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Source PDF: /mnt/main/jmc-storage/docs/DVB/ETSI 302 755 Frame struct channel coding, modulation for 2nd gen digital terrestrial TV bcasting sys (DVB-T2) (2009-09).pdf Like all conversions the text below should be fully readable as UTF-8 unicode text. --------------------------------------------------------------- ETSI EN 302 755 V1.1.1 (2009-09) European Standard (Telecommunications series) Digital Video Broadcasting (DVB); Frame structure channel coding and modulation for a second generation digital terrestrial television broadcasting system (DVB-T2) 2 ETSI EN 302 755 V1.1.1 (2009-09) Reference DEN/JTC-DVB-228 Keywords audio, broadcasting, data, digital, DVB, MPEG, terrestrial, TV, video ETSI 650 Route des Lucioles F-06921 Sophia Antipolis Cedex - FRANCE Tel.: +33 4 92 94 42 00 Fax: +33 4 93 65 47 16 Siret N° 348 623 562 00017 - NAF 742 C Association à but non lucratif enregistrée à la Sous-Préfecture de Grasse (06) N° 7803/88 Important notice Individual copies of the present document can be downloaded from: http://www.etsi.org The present document may be made available in more than one electronic version or in print. In any case of existing or perceived difference in contents between such versions, the reference version is the Portable Document Format (PDF). In case of dispute, the reference shall be the printing on ETSI printers of the PDF version kept on a specific network drive within ETSI Secretariat. Users of the present document should be aware that the document may be subject to revision or change of status. Information on the current status of this and other ETSI documents is available at http://portal.etsi.org/tb/status/status.asp If you find errors in the present document, please send your comment to one of the following services: http://portal.etsi.org/chaircor/ETSI_support.asp Copyright Notification No part may be reproduced except as authorized by written permission. The copyright and the foregoing restriction extend to reproduction in all media. © European Telecommunications Standards Institute 2009. © European Broadcasting Union 2009. © European Broadcasting Union 2009. All rights reserved. TM TM TM TM DECT , PLUGTESTS , UMTS , TIPHON , the TIPHON logo and the ETSI logo are Trade Marks of ETSI registered for the benefit of its Members. TM 3GPP is a Trade Mark of ETSI registered for the benefit of its Members and of the 3GPP Organizational Partners. LTE™ is a Trade Mark of ETSI currently being registered for the benefit of its Members and of the 3GPP Organizational Partners. ETSI 3 ETSI EN 302 755 V1.1.1 (2009-09) Contents Intellectual Property Rights ................................................................................................................................7 Foreword.............................................................................................................................................................7 1 Scope ........................................................................................................................................................8 2 References ................................................................................................................................................8 2.1 Normative references ......................................................................................................................................... 8 2.2 Informative references ........................................................................................................................................ 9 3 Definitions, symbols and abbreviations ...................................................................................................9 3.1 Definitions .......................................................................................................................................................... 9 3.2 Symbols ............................................................................................................................................................ 12 3.3 Abbreviations ................................................................................................................................................... 15 4 DVB-T2 System architecture .................................................................................................................17 4.1 System overview .............................................................................................................................................. 17 4.2 System architecture .......................................................................................................................................... 18 4.3 Target performance .......................................................................................................................................... 20 5 Input processing .....................................................................................................................................21 5.1 Mode adaptation ............................................................................................................................................... 21 5.1.1 Input Formats .............................................................................................................................................. 21 5.1.2 Input Interface ............................................................................................................................................. 22 5.1.3 Input Stream Synchronization (Optional) ................................................................................................... 22 5.1.4 Compensating Delay for Transport Streams ............................................................................................... 22 5.1.5 Null Packet Deletion (optional, for TS only, NM and HEM) ..................................................................... 23 5.1.6 CRC-8 encoding (for GFPS and TS, NM only) .......................................................................................... 23 5.1.7 Baseband Header (BBHEADER) insertion ................................................................................................ 24 5.1.8 Mode adaptation sub-system output stream formats ................................................................................... 25 5.2 Stream adaptation ............................................................................................................................................. 28 5.2.1 Scheduler .................................................................................................................................................... 29 5.2.2 Padding ....................................................................................................................................................... 29 5.2.3 Use of the padding field for in-band signalling .......................................................................................... 29 5.2.4 BB scrambling ............................................................................................................................................ 32 6 Bit-interleaved coding and modulation ..................................................................................................32 6.1 FEC encoding ................................................................................................................................................... 32 6.1.1 Outer encoding (BCH) ................................................................................................................................ 33 6.1.2 Inner encoding (LDPC) .............................................................................................................................. 35 6.1.2.1 Inner coding for normal FECFRAME................................................................................................... 35 6.1.2.2 Inner coding for short FECFRAME ...................................................................................................... 36 6.1.3 Bit Interleaver (for 16-QAM, 64-QAM and 256-QAM)............................................................................. 37 6.2 Mapping bits onto constellations ...................................................................................................................... 38 6.2.1 Bit to cell word de-multiplexer ................................................................................................................... 39 6.2.2 Cell word mapping into I/Q constellations ................................................................................................. 42 6.3 Constellation Rotation and Cyclic Q Delay ..................................................................................................... 46 6.4 Cell Interleaver ................................................................................................................................................. 46 6.5 Time Interleaver ............................................................................................................................................... 48 6.5.1 Mapping of Interleaving Frames onto one or more T2-frames ................................................................... 50 6.5.2 Division of Interleaving frames into Time Interleaving Blocks.................................................................. 50 6.5.3 Interleaving of each TI-block...................................................................................................................... 51 6.5.4 Using the three Time Interleaving options with sub-slicing ....................................................................... 53 7 Generation, coding and modulation of Layer 1 signalling .....................................................................55 7.1 Introduction ...................................................................................................................................................... 55 7.2 L1 signalling data ............................................................................................................................................. 56 7.2.1 P1 Signalling data ....................................................................................................................................... 56 7.2.2 L1-Pre Signalling data ................................................................................................................................ 58 7.2.3 L1-post signalling data................................................................................................................................ 61 ETSI 4 ETSI EN 302 755 V1.1.1 (2009-09) 7.2.3.1 Configurable L1-post signalling............................................................................................................ 62 7.2.3.2 Dynamic L1-post signalling .................................................................................................................. 66 7.2.3.3 Repetition of L1-post dynamic data ...................................................................................................... 67 7.2.3.4 L1-post extension field .......................................................................................................................... 68 7.2.3.5 CRC for the L1-post signalling ............................................................................................................. 68 7.2.3.6 L1 padding ............................................................................................................................................ 68 7.3 Modulation and error correction coding of the L1 data .................................................................................... 68 7.3.1 Overview .................................................................................................................................................... 68 7.3.1.1 Error correction coding and modulation of the L1-pre signalling ......................................................... 68 7.3.1.2 Error correction coding and modulation of the L1-post signalling ....................................................... 69 7.3.2 FEC Encoding ............................................................................................................................................. 