide broadcasts)

Oceania

Australia (uses DVB-T/MPEG-2 for SD and some HD transmissions; some HD transmissions use DVB-T/MPEG-4.)
New Zealand (uses MPEG-4/H.264 video; see Freeview New Zealand)

Asia

Afghanistan (uses DVB-T2 MPEG-4 launched April 2015 ^[14]
Bahrain (in assessment)^[15]
Bangladesh (Announced)^[16]
India (uses MPEG-2 for SD and MPEG-4 for HD transmissions)
Indonesia (adopted DVB-T2 on 2 February 2012) ^[17]
Iran (uses DVB-T MPEG-4/H.264/AAC SD :720x576i HD :1920x1080i)
Iraq (started in Kurdistan region-Iraq by MIX Media 31 Dec 2011 uses MPEG-4)
Israel (uses MPEG-4/H.264 video)
Jordan^[15]
Kuwait (will use DVB-T2)^[18]
Kyrgyzstan (DVB-T2)^[19]
Lebanon^[15]
Malaysia (experimental, may also adopt DMB-T/H, also experimenting with DVB-T2 as of 2011, may abandon DVB-T1 and go with DVB-T2 upon launch)
Mongolia (uses DVB-T2)
Myanmar
Oman (in assessment)^[15]
Palestine (in assessment)
Qatar^[20]
Singapore (4 DVB-T Channels on 1 January 2007 and 7 DVB-T2 Channels on 13 December 2013)
Saudi Arabia^[15]
Syria (implement it using DVB-T, MPEG-2 and MPEG-4.)^[15]
Taiwan (uses DVB-T/MPEG-2 for SD and DVB-T/H.264/MPEG-4 for HD transmissions)
Tajikistan (DVB-T2) ^[21]
Thailand (uses DVB-T2 launched 2014)
Vietnam
United Arab Emirates^[15]
Uzbekistan
Yemen^[15]

Africa

Angola
Algeria
Ghana
Cape Verde
Kenya (Will use DVB-T2MPEG-4)
Madagascar (use DVB-T2 on paid network)
Mauritius
Morocco
Namibia
Nigeria
Botswana (ISDB-T on February 26, 2013, first in African countries)
Rwanda (is already using DVB-T1/MPEG-4 and will soon migrate to DVB-T2)
South Africa (will use DVB-T2, after briefly considering ISDB-T)^[22]^[23]
Tunisia (experimental)

Notes

1 2 "What is DVB-T". Retrieved 2009-07-19.
↑ "DGTVi - Per la Televisione Digitale Terrestre".
↑ DVB.org, Official information taken from the DVB website
↑ "About - DVB". Retrieved 26 June 2016.
↑ El Espectador, Colombia adopta el estándar europeo para la tv digital terrestre, 28 August 2008
↑ Evaluamos, TV Digital no ha llegado a toda Colombia y la CNTV ya piensa en modificar la norma, July 2011
↑ "News - DVB". Retrieved 26 June 2016.
↑ "KTV Ltd.". Retrieved 26 June 2016.
↑ "Plan for the introduction of terrestrial digital television broadcasting(DVB-T) in the Republic of Bulgaria" (in Bulgarian). Ministry of Transportation, Information Technology and Communications. Retrieved 2012-12-17.
↑ "Digital Television". NURTS (TV tower operator). Retrieved 2012-12-17.
↑ "Digital Ísland" (in Icelandic). fjarskiptahandbokin.is. Retrieved 2009-10-27.
↑ "Russia adopts DVB-T2".
↑ "ETV: trial DVB-T2 network" (in Serbian). Retrieved 2012-03-22.
↑ "100,000 likes – Oqaab reaches over 1 Mio TV Households". 31 March 2015. Retrieved 26 June 2016.
1 2 3 4 5 6 7 8 "Samart eyes Middle East market for digital TV-enabled smartphone". Retrieved 26 June 2016.
↑ http://www.abu.org.my/Latest_News-@-Digital_TV_services_to_be_introduced_in_Bangladesh_by_2014__.aspx
↑ Standar Penyiaran Televisi Digital
↑ Hawkes, Rebecca (26 February 2014). "Kuwait TV opts for Harris DVB-T2 technology". http://www.rapidtvnews.com/. Retrieved 2014-04-11. External link in |website= (help)
↑ "Kyrgyztelecom launches DVB-T2 & DVB-S2".
↑ "Qatar Goes DVB-T2". https://www.dvb.org. 11 December 2013. External link in |website= (help)
↑ "Tajikistan Confirms DVB-T2 Adoption".
↑ "BusinessDay - State U-turn on Nyanda's digital-TV signal plan". Retrieved 2010-11-26.
↑ "DVB-T2 chosen as digital TV standard". Retrieved 2011-01-03.