70 7.3.2.1 Zero padding of BCH information bits ................................................................................................. 70 7.3.2.2 BCH encoding ....................................................................................................................................... 72 7.3.2.3 LDPC encoding ..................................................................................................................................... 72 7.3.2.4 Puncturing of LDPC parity bits ............................................................................................................. 72 7.3.2.5 Removal of zero padding bits................................................................................................................ 73 7.3.2.6 Bit interleaving for L1-post signalling .................................................................................................. 74 7.3.3 Mapping bits onto constellations ................................................................................................................ 74 7.3.3.1 Demultiplexing of L1-post signalling ................................................................................................... 74 7.3.3.2 Mapping into I/Q constellations ............................................................................................................ 75 8 Frame Builder .........................................................................................................................................75 8.1 Frame structure ................................................................................................................................................. 75 8.2 Super-frame ...................................................................................................................................................... 76 8.3 T2-Frame .......................................................................................................................................................... 77 8.3.1 Duration of the T2-Frame ........................................................................................................................... 77 8.3.2 Capacity and structure of the T2-frame ...................................................................................................... 78 8.3.3 Signalling of the T2-frame structure and PLPs ........................................................................................... 81 8.3.4 Overview of the T2-frame mapping ........................................................................................................... 81 8.3.5 Mapping of L1 signalling information to P2 symbol(s) .............................................................................. 82 8.3.6 Mapping the PLPs....................................................................................................................................... 84 8.3.6.1 Allocating the cells of the Interleaving Frames to the T2-Frames ........................................................ 84 8.3.6.2 Addressing of OFDM cells for common PLPs and data PLPs .............................................................. 85 8.3.6.3 Mapping the PLPs to the data cell addresses......................................................................................... 86 8.3.6.3.1 Mapping the Common and Type 1 PLPs ......................................................................................... 86 8.3.6.3.2 Mapping the Type 2 PLPs ............................................................................................................... 87 8.3.7 Auxiliary stream insertion .......................................................................................................................... 88 8.3.8 Dummy cell insertion.................................................................................................................................. 89 8.3.9 Insertion of unmodulated cells in the Frame Closing Symbol .................................................................... 89 8.4 Future Extension Frames (FEF) ....................................................................................................................... 89 8.5 Frequency interleaver ....................................................................................................................................... 90 9 OFDM Generation..................................................................................................................................94 9.1 MISO Processing .............................................................................................................................................. 95 9.2 Pilot insertion ................................................................................................................................................... 95 9.2.1 Introduction................................................................................................................................................. 95 9.2.2 Definition of the reference sequence .......................................................................................................... 96 9.2.2.1 Symbol level ......................................................................................................................................... 97 9.2.2.2 Frame level ............................................................................................................................................ 97 9.2.3 Scattered pilot insertion .............................................................................................................................. 98 9.2.3.1 Locations of the scattered pilots ............................................................................................................ 98 9.2.3.2 Amplitudes of the scattered pilots ......................................................................................................... 99 9.2.3.3 Modulation of the scattered pilots ....................................................................................................... 100 9.2.4 Continual pilot insertion ........................................................................................................................... 100 9.2.4.1 Locations of the continual pilots ......................................................................................................... 100 9.2.4.2 Locations of additional continual pilots in extended carrier mode...................................................... 100 9.2.4.3 Amplitudes of the Continual Pilots ..................................................................................................... 100 9.2.4.4 Modulation of the Continual Pilots ..................................................................................................... 101 9.2.5 Edge pilot insertion ................................................................................................................................... 101 9.2.6 P2 pilot insertion ....................................................................................................................................... 101 9.2.6.1 Locations of the P2 pilots .................................................................................................................... 101 9.2.6.2 Amplitudes of the P2 pilots ................................................................................................................. 101 ETSI 5 ETSI EN 302 755 V1.1.1 (2009-09) 9.2.6.3 Modulation of the P2 pilots ................................................................................................................. 101 9.2.7 Insertion of frame closing pilots ............................................................................................................... 102 9.2.7.1 Locations of the frame closing pilots .................................................................................................. 102 9.2.7.2 Amplitudes of the frame closing pilots ............................................................................................... 102 9.2.7.3 Modulation of the frame closing pilots ............................................................................................... 102 9.2.8 Modification of the pilots for MISO ......................................................................................................... 102 9.3 Dummy tone reservation ................................................................................................................................ 104 9.4 Mapping of data cells to OFDM carriers ........................................................................................................ 104 9.5 IFFT - OFDM Modulation ............................................................................................................................. 104 9.6 PAPR Reduction ............................................................................................................................................ 106 9.6.1 Active Constellation Extension................................................................................................................. 106 9.6.2 PAPR reduction using tone reservation .................................................................................................... 108 9.6.2.1 Algorithm of PAPR reduction using tone reservation ......................................................................... 109 9.7 Guard interval insertion .................................................................................................................................. 110 9.8 P1 Symbol insertion ....................................................................................................................................... 110 9.8.1 P1 Symbol overview ................................................................................................................................. 110 9.8.2 P1 Symbol description .............................................................................................................................. 110 9.8.2.1 Carrier Distribution in P1 symbol ....................................................................................................... 111 9.8.2.2 Modulation of the Active Carriers in P1 ............................................................................................. 112 9.8.2.3 Boosting of the Active Carriers ........................................................................................................... 114 9.8.2.4 Generation of the time domain P1 signal ............................................................................................ 114 9.8.2.4.1 Generation of the main part of the P1 signal ................................................................................. 114 9.8.2.4.2 Frequency Shifted repetition in Guard Intervals............................................................................ 115 10 Spectrum characteristics .......................................................................................................................115 Annex A (normative): Addresses of parity bit accumulators for Nldpc = 64 800 .......................117 Annex B (normative): Addresses of parity bit accumulators for Nldpc = 16 200 ........................124 Annex C (normative): Additional Mode Adaptation tools .............................................................126 C.1 Input stream synchronizer ....................................................................................................................126 C.1.1 Receiver Buffer Model ................................................................................................................................... 128 Annex D (normative): Splitting of input MPEG-2 TSs into the data PLPs and common PLP of a group of PLPs .......................................................................................130 D.1 Overview ..............................................................................................................................................130 D.2 Splitting of input TS into a TSPS stream and a TSPSC stream ...........................................................131 D.2.1 General ........................................................................................................................................................... 131 D.2.2 TS packets carrying any other type of content than Service Description Table (SDT) or Event Information Table (EIT), i.e. with PID values not equal to 0x0011 or 0x0012 .............................................. 132 D.2.3 TS packets carrying Service Description Table (SDT), i.e. with PID=0x0011 .............................................. 132 D.2.4 TS packets carrying Event Information Table (EIT), i.e. with PID=0x0012.................................................. 133 D.2.4.1 Required operations .................................................................................................................................. 134 D.2.4.2 Conditions ................................................................................................................................................. 134 D.3 Receiver Implementation Considerations.............................................................................................136 Annex E (informative): T2-frame structure for Time-Frequency Slicing ......................................137 E.1 General .................................................................................................................................................137 E.2 T2-frame structure ................................................................................................................................138 E.2.1 Duration and capacity of the T2-frame........................................................................................................... 138 E.2.2 Overall structure of the T2-frame ................................................................................................................... 138 E.2.3 Structure of the Type-2 part of the T2-frame ................................................................................................. 139 E.2.4 Restrictions on frame structure to allow tuner switching time ....................................................................... 140 E.2.5 Signalling of the dynamic parameters in a TFS configuration ....................................................................... 141 E.2.6 Indexing of RF channels................................................................................................................................. 141 E.2.7 Mapping the PLPs .......................................................................................................................................... 142 E.2.7.1 Mapping the Common and Type 1 PLPs .................................................................................................. 142 ETSI 6 ETSI EN 302 755 V1.1.1 (2009-09) E.2.7.2 Mapping the Type 2 PLPs ........................................................................................................................ 142 E.2.7.2.1 Allocating the cells of the Interleaving Frame to the T2-Frames ........................................................ 142 E.2.7.2.2 Size of the sub-slices ........................................................................................................................... 143 E.2.7.2.3 Allocation of cell addresses to the sub-slices on RFstart .................................................................... 144 E.2.7.2.4 Allocation of cell addresses to the sub-slices on the other RF channels ............................................. 144 E.2.7.2.5 Mapping the PLP cells to the allocated cell addresses ........................................................................ 146 E.2.8 Auxiliary streams and dummy cells ............................................................................................................... 146 Annex F (normative): Calculation of the CRC word .....................................................................147 Annex G (normative): Locations of the continual pilots .................................................................148 Annex H (normative): Reserved carrier indices for PAPR reduction ...........................................153 Annex I (informative): Transport Stream regeneration and clock recovery using ISCR ............155 Annex J (informative): Pilot patterns ................................................................................................156 Annex K (informative): Allowable sub-slicing values .......................................................................164 Annex L (informative): Bibliography .................................................................................................166 History ............................................................................................................................................................167 ETSI 7 ETSI EN 302 755 V1.1.1 (2009-09) Intellectual Property Rights IPRs essential or potentially essential to the present document may have been declared to ETSI. The information pertaining to these essential IPRs, if any, is publicly available for ETSI members and non-members, and can be found in ETSI SR 000 314: "Intellectual Property Rights (IPRs); Essential, or potentially Essential, IPRs notified to ETSI in respect of ETSI standards", which is available from the ETSI Secretariat. Latest updates are available on the ETSI Web server (http://webapp.etsi.org/IPR/home.asp). Pursuant to the ETSI IPR Policy, no investigation, including IPR searches, has been carried out by ETSI. No guarantee can be given as to the existence of other IPRs not referenced in ETSI SR 000 314 (or the updates on the ETSI Web server) which are, or may be, or may become, essential to the present document. Foreword This European Standard (Telecommunications series) has been produced by Joint Technical Committee (JTC) Broadcast of the European Broadcasting Union (EBU), Comité Européen de Normalisation ELECtrotechnique (CENELEC) and the European Telecommunications Standards Institute (ETSI). NOTE: The EBU/ETSI JTC Broadcast was established in 1990 to co-ordinate the drafting of standards in the specific field of broadcasting and related fields. Since 1995 the JTC Broadcast became a tripartite body by including in the Memorandum of Understanding also CENELEC, which is responsible for the standardization of radio and television receivers. The EBU is a professional association of broadcasting organizations whose work includes the co-ordination of its members' activities in the technical, legal, programme-making and programme-exchange domains. The EBU has active members in about 60 countries in the European broadcasting area; its headquarters is in Geneva. European Broadcasting Union CH-1218 GRAND SACONNEX (Geneva) Switzerland Tel: +41 22 717 21 11 Fax: +41 22 717 24 81 Founded in September 1993, the DVB Project is a market-led consortium of public and private sector organizations in the television industry. Its aim is to establish the framework for the introduction of MPEG-2 based digital television services. Now comprising over 200 organizations from more than 25 countries around the world, DVB fosters market-led systems, which meet the real needs, and economic circumstances, of the consumer electronics and the broadcast industry. National transposition dates Date of adoption of this EN: 7 September 2009 Date of latest announcement of this EN (doa): 31 December 2009 Date of latest publication of new National Standard or endorsement of this EN (dop/e): 30 June 2010 Date of withdrawal of any conflicting National Standard (dow): 30 June 2010 ETSI 8 ETSI EN 302 755 V1.1.1 (2009-09) 1 Scope The present document describes a second generation baseline transmission system for digital terrestrial television broadcasting. It specifies the channel coding/modulation system intended for digital television services and generic data streams. The scope is as follows: • it gives a general description of the Baseline System for digital terrestrial TV; • it specifies the digitally modulated signal in order to allow compatibility between pieces of equipment developed by different manufacturers. This is achieved by describing in detail the signal processing at the modulator side, while the processing at the receiver side is left open to different implementation solutions. However, it is necessary in this text to refer to certain aspects of reception. 2 References References are either specific (identified by date of publication and/or edition number or version number) or non-specific. • For a specific reference, subsequent revisions do not apply. • Non-specific reference may be made only to a complete document or a part thereof and only in the following cases: - if it is accepted that it will be possible to use all future changes of the referenced document for the purposes of the referring document; - for informative references. Referenced documents which are not found to be publicly available in the expected location might be found at http://docbox.etsi.org/Reference. For online referenced documents, information sufficient to identify and locate the source shall be provided. Preferably, the primary source of the referenced document should be cited, in order to ensure traceability. Furthermore, the reference should, as far as possible, remain valid for the expected life of the document. The reference shall include the method of access to the referenced document and the full network address, with the same punctuation and use of upper case and lower case letters. NOTE: While any hyperlinks included in this clause were valid at the time of publication ETSI cannot guarantee their long term validity. 2.1 Normative references The following referenced documents are indispensable for the application of the present document. For dated references, only the edition cited applies. For non-specific references, the latest edition of the referenced document (including any amendments) applies. [1] ETSI TS 101 162: "Digital Video Broadcasting (DVB); Allocation of Service Information (SI) and Data Broadcasting Codes for Digital Video Broadcasting (DVB) systems". ETSI 9 ETSI EN 302 755 V1.1.1 (2009-09) 2.2 Informative references The following referenced documents are not essential to the use of the present document but they assist the user with regard to a particular subject area. For non-specific references, the latest version of the referenced document (including any amendments) applies. [i.1] ISO/IEC 13818-1: "Information technology - Generic coding of moving pictures and associated audio information: Systems". [i.2] ETSI TS 102 606: "Digital Video Broadcasting (DVB); Generic Stream Encapsulation (GSE) Protocol". [i.3] ETSI EN 302 307: "Digital Video Broadcasting (DVB); Second generation framing structure, channel coding and modulation systems for Broadcasting, Interactive Services, News Gathering and other broadband satellite applications (DVB-S2)". [i.4] ETSI EN 300 468: "Digital Video Broadcasting (DVB); Specification for Service Information (SI) in DVB systems". [i.5] ETSI EN 300 744: "Digital Video Broadcasting (DVB); Framing structure, channel coding and modulation for digital terrestrial television". 