References

ETSI Standard: EN 300 744 V1.5.1, Digital Video Broadcasting (DVB); Framing structure, channel coding and modulation for digital terrestrial television, available at ETSI Publications Download Area (This will open ETSI document search engine, to find the latest version of the document enter a search string; free registration is required to download PDF.)

External links

Wikimedia Commons has media related to DVB-T.

Wireless video and data distribution methods

Advanced Wireless Services
Amateur television
Analog television
Digital radio
Digital television
Digital terrestrial television (DTT or DTTV)
Digital Video Broadcasting
- Terrestrial (DVB-T)
- Satellite (DVB-S2)
- Handheld (DVB-H)
Multipoint Video Distribution System (MVDS or DVB-MS)
HomeRF
Instructional Television Fixed Service (ITFS; now known as Educational Broadband Service (EBS))
K_u band
Local Multipoint Distribution Service (LMDS)
Microwave
Mobile broadband
Mobile television
Mobile WiMAX (IEEE 802.16e)
Mobile broadband wireless access (IEEE 802.20)
Multichannel Multipoint Distribution Service (MMDS; now known as Business Radio Service (BRS))
MVDS
MVDDS
Multimedia Broadcast Multicast Service (3G MMMS)
Satellite Internet access
Satellite radio
Satellite television
UWB (IEEE 802.15.3)
Visual sensor network
Wi-Fi (IEEE 802.11)
WiMAX (IEEE 802.16)
WRAN (IEEE 802.22)
Wireless local loop (WLL)
Wireless broadband
Wireless USB
3GPP Long Term Evolution (LTE)
4G

Broadcast video formats

Television

Analog

525 lines	System M NTSC NTSC-J PAL-M

625 lines	PAL System B System D System G System H System I System K PAL-N PALplus SECAM System B System D System G System K System L (SECAM-L)

Audio	BTSC (MTS) EIAJ NICAM SAP Sound-in-Syncs Zweikanalton (A2/IGR)

Hidden signals	Captioning CGMS-A EPG GCR PDC Teletext VBI VEIL VIT VITC WSS XDS

Historical	Pre-1940 Mechanical television 180-line 405-line System A 441-line 819-line MAC MUSE

Digital

Interlaced	SDTV 480i 576i HDTV 1080i

Progressive	LDTV 1seg 240p 288p EDTV 480p 576p HDTV 720p 1080p UHDTV 2160p 4320p

MPEG-2 standards	ATSC DVB ISDB DTMB DVB 3D-TV

MPEG-4 AVC standards	ATSC A/72 DMB DTMB DVB SBTVD 1seg

HEVC standards	ATSC 3.0

Audio	AC-3 (5.1) DTS MPEG-1 Audio Layer II MPEG Multichannel PCM LPCM AAC HE-AAC

Hidden signals	AFD Broadcast flag Captioning CPCM EPG Teletext

Technical issues

14:9 compromise Broadcast-safe Digital cinema (DCI) Display motion blur Moving image formats MPEG transport stream Reverse Standards Conversion Standards conversion Television transmitter Video on demand Video processing Widescreen signaling Templates (Analogue TV Topics)

Telecommunications

History	Beacon Broadcasting Cable TV Communications satellite Computer network Drums Electrical telegraph Fax Heliographs Hydraulic telegraph Internet Mass media Mobile phone Optical telecommunication Optical telegraphy Photophone Prepaid mobile phone Radio Radiotelephone Satellite communications Semaphore Smartphone Smoke signals Telecommunications history Telautograph Telegraphy Teleprinter (teletype) Telephone The Telephone Cases Television Timeline of communication technology Undersea telegraph line Videoconferencing Videophone Videotelephony

Pioneers	Edwin Howard Armstrong John Logie Baird Paul Baran Alexander Graham Bell Tim Berners-Lee Jagadish Chandra Bose Vint Cerf Claude Chappe Donald Davies Lee de Forest Philo Farnsworth Reginald Fessenden Elisha Gray Innocenzo Manzetti Guglielmo Marconi Antonio Meucci Alexander Stepanovich Popov Johann Philipp Reis Nikola Tesla Camille Tissot Alfred Vail Charles Wheatstone Vladimir K. Zworykin

Transmission media	Electromagnetic radiation Electrical cable Free-space optical communication Molecular communication Optical fiber

Network topology and switching	Links Nodes Terminal node Network switching (circuit packet) Telephone exchange

Multiplexing	Space-division Frequency-division Time-division Polarization-division Orbital angular-momentum Code-division

Networks	ARPANET BITNET Cellular network Computer CYCLADES Ethernet FidoNet Internet ISDN LAN Mobile NGN NPL network Public Switched Telephone Radio Telecommunications equipment Television Telex WAN Wireless World Wide Web

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