3 Definitions, symbols and abbreviations 3.1 Definitions For the purposes of the present document, the following terms and definitions apply: active cell: OFDM cell carrying a constellation point for L1 signalling or a PLP auxiliary stream: sequence of cells carrying data of as yet undefined modulation and coding, which may be used for future extensions or as required by broadcasters or network operators BBFRAME: set of Kbch bits which form the input to one FEC encoding process (BCH and LDPC endcoding) common PLP: PLP having one slice per T2-frame, transmitted just after the L1 signalling, which may contain data shared by multiple PLPs configurable L1-signalling: L1 signalling consisting of parameters which remain the same for the duration of one super-frame data cell: OFDM cell which is not a pilot or tone reservation cell (may be an unmodulated cell in the Frame Closing Symbol) data symbol: OFDM symbol in a T2-frame which is not a P1 or P2 symbol data PLP: PLP of Type 1 or Type 2 dummy cell: OFDM cell carrying a pseudo-random value used to fill the remaining capacity not used for L1 signalling, PLPs or Auxiliary Streams dynamic L1-signalling: L1 signalling consisting of parameters which may change from one T2-frame to the next elementary period: time period which depends on the system bandwidth and is used to define the other time periods in the T2 system FEC Block: A set of Ncells OFDM cells carrying all the bits of one LDPC FECFRAME FECFRAME: set of Nldpc (16 200 or 64 800) bits from one LDPC encoding operation ETSI 10 ETSI EN 302 755 V1.1.1 (2009-09) FEF part: part of the super-frame between two T2-frames which contains FEFs NOTE: A FEF part always starts with a P1 symbol. The remaining contents of the FEF part should be ignored by a DVB-T2 receiver. FFT size: nominal FFT size used for a particular mode, equal to the active symbol period Ts expressed in cycles of the elementary period T frame closing symbol: OFDM symbol with higher pilot density used at the end of a T2-frame in certain combinations of FFT size, guard interval and scattered pilot pattern interleaving frame: unit over which dynamic capacity allocation for a particular PLP is carried out, made up of an integer, dynamically varying number of FEC blocks and having a fixed relationship to the T2-frames NOTE: The Interleaving Frame may be mapped directly to one T2-frame or may be mapped to multiple T2-frames. It may contain one or more TI-blocks. L1-post signalling: signalling carried in the P2 symbol carrying more detailed L1 information about the T2 system and the PLPs L1-pre signalling: signalling carried in the P2 symbols having a fixed size, coding and modulation, including basic information about the T2 system as well as information needed to decode the L1-post signalling NOTE: L1-pre signalling remains the same for the duration of a super-frame. MISO group: group (1 or 2) to which a particular transmitter in a MISO network belongs, determining the type of processing which is performed to the data cells and the pilots NOTE: Signals from transmitters in different groups will combine in an optimal manner at the receiver normal symbol: OFDM symbol in a T2-frame which is not a P1, P2 or Frame Closing symbol OFDM cell: modulation value for one OFDM carrier during one OFDM symbol, e.g. a single constellation point OFDM symbol: waveform Ts in duration comprising all the active carriers modulated with their corresponding modulation values and including the guard interval P1 signalling: signalling carried by the P1 symbol and used to identify the basic mode of the DVB-T2 symbol P1 symbol: fixed pilot symbol that carries S1 and S2 signalling fields and is located in the beginning of the frame within each RF-channel NOTE: The P1 symbol is mainly used for fast initial band scan to detect the T2 signal, its timing, frequency offset, and FFT-size. P2 symbol: pilot symbol located right after P1 with the same FFT-size and guard interval as the data symbols NOTE: The number of P2 symbols depends on the FFT-size. The P2 symbols are used for fine frequency and timing synchronization as well as for initial channel estimate. P2 symbols carry L1 and L2 signalling information and may also carry data. PLP_ID: this 8-bit field identifies uniquely a PLP within the T2 system, identified with the T2_system_id NOTE: The same PLP_ID may occur in one or more frames of the super-frame physical layer pipe: physical layer TDM channel that is carried by the specified sub-slices NOTE: A PLP may carry one or multiple services. sub-slice: group of cells from a single PLP, which before frequency interleaving, are transmitted on active OFDM cells with consecutive addresses over a single RF channel ETSI 11 ETSI EN 302 755 V1.1.1 (2009-09) T2 system: second generation terrestrial broadcast system whose input is one or more TS or GSE streams and whose output is an RF signal NOTE: The T2 system: means an entity where one or more PLPs are carried, in a particular way, within a DVB-T2 signal on one or more frequencies. is unique within the T2 network and it is identified with T2_system_id. Two T2 systems with the same T2_system_id and network_id have identical physical layer structure and configuration, except for the cell_id which may differ. is transparent to the data that it carries (including transport streams and services) T2_SYSTEM_ID: this 16-bit field identifies uniquely the T2 system within the T2 network T2 Super-frame: set of T2-frames consisting of a particular number of consecutive T2-frames NOTE: A super-frame may in addition include FEF parts T2-frame: fixed physical layer TDM frame that is further divided into variable size sub-slices. T2-frame starts with one P1 and one or multiple P2 symbols type 1 PLP: PLP having one slice per T2-frame, transmitted before any Type 2 PLPs type 2 PLP: PLP having two or more sub-slices per T2-frame, transmitted after any Type 1 PLPs slice: set of all cells of a PLP which are mapped to a particular T2-frame NOTE: A slice may be divided into sub-slices. time interleaving block (TI-block): set of cells within which time interleaving is carried out, corresponding to one use of the time interleaver memory div: integer division operator, defined as: ⎢x⎥ x div y = ⎢ y⎥ ⎣ ⎦ mod: modulo operator, defined as: ⎢x⎥ x mod y = x − y ⎢ ⎥ ⎣ y⎦ Re(x): real part of x Im(x): imaginary part of x reserved for future use: not defined by the present document but may be defined in future revisions of the present document NOTE: Further requirments concerning the use of fields indicated as "reserved for future use" are given in clause 7.1. for i=0..xxx-1: the corresponding signalling loop is repeated as many times as there are elements of the loop NOTE: If there are no elements, the whole loop is omitted. nnD: digits 'nn' should be interpreted as a decimal number 0xkk: digits 'kk' should be interpreted as a hexadecimal number ETSI 12 ETSI EN 302 755 V1.1.1 (2009-09) 3.2 Symbols For the purposes of the present document, the following symbols apply: ⊕ Exclusive OR / modulo-2 addition operation Δ Guard interval duration λi LDPC codeword bits ηMOD, ηMOD(i) number of transmitted bits per constellation symbol (for PLP i) 1TR Vector containing ones at positions corresponding to reserved carriers and zeros elsewhere a m,l,p Frequency-Interleaved cell value, cell index p of symbol l of T2-frame m ACP Amplitude of the continual pilot cells AP2 Amplitude of the P2 pilot cells ASP Amplitude of the scattered pilot cells bBS,j Bit j of the BB scrambling sequence be,do Output bit of index do from substream e from the bit-to-sub-stream demultiplexer c(x) BCH codeword polynomial C/N Carrier-to-noise power ratio C/N+I Carrier-to-(Noise+Interference) ratio Cdata Number of active cells in one normal symbol CFC Number of active cells in one frame closing symbol cm,l,k Cell value for carrier k of symbol l of T2-frame m CP2 Number of active cells in one P2 symbol CSSS1,i Bit i of the S1 modulation sequence CSSS2,i Bit i of the S2 modulation sequence Ctot Number of active cells in one T2-frame Di Number of cells mapped to each T2-frame of the Interleaving Frame for PLP i Di,aux Number of cells carrying auxiliary stream i in the T2-frame Di,common Number of cells mapped to each T2-frame for common PLP i Di,j Number of cells mapped to each T2-frame for PLP i of type j DL1 Number of OFDM cells in each T2-frame carrying L1 signalling DL1post Number of OFDM cells in each T2-frame carrying L1-post signalling DL1pre Number of OFDM cells in each T2-frame carrying L1-pre signalling dn,s,r,q Time Interleaver input / Cell interleaver output for cell q of FEC block r of TI-block s of Interleaving Frame n DPLP Number of OFDM cells in each T2-frame available to carry PLPs dr,q Cell interleaver output for cell q of FEC block r Dx Difference in carrier index between adjacent scattered-pilot-bearing carriers Dy Difference in symbol number between successive scattered pilots on a given carrier em,l,p Cell value for cell index p of symbol l of T2-frame m following MISO processing fc Centre frequency of the RF signal f_postm,i Cell i of coded and modulated L1-post signalling for T2-frame m f_prem,i Cell i of coded and modulated L1-pre signalling for T2-frame m fq Constellation point normalized to mean energy of 1 fSH Frequency shift for parts 'B' and 'C' of the P1 signal g(x) BCH generator polynomial g1(x), g2(x), …, g12(x) polynomials to obtain BCH code generator polynomial gq OFDM cell value after constellation rotation and cyclic Q delay H(p) Frequency interleaver permutation function, element p H0(p) Frequency interleaver permutation function, element p, for even symbols ETSI 13 ETSI EN 302 755 V1.1.1 (2009-09) H1(p) Frequency interleaver permutation function, element p, for odd symbols IJUMP, IJUMP(i) Frame interval: difference in frame index between successive T2-frames to which a particular PLP is mapped (for PLP i) ij BCH codeword bits which form the LDPC information bits j −1 k' Carrier index relative to the centre frequency k OFDM carrier index Kbch number of bits of BCH uncoded Block Kbit 1024 bits Kext Number of carriers added on each side of the spectrum in extended carrier mode KL1_PADDING Length of L1_PADDING field Kldpc number of bits of LDPC uncoded Block Kmax Carrier index of last (highest frequency) active carrier Kmin Carrier index of first (lowest frequency) active carrier Kmod Modulo value used to calculate continual pilot locations kp1(i) Carrier index k for active carrier i of the P1 symbol Kpost Length of L1-post signalling field including the padding field Kpost_ex_pad Number of information bits in L1-post signalling excluding the padding field Kpre Information length of the L1-pre signalling Ksig Number of signalling bits per FEC block for L1-pre- or L1-post signalling Ktotal Number of OFDM carriers l Index of OFDM symbol within the T2-frame Ldata Number of data symbols per T2-frame including any frame closing symbol but excluding P1 and P2 LF Number of OFDM symbols per T2-frame excluding P1 Lnormal Number of normal symbols in a T2-frame, i.e. not including P1, P2 or any frame closing symbol Lr(q) Cell interleaver permutation function for FEC block r of the TI-block m T2-frame number Maux Number of auxiliary streams in the T2 system Mbit 220 bits Mbit/s Data rate corresponding to 106 bits per second Mcommon Number of common PLPs in the T2 system mi BCH message bits Mj Number of PLPs of type j in the T2 system Mmax Sequence length for the frequency interleaver MSS_DIFFi Bit i of the differentially modulated P1 sequence MSS_SCRi Bit i of the scrambled P1 modulation sequence MSS_SEQi Bit i of the overall P1 modulation sequence MTI Maximum number of cells required in theTI memory n Interleaving Frame index within the super-frame Nbch number of bits of BCH coded Block Nbch_parity Number of BCH parity bits NBLOCKS_IF(n), NBLOCKS_IF(i,n) Number of FEC blocks in Interleaving Frame n (for PLP i) NBLOCKS_IF_MAX Maximum value of NBLOCKS_IF(n) Ncells, Ncells(i) Number of OFDM cells per FEC Block (for PLP i) Ndata Number of data cells in an OFDM symbol (including any unmodulated data cells in the frame closing symbol) Ndummy Number of dummy cells in the T2-frame NFEC_TI (n,s) Number of FEC blocks in TI-block s of Interleaving Frame n NFEF Number of FEF parts in one super-frame ETSI 14 ETSI EN 302 755 V1.1.1 (2009-09) NFFT FFT size Ngroup Number of bit-groups for BCH shortening NL1_mult Number of bits that Npost must be a multiple of Nldpc number of bits of LDPC coded Block NMOD_per_Block Number of modulated cells per FEC block for the L1-post signalling NMOD_Total Total number of modulated cells for the L1-post signalling NP2 Number of P2 symbols per T2-frame Npad Number of BCH bit-groups in which all bits will be padded for L1 signalling NPN Length of the frame-level PN sequence Npost Length of punctured and shortened LDPC codeword for L1-post signalling Npost_FEC_Block Number of FEC blocks for the L1-post signalling Npost_temp Intermediate value used in L1 puncturing calculation Npunc Number of LDPC parity bits to be punctured Npunc_groups Number of parity groups in which all parity bits are punctured for L1 signalling Npunc_temp Intermediate value used in L1 puncturing calculation Nr Number of bits in Frequency Interleaver sequence NRF Number of RF channels used in a TFS system Nsubslices Number of sub-slices per T2-frame on each RF channel Nsubslices_total Number of subslices per T2-frame across all RF channels Nsubstreams Number of substreams produced by the bit-to-sub-stream demultiplexer NT2 Number of T2-frames in a super-frame NTI Number of TI-blocks in an Interleaving Frame p Data cell index within the OFDM symbol in the stages prior to insertion of pilots and dummy tone reservation cells P(r) Cyclic shift value for cell interleaver in FEC block r of the TI-block p1(t) Time-domain complex baseband waveform for the P1 signal p1A(t) Time-domain complex baseband waveform for part 'A' of the P1 signal PI , PI(i) Number of T2-frames to which each Interleaving Frame is mapped (for PLP i) pi LDPC parity bits pnl Frame level PN sequence value for symbol l q Index of cell within coded and modulated LDPC codeword Qldpc Code-rate dependent LDPC constant r FEC block index within the TI-block Reff_16K_LDPC_1_2 Effective code rate of 16K LDPC with nominal rate 1/2 Reff_post Effective code rate of L1-post signalling ri BCH remainder bits Ri Value of element i of the frequency interleaver sequence following bit permutations R'i Value of element i of the frequency interleaver sequence prior to bit permutations rl,k Pilot reference sequence value for carrier k in symbol l RRQD Complex phasor representing constellation rotation angle s Index of TI-block within the Interleaving Frame Si Element i of cell interleaver PRBS sequence T Elementary time period for the bandwidth in use tc Column-twist value for column c TF Duration of one T2-frame TF Frame duration TFEF Duration of one FEF part TP Time interleaving period TP1 Duration of the P1 symbol ETSI 15 ETSI EN 302 755 V1.1.1 (2009-09) TP1A Duration of part 'A' of the P1 signal TP1B Duration of part 'B' of the P1 signal TP1C Duration of part 'C' of the P1 signal TS Total OFDM symbol duration TSF Duration of one super-frame TU Active OFDM symbol duration ui Parity-interleaver output bits vi column-twist-interleaver output bits wi Bit i of the symbol-level reference PRBS ⎣x ⎦ Round towards minus infinity: the most positive integer less than or equal to x ⎤ ⎡x ⎥ ⎢ Round towards plus infinity: the most negative integer greater than or equal to x x* Complex conjugate of x Xj The set of bits in group j of BCH information bits for L1 shortening xm,l,p Complex cell modulation value for cell index p of OFDM symbol l of T2-frame m yi,q Bit i of cell word q from the bit-to-cell-word demultiplexer zq Constellation point prior to normalization π p Permutation operator defining parity bit groups to be punctured for L1 signalling π s Permutation operator defining bit-groups to be padded for L1 signalling The symbols s, t, i, j, k are also used as dummy variables and indices within the context of some clauses or equations. In general, parameters which have a fixed value for a particular PLP for one processing block (e.g. T2-frame, Interleaving Frame, TI-block as appropriate) are denoted by an upper case letter. Simple lower-case letters are used for indices and dummy variables. The individual bits, cells or words processed by the various stages of the system are denoted by lower case letters with one or more subscripts indicating the relevant indices. 3.3 Abbreviations For the purposes of the present document, the following abbreviations apply: 16-QAM 16-ary Quadrature Amplitude Modulation 256-QAM 256-ary Quadrature Amplitude Modulation 64-QAM 64-ary Quadrature Amplitude Modulation ACM Adaptive Coding and Modulation BB BaseBand BCH Bose-Chaudhuri-Hocquenghem multiple error correction binary block code BICM Bit Interleaved Coding and Modulation CBR Constant Bit Rate CCM Constant Coding and Modulation CI Cell Interleaver CRC Cyclic Redundancy Check D Decimal notation DAC Digital to Analogue Conversion DBPSK Differential Binary Phase Shift Keying DFL Data Field Length DNP Deleted Null Packets DVB Digital Video Broadcasting project DVB-T DVB system for Terrestrial broadcasting NOTE: Specified in EN 300 744 [i.5]. DVB-T2 DVB-T2 System as specified in the present document EBU European Broadcasting Union ETSI 16 ETSI EN 302 755 V1.1.1 (2009-09) EIT Event Information Table FEC Forward Error Correction FEF Future Extension Frame FFT Fast Fourier Transform FIFO First In First Out GCS Generic Continuous Stream GF Galois Field GFPS Generic Fixed-length Packetized Stream GS Generic Stream GSE Generic Stream Encapsulation HEM High Efficiency Mode HEX Hexadecimal notation IF Intermediate Frequency IFFT Inverse Fast Fourier Transform IS Interactive Services ISCR Input Stream Time Reference ISI Input Stream Identifier ISSY Input Stream SYnchronizer ISSYI Input Stream SYnchronizer Indicator LDPC Low Density Parity Check (codes) LSB Least Significant Bit MIS Multiple Input Stream MISO Multiple Input, Single Output NOTE: Meaning multiple transmitting antennas but one receiving antenna. MODCOD MODulation and CODing MPEG Moving Pictures Experts Group MSB Most Significant Bit NOTE: In DVB-T2 the MSB is always transmitted first. MSS Modulation Signalling Sequences NA Not Applicable NM Normal Mode NPD Null-Packet Deletion OFDM Orthogonal Frequency Division Multiplex O-UPL Original User Packet Length PAPR Peak to Average Power Ratio PCR Programme Clock Reference PER (MPEG TS) Packet Error Rate PID Packet IDentifier PLL Phase Locked Loop PLP Physical Layer Pipe PRBS Pseudo Random Binary Sequence QEF Quasi Error Free QPSK Quaternary Phase Shift Keying RF Radio Frequency SDT Service Description Table SIS Single Input Stream SISO Single Input Single Output (meaning one transmitting and one receiving antenna) SoAC Sum of AutoCorrelation TDM Time Division Multiplex TF Time/Frequency TFS Time-Frequency Slicing TS Transport Stream TSPS Transport Stream Partial Stream TSPSC Transport Stream Partial Stream Common TTO Time To Output TV TeleVision UP User Packet ETSI 17 ETSI EN 302 755 V1.1.1 (2009-09) UPL User Packet Length VCM Variable Coding and Modulation 4 DVB-T2 System architecture 4.1 System overview The generic T2 system model is represented in figure 1. The system input(s) may be one or more MPEG-2 Transport Stream(s) [i.1] and/or one or more Generic Stream(s) [i.2]. The Input Pre-Processor, which is not part of the T2 system, may include a Service splitter or de-multiplexer for Transport Streams (TS) for separating the services into the T2 system inputs, which are one or more logical data streams. These are then carried in individual Physical Layer Pipes (PLPs). The system output is typically a single signal to be transmitted on a single RF channel. Optionally, the system can generate a second set of output signals, to be conveyed to a second set of antennas in what is called MISO transmission mode. The present document defines a single profile which incorporates time-slicing but not time-frequency-slicing (TFS). Features which would allow a possible future implementation of TFS (for receivers with two tuners/front-ends) can be found in annex E. It is not intended that a receiver with a single tuner should support TFS. Bit Input Input Interleaved Frame OFDM pre- processing Coding & Builder generation processor(s) Modulation TS or T2 system GS inputs Figure 1: High level T2 block diagram The input data streams shall be subject to the constraint that, over the duration of one physical-layer frame (T2-frame), the total input data capacity (in terms of cell throughput, following null-packet deletion, if applicable, and after coding and modulation), shall not exceed the T2 available capacity (in terms of data cells, constant in time) of the T2-frame for the current frame parameters. Typically, this will be achieved by arranging that PLPs within a group of PLPs will always use same modulation and coding (MODCOD), and interleaving depth, and that one or more groups of PLPs with the same MODCOD and interleaving depth originate from a single, constant bit-rate, statistically-multiplexed source. Each group of PLPs may contain one common PLP, but a group of PLPs need not contain a common PLP. When the DVB-T2 signal carries a single PLP there is no common PLP. It is assumed that the receiver will always be able to receive one data PLP and its associated common PLP, if any. More generally, the group of statistically multiplexed services can use variable coding and modulation (VCM) for different services, provided they generate a constant total output capacity (i.e. in terms of cell rate including FEC and modulation). When multiple input MPEG-2 TSs are transmitted via a group of PLPs, splitting of input TSs into TSPS streams (carried via the data PLPs) and a TSPSC stream (carried via the associated common PLP), as described in annex D, shall be performed immediately before the Input processing block shown in figure 1. This processing shall be considered an integral part of an extended DVB-T2 system. The maximum input rate for any TS, including null packets, shall be 72 Mbit/s. The maximum achievable throughput rate, after deletion of null packets when applicable, is more than 50 Mbit/s (in an 8 MHz channel). ETSI 18 ETSI EN 302 755 V1.1.1 (2009-09) 4.2 System architecture The T2 system block diagram is shown in figure 2, which is split into several parts. Figure 2(a) shows the input processing for input mode 'A' (single PLP), and figure 2(b) and figure 2(c) show the case of input mode 'B' (multiple PLPs). Figure 2(d) shows the BICM module and figure 2(e) shows the frame builder module. Figure 2(f) shows the OFDM generation module. Single input To BICM stream Input CRC-8 BB Header Padding BB module interface encoder insertion insertion Scrambler Mode adaptation Stream adaptation Figure 2: System block diagram (a) Input processing module for input mode 'A' (single PLP) Input Input Comp- Null- CRC-8 BB interface Stream ensating packet encoder Header PLP0 Synchroniser delay deletion insertion Input Input Comp- Null- CRC-8 BB interface Stream ensating packet encoder Header PLP1 Synchroniser delay deletion insertion Multiple To stream input adaptation streams Input Input Comp- Null- CRC-8 BB interface Stream ensating packet encoder Header PLPn Synchroniser delay deletion insertion Figure 2(b): Mode adaptation for input mode 'B' (multiple PLP) ETSI 19 ETSI EN 302 755 V1.1.1 (2009-09) frame m frame m-1 In-band frame signalling or (if BB PLP0 delay relevant) padding Scrambler insertion L1 dynPLP0 (m) Scheduler In-band frame signalling or (if BB PLP1 delay relevant) padding Scrambler insertion L1 dynPLP1 (m) To BICM module In-band frame signalling or (if BB PLPn delay relevant) padding Scrambler insertion L1 dynPLPn (m) Dynamic scheduling information L1 dynPLP0-n (m) Figure 2(c): Stream adaptation for input mode 'B' (multiple PLP) FEC encoding Bit Demux Map cells to Constellation Cell Time (LDPC/BCH) interleaver bits to constellations rotation and interleaver interleaver PLP0 cells (Gray mapping) cyclic Q-delay FEC encoding Bit Demux Map cells to Constellation Cell Time (LDPC/BCH) interleaver bits to constellations rotation and interleaver interleaver PLP1 cells (Gray mapping) cyclic Q-delay To frame mapper module FEC encoding Bit Demux Map cells to Constellation Cell Time (LDPC/BCH) interleaver bits to constellations rotation and interleaver interleaver PLPn cells (Gray mapping) cyclic Q-delay FEC encoding Map cells to (Shortened/punctured constellations L1-dynPLP0-n L1 L1-pre LDPC/BCH) signalling generation FEC encoding Bit Demux Map cells to (Shortened/punctured interleaver bits to constellations L1-post LDPC/BCH) cells (Gray mapping) L1 Configuration Figure 2(d): Bit Interleaved Coding and Modulation (BICM) ETSI 20 ETSI EN 302 755 V1.1.1 (2009-09) Assembly of PLP0 common PLP cells Cell Mapper (assembles PLP1 modulated cells of Sub-slice PLPs and L1 processor signalling into To OFDM arrays generation corresponding to Frequency Assembly of OFDM symbols. interleaver data PLP Operates cells according to PLPn dynamic scheduling information produced by scheduler) compensating Assembly of delay L1 cells L1 Signalling Compensates for frame delay in input module and delay in time interleaver Figure 2(e): Frame builder Pilot insertion & Guard P1 Tx1 MISO IFFT PAPR DAC processing dummy tone reduction interval Symbol reservation insertion insertion Tx2 (optional) To transmitter(s) Figure 2(f): OFDM generation 4.3 Target performance If the received signal is above the C/N+I threshold, the Forward Error Correction (FEC) technique adopted in the System is designed to provide a "Quasi Error Free" (QEF) quality target. The definition of QEF adopted for DVB-T2 is "less than one uncorrected error-event per transmission hour at the level of a 5 Mbit/s single TV service decoder", approximately corresponding to a Transport Stream Packet Error Ratio PER < 10-7 before the de-multiplexer. ETSI 21 ETSI EN 302 755 V1.1.1 (2009-09) 5 Input processing 5.1 Mode adaptation The input to the T2 system shall consist of one or more logical data streams. One logical data stream is carried by one Physical Layer Pipe (PLP). The mode adaptation modules, which operate separately on the contents of each PLP, slice the input data stream into data fields which, after stream adaptation, will form baseband frames (BBFRAMEs). The mode adaptation module comprises the input interface, followed by three optional sub-systems (the input stream synchronizer, null packet deletion and the CRC-8 encoder) and then finishes by slicing the incoming data stream into data fields and inserting the baseband header (BBHEADER) at the start of each data field. Each of these sub-systems is described in the following clauses. Each input PLP may have one of the formats specified in clause 5.1.1. The mode adaptation module can process input data in one of two modes, normal mode (NM) or high efficiency mode (HEM), which are described in clauses 5.1.7 and 5.1.8 respectively. NM is in line with the Mode Adaptation in [i.3], whereas in HEM, further stream specific optimizations may be performed to reduce signalling overhead. The BBHEADER (see clause 5.1.7) signals the input stream type and the processing mode. 5.1.1 Input Formats The Input Pre-processor/Service Splitter (see figure 1) shall supply to the Mode Adaptation Module(s) a single or multiple streams (one for each Mode Adaptation Module). In the case of a TS, the packet rate will be a constant value, although only a proportion of the packets may correspond to service data and the remainder may be null-packets. Each input stream (PLP) of the T2 system shall be associated with a modulation and FEC protection mode which is statically configurable. Each input PLP may take one of the following formats: • Transport Stream (TS) [i.1]. • Generic Encapsulated Stream (GSE) [i.2]. • Generic Continuous Stream (GCS) (a variable length packet stream where the modulator is not aware of the packet boundaries). • Generic Fixed-length Packetized Stream (GFPS); this form is retained for compatibility with DVB-S2 [i.3], but it is expected that GSE would now be used instead. A Transport Stream shall be characterized by User Packets (UP) of fixed length O-UPL = 188 × 8 bits (one MPEG packet), the first byte being a Sync-byte (47HEX). It shall be signalled in the BBHEADER TS/GS field, see clause 5.1.7. NOTE: The maximum achievable throughput rate, after deletion of null packets when applicable, is approximately 50,3 Mbit/s (in an 8 MHz channel). A GSE stream shall be characterized by variable length packets or constant length packets, as signalled within GSE packet headers, and shall be signalled in the BBHEADER by TS/GS field, see clause 5.1.7. A GCS shall be characterized by a continuous bit-stream and shall be signalled in the BBHEADER by TS/GS field and UPL = 0D, see clause 5.1.7. A variable length packet stream where the modulator is not aware of the packet boundaries, or a constant length packet stream exceeding 64 kbit, shall be treated as a GCS, and shall be signalled in the BBHEADER by TS/GS field as a GCS and UPL = 0D, see clause 5.1.7. A GFPS shall be a stream of constant-length User Packets (UP), with length O-UPL bits (maximum O-UPL value 64 K), and shall be signalled in the base-band header TS/GS field, see clause 5.1.7. O-UPL is the Original User Packet Length. UPL is the transmitted User Packet Length, as signalled in the BBHEADER. ETSI 22 ETSI EN 302 755 V1.1.1 (2009-09) 5.1.2 Input Interface The input interface subsystem shall map the input into internal logical-bit format. The first received bit will be indicated as the Most Significant Bit (MSB). Input interfacing is applied separately for each single physical layer pipe (PLP), see figure 2. The Input Interface shall read a data field, composed of DFL bits (Data Field Length), where: 0 < DFL < (Kbch - 80) where Kbch is the number of bits protected by the BCH and LDPC codes (see clause 6.1). The maximum value of DFL depends on the chosen LDPC code, carrying a protected payload of Kbch bits. The 10-byte (80 bits) BBHEADER is appended to the front of the data field, and is also protected by the BCH and LDPC codes. The Input Interface shall either allocate a number of input bits equal to the available data field capacity, thus breaking UPs in subsequent data fields (this operation being called "fragmentation"), or shall allocate an integer number of UPs within the data field (no fragmentation). The available data field capacity is equal to Kbch - 80 when in-band signalling is not used (see clause 5.2.3), but less when in-band signalling is used. When the value of DFL < Kbch - 80, a padding field shall be inserted by the stream adapter (see clause 5.2) to complete the LDPC / BCH code block capacity. A padding field, if applicable, shall also be allocated in the first BBFRAME of a T2-Frame, to transmit in-band signalling (whether fragmentation is used or not). 5.1.3 Input Stream Synchronization (Optional) Data processing in the DVB-T2 modulator may produce variable transmission delay on the user information. The Input Stream Synchronizer subsystem shall provide suitable means to guarantee Constant Bit Rate (CBR) and constant end-to-end transmission delay for any input data format. The use of the Input Stream Synchronizer subsystem is optional, except that it shall always be used for PLPs carrying transport streams where the number of FEC blocks per T2-frame may vary. This process shall follow the specification given in annex C, which is similar to [i.3]. Examples of receiver implementation are given in annex I. This process will also allow synchronization of multiple input streams travelling in independent PLPs, since the reference clock and the counter of the input stream synchronizers shall be the same. The ISSY field (Input Stream Synchronization, 2 bytes or 3 bytes) carries the value of a counter clocked at the modulator clock rate (1/T where T is defined in clause 9.5) and can be used by the receiver to regenerate the correct timing of the regenerated output stream. The ISSY field carriage shall depend on the input stream format and on the Mode, as defined in clauses 5.1.7 and 5.1.8 and figures 4 to 8. In Normal Mode the ISSY Field is appended to UPs for packetized streams. In High Efficiency Mode a single ISSY field is transmitted per BBFRAME in the BBHEADER, taking advantage that UPs of a BBFRAME travel together, and therefore experience the same delay/jitter. When the ISSY mechanism is not being used, the corresponding fields of the BBHEADER, if any, shall be set to '0'. A full description of the format of the ISSY field is given in annex C. 5.1.4 Compensating Delay for Transport Streams The interleaving parameters PI and NTI (see clause 6.5), and the frame interval IJUMP (see clause 8.2) may be different for the data PLPs in a group and the corresponding common PLP. In order to allow the Transport Stream recombining mechanism described in annex D without requiring additional memory in the receiver, the input Transport Streams shall be delayed in the modulator following the insertion of Input Stream Synchronization information. The delay (and the indicated value of TTO - see annex C) shall be such that, for a receiver implementing the buffer strategy defined in clause C.1.1, the partial transport streams at the output of the dejitter buffers for the data and common PLPs would be essentially co-timed, i.e. packets with corresponding ISCR values on the two streams would be output within 1ms of one another. ETSI 23 ETSI EN 302 755 V1.1.1 (2009-09) 5.1.5 Null Packet Deletion (optional, for TS only, NM and HEM) Transport Stream rules require that bit rates at the output of the transmitter's multiplexer and at the input of the receiver's demultiplexer are constant in time and the end-to-end delay is also constant. For some Transport-Stream input signals, a large percentage of null-packets may be present in order to accommodate variable bit-rate services in a constant bit-rate TS. In this case, in order to avoid unnecessary transmission overhead, TS null-packets shall be identified (PID = 8191D) and removed. The process is carried-out in a way that the removed null-packets can be re-inserted in the receiver in the exact place where they were originally, thus guaranteeing constant bit-rate and avoiding the need for time-stamp (PCR) updating. When Null Packet Deletion is used, Useful Packets (i.e. TS packets with PID 8 191D), including the optional ISSY ≠ appended field, shall be transmitted while null-packets (i.e. TS packets with PID = 8 191D, including the optional ISSY appended field, may be removed. See figure 3. After transmission of a UP, a counter called DNP (Deleted Null-Packets, 1 byte) shall be first reset and then incremented at each deleted null-packet. When DNP reaches the maximum allowed value DNP = 255D, then if the following packet is again a null-packet this null-packet is kept as a useful packet and transmitted. Insertion of the DNP field (1 byte) shall be after each transmitted UP according to clause 5.1.8 and figures 5 and 6. Reset after DNP DNP insertion Null-packet deletion Counter Useful- DNP (1 byte) packets Insertion after Output Input ut Next Useful Null- Packet packets Input Optional S I S I S I S I S I Y UP S S Y UP S S Y UP S S Y UP S S Y UP S S N N N N N C Y C Y C Y C Y C Y DNP=0 DNP=0 DNP=1 DNP=2 S I D S I D Y UP S N Y UP S N Output N C S Y P N C S Y P Figure 3: Null packet deletion scheme 5.1.6 CRC-8 encoding (for GFPS and TS, NM only) CRC-8 is applied for error detection at UP level (Normal Mode and packetized streams only). When applicable (see clause 5.1.8), the UPL-8 bits of the UP (after sync-byte removal, when applicable) shall be processed by the systematic 8-bit CRC-8 encoder defined in annex F. The computed CRC-8 shall be appended after the UP according to clause 5.1.8 and figure 5. ETSI 24 ETSI EN 302 755 V1.1.1 (2009-09) 5.1.7 Baseband Header (BBHEADER) insertion A fixed length BBHEADER of 10 bytes shall be inserted in front of the baseband data field in order to describe the format of the data field. The BBHEADER shall take one of two forms as shown in figure 4(a) for normal mode (NM) and in figure 4(b) for high efficiency mode (HEM). The current mode (NM or HEM) may be detected by the MODE field (EXORed with the CRC-8 field). CR C -8 M A T YP E UPL D FL SYN C S YNC D (2 b ytes) (2 byte s) (2 b yte s) (1 byte ) (2 b yte s) MODE (1 byte ) Figure 4(a): BBHEADER format (NM) IS S Y CR C -8 M A T YP E IS S Y 2 MS B D FL S YNC D (2 b ytes) (2 byte s) (2 b yte s) 1LS B (2 b yte s) MODE (1 byte ) (1 byte ) Figure 4(b): BBHEADER format (HEM) The use of the bits of the MATYPE field is described below. The use of the remaining fields of the BBHEADER is described in table 2. MATYPE (2 bytes): describes the input stream format and the type of Mode Adaptation as explained in table 1. First byte (MATYPE-1): • TS/GS field (2 bits), Input Stream Format: Generic Packetized Stream (GFPS); Transport Stream; Generic Continuous Stream (GCS); Generic Encapsulated Stream (GSE). • SIS/MIS field (1 bit): Single or Multiple Input Streams (referred to the global signal, not to each PLP). • CCM/ACM field (1 bit): Constant Coding and Modulation or Variable Coding and Modulation. NOTE 1: The term ACM is retained for compatibility with DVB-S2 [i.3]. CCM means that all PLPs use the same coding and modulation, whereas ACM means that not all PLPs use the same coding and modulation. In each PLP, the modulation and coding will be constant in time (although it may be statically reconfigured). • ISSYI (1 bit), (Input Stream Synchronization Indicator): If ISSYI = 1 = active, the ISSY field shall be computed (see annex C) and inserted according to clause 5.1.8. • NPD (1 bit): Null-packet deletion active/not active. If NPD active, then DNP shall be computed and appended after UPs. • EXT (2 bits), media specific (for T2, EXT=0: reserved for future use). Table 1: MATYPE-1 field mapping TS/GS (2 bits) SIS/MIS (1 bit) CCM/ACM (1 bit) ISSYI (1 bit) NPD (1 bit) EXT (2 bits) 00 = GFPS 1 = single 1 = CCM 1 = active 1 = active Reserved for future 11 = TS 0 = multiple 0 = ACM 0 = not-active 0 = not-active use 01 = GCS (see note 1) 10 = GSE NOTE 1: For T2, EXT=reserved for future use and for S2, EXT=RO =transmission roll-off. NOTE 2: For compatibility with DVB-S2 [i.3], when GSE is used with normal mode, it shall be treated as a Continuous Stream and indicated by TS/GS = 01. Second byte (MATYPE-2): • If SIS/MIS = Multiple Input Stream, then second byte = Input Stream Identifier (ISI); else second byte = '0' (reserved for future use). ETSI 25 ETSI EN 302 755 V1.1.1 (2009-09) NOTE 2: The term ISI is retained here for compatibility with DVB-S2 [i.3], but has the same meaning as the term PLP_ID which is used throughout the present document. Table 2: Description of the fields of the BBHEADER Field Size (Bytes) Description MATYPE As described above 2 UPL User Packet Length in bits, in the range [0,65535] 2 DFL Data Field Length in bits, in the range [0,53760] 2 SYNC A copy of the User Packet Sync-byte. In the case of GCS, SYNC=0x00-0xB8 is 1 reserved for transport layer protocol signaling and shall be set according to [1], SYNC=0xB9-0xFF user private SYNCD The distance in bits from the beginning of the DATA FIELD to the beginning of the first 2 transmitted UP which starts in the data field. SYNCD=0D means that the first UP is aligned to the beginning of the Data Field. SYNCD = 65535D means that no UP starts in the DATA FIELD; for GCS, SYNCD is reserved for future use and shall be set to 0D unless otherwise defined. CRC-8 MODE The XOR of the CRC-8 (1-byte) field with the MODE field (1-byte). CRC-8 is the error 1 detection code applied to the first 9 bytes of the BBHEADER (see annex F). MODE (8 bits) shall be: • 0D Normal Mode. • 1D High Efficiency Mode. • Other values: reserved for future use. 5.1.8 Mode adaptation sub-system output stream formats This clause describes the Mode Adaptation processing and fragmentation for the various Modes and Input Stream formats, as well as illustrating the output stream format. Normal Mode, GFPS and TS See clause 5.1.7 for BBHEADER signalling. For Transport Stream, O-UPL=188x8 bits, and the first byte shall be a Sync-byte (47HEX). UPL (the transmitted user packet length) shall initially be set equal to O-UPL The Mode Adaptation unit shall perform the following sequence of operations (see figure 5): • Optional input stream synchronization (see clause 5.1.3); UPL increased by 16D or 24D bits according to ISSY field length; ISSY field appended after each UP. For TS, either the short or long format of ISSY may be used; for GFPS, only the short format may be used. • If a sync-byte is the first byte of the UP, it shall be removed, and stored in the SYNC field of the BBHEADER, and UPL shall be decreased by 8D. Otherwise SYNC in the BBHEADER shall be set to 0 and UPL shall remain unmodified. • For TS only, optional null-packet deletion (see clause 5.1.5); DNP computation and storage after the next transmitted UP; UPL increased by 8D. • CRC-8 computation at UP level (see clause 5.1.6); CRC-8 storage after the UP; UPL increased by 8D. • SYNCD computation (pointing at the first bit of the first transmitted UP which starts in the Data Field) and storage in BBHEADER. The bits of the transmitted UP start with the CRC-8 of the previous UP, if used, followed by the original UP itself, and finish with the ISSY and DNP fields, if used. Hence SYNCD points to the first bit of the CRC-8 of the previous UP. ETSI 26 ETSI EN 302 755 V1.1.1 (2009-09) • For GFPS: UPL storage in BBHEADER. NOTE 1: O-UPL in the modulator may be derived by static setting (GFPS only) or un-specified automatic signalling. NOTE 2: Normal Mode is compatible with DVB-S2 BBFRAME Mode Adaptation [i.3]. SYNCD=0 means that the UP is aligned to the start of the Data Field and when present, the CRC-8 (belonging to the last UP of the previous BBFRAME) will be replaced in the receiver by the SYNC byte or discarded. Tim e U PL TS P acketised Stream only C I D C I D C I D C I D C I D R C O riginal S S N P R C O riginal S S N P R C O riginal S N R C O riginal S N R C O riginal S N S P S P S P 8 UP Y 8 UP Y 8 UP Y 8 UP Y 8 UP Y S YN C D O ptional 80 bits D FL B B HEAD ER D A T A FIELD R M A TYP E U PL D FL S YN C S YN C D C R C -8 (2 b ytes) (2 byte s) (2 b yte s) (1 b yte ) (2 byte s) M O D E (1 byte) Figure 5: Stream format at the output of the MODE ADAPTER, Normal Mode, GFPS and TS High Efficiency Mode, Transport Streams For Transport Streams, the receiver knows a-priori the sync-byte configuration and O-UPL=188x8 bits, therefore UPL and SYNC fields in the BBHEADER shall be re-used to transmit the ISSY field. The Mode Adaptation unit shall perform the following sequence of operations (see figure 6): • Optional input stream synchronization (see clause 5.1.3) relevant to the first complete transmitted UP of the data field; ISSY field inserted in the UPL and SYNC fields of the BBHEADER. • Sync-byte removed, but not stored in the SYNC field of the BBHEADER. • Optional null-packet deletion (see clause 5.1.5); DNP computation and storage after the next transmitted UP. • CRC-8 at UP level shall not be computed nor inserted. • SYNCD computation (pointing at the first bit of the first transmitted UP which starts in the Data Field) and storage in BBHEADER. The bits of the transmitted UP start with the original UP itself after removal of the sync-byte, and finish with the DNP field, if used. Hence SYNCD points to the first bit of the original UP following the sync-byte. • UPL not computed nor transmitted in the BBHEADER. ETSI 27 ETSI EN 302 755 V1.1.1 (2009-09) Tim e Transport S tream D D D D D N O riginal N P O riginal N P O riginal N P O riginal N P O riginal P UP UP UP UP UP S YN C D O ptional 80 bits DFL B B HEA DE R D AT A F IE LD M A T YP E IS S Y DFL IS S Y S YN CD CR C-8 (2 b yte s) (2 M S B ) (2 byte s) (1 LS B ) (2 byte s) M O D E (1 byte) O ptional Figure 6: Stream format at the output of the MODE ADAPTER, High Efficiency Mode for TS, (no CRC-8 computed for UPs, optional single ISSY inserted in the BBHEADER, UPL not transmitted) Normal Mode, GCS and GSE See clause 5.1.7 for BBHEADER signalling. For GCS the input stream shall have no structure, or the structure shall not be known by the modulator. For GSE the first GSE packet shall always be aligned to the data field (no GSE fragmentation allowed). For both GCS and GSE the Mode Adaptation unit shall perform the following sequence of operations (see figure 7): • Set UPL=0D; set SYNC=0x00-0xB8 is reserved for transport layer protocol signaling and should be set according to [1], SYNC=0xB9-0xFF user private; SYNCD is reserved for future use and shall be set to 0D when not otherwise defined. • Null packed deletion (see clause 5.1.5) and CRC-8 computation for Data Field (see clause 5.1.6) shall not be performed. Tim e G eneric C ontinuous S tream 80 bits D FL B B H EA D E R D A T A FIELD M A TYP E UPL DFL S YN C S YNC D CR C-8 (2 b ytes) (2 b ytes) (2 byte s) (1 byte ) (2 byte s) M O D E (1 byte) Figure 7: Stream format at the output of the MODE ADAPTER, Normal Mode (GSE & GCS) ETSI 28 ETSI EN 302 755 V1.1.1 (2009-09) High Efficiency Mode, GSE GSE variable-length or constant length UPs may be transmitted in HEM. If GSE packet fragmentation is used, SYNCD shall be computed. If the GSE packets are not fragmented, the first packet shall be aligned to the Data Field and thus SYNCD shall always be set to 0D. The receiver may derive the length of the UPs from the packet header [i.2], therefore UPL transmission in BBHEADER is not performed. As per TS, the optional ISSY field is transmitted in the BBHEADER. The Mode Adaptation unit shall perform the following sequence of operations (see figure 8): • Optional input stream synchronization (see clause 5.1.3) relevant to the first transmitted UP which starts in the data field; ISSY field inserted in the UPL and SYNC fields of the BBHEADER. • Null-packet Deletion and CRC-8 at UP level shall not be computed nor inserted. • SYNCD computation (pointing at the first bit of the first transmitted UP which starts in the Data Field) and storage in BBHEADER. The transmitted UP corresponds exactly to the original UP itself. Hence SYNCD points to the first bit of the original UP. • UPL not computed nor transmitted. U PL (in G SE H eaders) Tim e GSE UP UP UP UP UP S YN C D U ser Packet 80 bits DFL B B HEA DE R D AT A F IE LD M A T YP E IS S Y DFL IS S Y S YN CD CR C-8 (2 b yte s) (2 M S B ) (2 b yte s) (1 LS B ) (2 b yte s) M O D E (1 byte) O ptional Figure 8: Stream format at the output of the MODE ADAPTER, High Efficiency Mode for GSE, (no CRC-8 computed for UPs, optional single ISSY inserted in the BBHEADER, UPL not transmitted) High Efficiency Mode, GFPS and GCS These modes are not defined (except for the case of TS, as described above). 5.2 Stream adaptation Stream adaptation (see figures 2 and 9) provides: a) scheduling (for input mode 'B'), see clause 5.2.1; b) padding (see clause 5.2.2) to complete a constant length (Kbch bits) BBFRAME and/or to carry in-band signalling according to clause 5.2.3; c) scrambling (see clause 5.2.4) for energy dispersal. The input stream to the stream adaptation module shall be a BBHEADER followed by a DATA FIELD. The output stream shall be a BBFRAME, as shown in figure 9. ETSI 29 ETSI EN 302 755 V1.1.1 (2009-09) 80 bits DFL Kbch-DFL-80 BBHEADER DATA FIELD PADDING AND/OR IN- BAND SIGNALLING BBFRAME (Kbch bits) Figure 9: BBFRAME format at the output of the STREAM ADAPTER 5.2.1 Scheduler In order to generate the required L1 dynamic signalling information, the scheduler must decide exactly which cells of the final T2 signal will carry data belonging to which PLPs, as shown in figure 2(c). Although this operation has no effect on the data stream itself at this stage, the scheduler shall define the exact composition of the frame structure, as described in clause 8. The scheduler works by counting the FEC blocks from each of the PLPs. Starting from the beginning of the Interleaving Frame (which corresponds to either one or more T2-frames - see clause 6.5), the scheduler counts separately the start of each FEC block received from each PLP. The scheduler then calculates the values of the dynamic parameters for each PLP for each T2-frame. This is described in more detail in clause 8 (or in the case of TFS, in annex E). The scheduler then forwards the calculated values for insertion as in-band signalling data, and to the L1 signalling generator. The scheduler does not change the data in the PLPs whilst it is operating. Instead, the data will be buffered in preparation for frame building, typically in the time interleaver memories as described in clause 6.5. 5.2.2 Padding Kbch depends on the FEC rate, as reported in table 5. Padding may be applied in circumstances when the user data available for transmission is not sufficient to completely fill a BBFRAME, or when an integer number of UPs has to be allocated in a BBFRAME. (Kbch-DFL-80) zero bits shall be appended after the DATA FIELD. The resulting BBFRAME shall have a constant length of Kbch bits. 5.2.3 Use of the padding field for in-band signalling In input mode 'B', the PADDING field may also be used to carry in-band signalling. An in-band signalling carrying L1/L2 update information and co-scheduled information is defined as in-band type A. When IN-BAND_FLAG field in L1-post signalling, defined in clause 7.2.3, is set to '0', the in-band type A is not carried in the PADDING field. The use of in-band type A is mandatory for PLPs that appear in every T2-frame and for which one Interleaving Frame is mapped to one T2-frame (i.e. the values for PI and IJUMP for the current PLP are both equal to 1; see clauses 8.3.6.1 and 8.2). The L1 dynamic signalling for Interleaving Frame n+1 (Interleaving Frame n+2 in the case of TFS, see annex E) of a PLP or multiple PLPs is inserted in the PADDING field of the first BBFRAME of Interleaving Frame n of each PLP. If NUM_OTHER_PLP_IN_BAND=0 (see below), the relevant PLP carries only its own in-band L1 dynamic information. If NUM_OTHER_PLP_IN_BAND>0, it carries L1 dynamic information of other PLPs as well as its own information, for shorter channel switching time. Figure 10 illustrates the signalling format of the PADDING field when in-band type A is delivered. ETSI 30 ETSI EN 302 755 V1.1.1 (2009-09) Figure 10: PADDING format at the output of the STREAM ADAPTER for in-band type A Table 3 indicates the detailed use of fields for in-band signalling. Table 3: Padding field mapping for in-band type A Field Size PADDING_TYPE 2 bits PLP_L1_CHANGE_COUNTER 8 bits RESERVED_1 8 bits For j=0..PI-1 { SUB_SLICE_INTERVAL 22 bits START_RF_IDX 3 bits CURRENT_PLP_START 22 bits RESERVED_2 8 bits } CURRENT_PLP_NUM_BLOCKS 10 bits NUM_OTHER_PLP_IN_BAND 8 bits For i=0..NUM_OTHER_PLP_IN_BAND-1 { PLP_ID 8 bits PLP_START 22 bits PLP_NUM_BLOCKS 10 bits RESERVED_3 8 bits } For j=0..PI-1 { TYPE_2_START 22 bits } RESERVED_4 Remainder of BBFRAME PADDING_TYPE: This 2-bit field indicates the type of the PADDING field within the current BBFRAME. The mapping of different types is given in table 4. Table 4: The mapping of PADDING types Value Type 00 In-band type A 01 Reserved for future use 10 Reserved for future use 11 Reserved for future use PLP_L1_CHANGE_COUNTER: This 8-bit field indicates the number of super-frames ahead where the configuration (i.e. the contents of the fields in the L1-pre signalling or the configurable part of the L1-post signalling) will change in a way that affects the PLPs referred to by this in-band signalling field. The next super-frame with changes in the configuration is indicated by the value signalled within this field. If this field is set to the value '0', it means that no scheduled change is foreseen. E.g. value '1' indicates that there is change in the next super-frame. This counter shall always start counting down from a minimum value of 2. RESERVED_1: This 8-bit field is reserved for future use. ETSI 31 ETSI EN 302 755 V1.1.1 (2009-09) For the current PLP, the in-band signalling shall be repeated, in order of T2-frame index, for each of the PI T2-frames to which the next Interleaving Frame is mapped (see clauses 6.5.1 and 8.3.6.1). In the case of TFS, the next-but-one Interleaving Frame shall be signalled. The following fields appear in the PI loop: SUB_SLICE_INTERVAL: This 22-bit field indicates the number of OFDM cells from the start of one sub-slice of one PLP to the start of the next sub-slice of the same PLP on the same RF channel for the relevant T2-frame. If the number of sub-slices per frame equals the number of RF channels, then the value of this field indicates the number of OFDM cells on one RF channel for the type 2 data PLPs in the relevant T2-frame. If there are no type 2 PLPs, this field shall be set to '0'. The use of this parameter is defined with greater detail in clause 8.3.6.3.2. START_RF_IDX: This 3-bit field indicates the ID of the starting frequency of the TFS scheduled frame, for the relevant T2-frame, as described in annex E. The starting frequency within the TFS scheduled frame may change dynamically. When TFS is not used, the value of this field shall be set to '0'. CURRENT_PLP_START: This 22-bit field signals the start position of the current PLP in the relevant T2-frame. The start position is specified using the addressing scheme described in clause 8.3.6.2. RESERVED_2: This 8-bit field is reserved for future use. CURRENT_PLP_NUM_BLOCKS: This 10-bit field indicates the number of FEC blocks used for the current PLP within the next Interleaving Frame (or the next-but-one Interleaving Frame in the case of TFS). NUM_OTHER_PLP_IN_BAND: This 8-bit field indicates the number of other PLPs excluding the current PLP for which L1 dynamic information is delivered via the current in-band signalling. This mechanism shall only be used when the values for PI and IJUMP for the current PLP are both equal to 1 (otherwise NUM_OTHER_PLP_IN_BAND shall be set to zero and the loop will be empty). The following fields appear in the NUM_OTHER_PLP_IN_BAND loop: PLP_ID: This 8-bit field identifies uniquely a PLP. If the PLP_ID corresponds to a PLP whose PLP_TYPE (see clause 7.2.3.1) is one of the values reserved for future use, the remaining bits of this other PLP loop shall still be carried, and they too shall be reserved for future use and shall be ignored. PLP_START: This 22-bit field signals the start position of PLP_ID in the next T2-frame (or the next-but-one T2-frame in the case of TFS). When PLP_ID is not mapped to the relevant T2-frame, this field shall be set to '0'. The start position is specified using the addressing scheme described in clause 8.3.6.2. PLP_NUM_BLOCKS: This 10-bit field indicates the number of FEC blocks for PLP_ID contained in the Interleaving Frame which is mapped to the next T2-frame (or the Interleaving Frame which is mapped to the next-but-one T2-frame in the case of TFS). It shall have the same value for every T2-frame to which the Interleaving Frame is mapped. When PLP_ID is not mapped to the next T2-frame (or the next-but-one T2-frame in the case of TFS), this field shall be set to '0'. RESERVED_3: This 8-bit field is reserved for future use. TYPE_2_START: This 22-bit field indicates the start position of the first of the type 2 PLPs using the cell addressing scheme defined in 8.3.6.2. If there are no type 2 PLPs, this field shall be set to '0'. It has the same value on every RF channel, and with TFS can be used to calculate when the sub-slices of a PLP are 'folded' (see clause E.2.7.2.4). The value of TYPE_2_START shall be signalled for each of the PI T2-frames to which the next Interleaving Frame is mapped (see clauses 6.5.1 and 8.3.6.1). In the case of TFS, the next-but-one Interleaving Frame shall be signalled. RESERVED_4: The remaining bits in the BBFRAME, if any, shall currently be set to '0' and are reserved for future use. If there is no user data for a PLP in a given Interleaving Frame, the scheduler shall either: • allocate no blocks (previously indicated by PLP_NUM_BLOCKS equal to 0); or • allocate one block (previously indicated by PLP_NUM_BLOCKS equal to 1), with DFL=0, to carry the in-band signalling (and the remainder of the BBFRAME will be filled with padding by the input processor). ETSI 32 ETSI EN 302 755 V1.1.1 (2009-09) NOTE 1: In the case when the value of PLP_NUM_BLOCKS referring to the current Interleaving Frame equals 0 (as signalled in a previous Interleaving Frame), the dynamic signalling normally carried in the in-band signalling for the relevant PLP will still be present in the L1 signalling in P2 (see clause 7.2.3.2), and may also be carried in the in-band signalling of another PLP. NOTE 2: In order to allow in-band signalling to be used together with GSE [i.2] it is assumed that, for Baseband frames containing in-band signalling, the data field, containing the GSE packets, does not fill the entire Baseband frame capacity, but leaves space for a padding field including in-band signalling at the end of the Baseband frame. 5.2.4 BB scrambling The complete BBFRAME shall be randomized. The randomization sequence shall be synchronous with the BBFRAME, starting from the MSB and ending after Kbch bits. The scrambling sequence shall be generated by the feed-back shift register of figure 11. The polynomial for the Pseudo Random Binary Sequence (PRBS) generator shall be: 1 + X14 + X15 Loading of the sequence (100101010000000) into the PRBS register, as indicated in figure 11, shall be initiated at the start of every BBFRAME. Initia lization seque nce 1 0 0 1 0 1 0 1 0 0 0 0 0 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 0 0 0 0 0 0 1 1 .... EXOR clear BBFRAME input Randomised BBFRAME output Figure 11: Possible implementation of the PRBS encoder 6 Bit-interleaved coding and modulation 6.1 FEC encoding This sub-system shall perform outer coding (BCH), Inner Coding (LDPC) and Bit interleaving. The input stream shall be composed of BBFRAMEs and the output stream of FECFRAMEs. Each BBFRAME (Kbch bits) shall be processed by the FEC coding subsystem, to generate a FECFRAME (Nldpc bits). The parity check bits (BCHFEC) of the systematic BCH outer code shall be appended after the BBFRAME, and the parity check bits (LDPCFEC) of the inner LDPC encoder shall be appended after the BCHFEC field, as shown in figure 12. ETSI 33 ETSI EN 302 755 V1.1.1 (2009-09) Nbch= Kldpc Kbch Nbch-Kbch Nldpc-Kldpc BBFRAME BCHFEC LDPCFEC (Nldpc bits) Figure 12: format of data before bit interleaving (Nldpc = 64 800 bits for normal FECFRAME, Nldpc = 16 200 bits for short FECFRAME) Table 5(a) gives the FEC coding parameters for the normal FECFRAME (Nldpc = 64 800 bits) and table 5(b) for the short FECFRAME (Nldpc = 16 200 bits). Table 5(a): coding parameters (for normal FECFRAME Nldpc = 64 800) LDPC BCH Uncoded BCH coded block Nbch BCH Nbch-Kbch LDPC Coded Block Code Block Kbch LDPC Uncoded Block t-error correction Nldpc Kldpc 1/2 32 208 32 400 12 192 64 800 3/5 38 688 38 880 12 192 64 800 2/3 43 040 43 200 10 160 64 800 3/4 48 408 48 600 12 192 64 800 4/5 51 648 51 840 12 192 64 800 5/6 53 840 54 000 10 160 64 800 Table 5(b): coding parameters (for short FECFRAME Nldpc = 16 200) LDPC BCH Uncoded BCH coded block Nbch BCH Nbch-Kbch Effective LDPC Coded Code Block Kbch LDPC Uncoded Block t-error LDPC Rate Block identifier Kldpc correction Kldpc/16 200 Nldpc 1/4 3 072 3 240 12 168 1/5 16 200 (see note) 1/2 7 032 7 200 12 168 4/9 16 200 3/5 9 552 9 720 12 168 3/5 16 200 2/3 10 632 10 800 12 168 2/3 16 200 3/4 11 712 11 880 12 168 11/15 16 200 4/5 12 432 12 600 12 168 7/9 16 200 5/6 13 152 13 320 12 168 37/45 16 200 NOTE: This code rate is only used for protection of L1-pre signalling and not for data. NOTE: For Nldpc = 64 800 as well as for Nldpc =16 200 the LDPC code rate is given by Kldpc / Nldpc. In table 5(a) the LDPC code rates for Nldpc = 64 800 are given by the values in the 'LDPC Code' column. In table 5(b) the LDPC code rates for Nldpc = 16 200 are given by the values in the 'Effective LDPC rate' column, i.e. for Nldpc = 16 200 the 'LDPC Code identifier' is not equivalent to the LDPC code rate. 6.1.1 Outer encoding (BCH) A t-error correcting BCH (Nbch, Kbch) code shall be applied to each BBFRAME to generate an error protected packet. The BCH code parameters for Nldpc = 64 800 are given in table 5(a) and for Nldpc = 16 200 in table 5(b). The generator polynomial of the t error correcting BCH encoder is obtained by multiplying the first t polynomials in Table 6(a) for Nldpc = 64 800 and in table 6(b) for Nldpc = 16 200. ETSI 34 ETSI EN 302 755 V1.1.1 (2009-09) Table 6(a): BCH polynomials (for normal FECFRAME Nldpc = 64 800) g1(x) 1+x2+x3+x5+x16 g2(x) 1+x+x4+x5+x6+x8+x16 g3(x) 1+x2+x3+x4+x5+x7+x8+x9+x10+x11+x16 g4(x) 1+x2+x4+x6+x9+x11+x12+x14+x16 g5(x) 1+x+x2+x3+x5+x8+x9+x10+x11+x12+x16 g6(x) 1+x2+x4+x5+x7+x8+x9+x10+x12+x13+x14+x15+x16 g7(x) 1+x2+x5+x6+x8+x9+x10+x11+x13+x15+x16 g8(x) 1+x+x2+x5+x6+x8+x9+x12+x13+x14+x16 g9(x) 1+x5+x7+x9+x10+x11+x16 g10(x) 1+x+x2+x5+x7+x8+x10+x12+x13+x14+x16 g11(x) 1+x2+x3+x5+x9+x11+x12+x13+x16 g12(x) 1+x+x5+x6+x7+x9+x11+x12+x16 Table 6(b): BCH polynomials (for short FECFRAME Nldpc = 16 200) g1(x) 1+x+x3+x5+x14 g2(x) 1+x6+x8+x11+x14 g3(x) 1+x+x2+x6+x9+x10+x14 g4(x) 1+x4+x7+x8+x10+x12+x14 g5(x) 1+x2+x4+x6+x8+x9+x11+x13+x14 g6(x) 1+x3+x7+x8+x9+x13+x14 g7(x) 1+x2+x5+x6+x7+x10+x11+x13+x14 g8(x) 1+x5+x8+x9+x10+x11+x14 g9(x) 1+x+x2+x3+x9+x10+x14 g10(x) 1+x3+x6+x9+x11+x12+x14 g11(x) 1+x4+x11+x12+x14 g12(x) 1+x+x2+x3+x5+x6+x7+x8+x10+x13+x14 The bits of the baseband frame form the message bits M = (mK bch −1 , mK bch − 2 ,..., m1 , m0 ) for BCH encoding, where mK bch −1 is the first bit of the BBHEADER and m0 is the last bit of the BBFRAME (or padding field if present). BCH encoding of information bits M = ( mKbch −1 , mKbch − 2 ,..., m1 , m0 ) onto a codeword is achieved as follows: kbch −1 • Multiply the message polynomial m(x) = mK bch −1 x + mKbch −2 x kbch −2 + ... + m1 x + m0 by x Nbch − Kbch . N bch − K bch • Divide x m(x) by g(x), the generator polynomial. Let d ( x) = d Nbch − Kbch −1 x Nbch − Kbch −1 + ... + d1 x + d 0 be the remainder. • Construct the output codeword I, which forms the information word I for the LDPC coding, as follows: I = (i0 , i1 ,..., i N bch −1 ) = (mKbch −1 , mKbch −2 ,..., m1 , m0 , d Nbch − Kbch −1 , d Nbch − Kbch − 2 ,..., d1 , d 0 ) N bch − K bch NOTE: The equivalent codeword polynomial is c( x ) = x m( x ) + d ( x ) . ETSI 35 ETSI EN 302 755 V1.1.1 (2009-09) 6.1.2 Inner encoding (LDPC) The LDPC encoder treats the output of the outer encoding, I = (i0 , i1 ,..., iKldpc −1 ) , as an information block of size K ldpc = N BCH , and systematically encodes it onto a codeword of size N ldpc , where: Λ Λ ( ) = λ0 , λ1, λ2 ,..., λ N LDPC −1 = (i0 , i1,..., iK ldpc −1 , p0 , p1 ,... p N ldpc − K ldpc −1 ) . The LDPC code parameters ( N ldpc , K ldpc ) are given in table 5. 6.1.2.1 Inner coding for normal FECFRAME The task of the encoder is to determine N ldpc − K ldpc parity bits ( p0 , p1 ,..., pnldpc − k ldpc −1 ) for every block of k ldpc information bits, (i0 , i1 ,..., iK ldpc −1 ) . The procedure is as follows: • Initialize p0 = p1 = p2 = ... = p Nldpc − Kldpc −1 = 0 • Accumulate the first information bit, i0 , at parity bit addresses specified in the first row of tables A.1 through A.6. For example, for rate 2/3 (see table A.3), (all additions are in GF(2)): p317 = p317 ⊕ i0 p6700 = p6700 ⊕ i0 p2255 = p2255 ⊕ i0 p9101 = p9101⊕ i0 p2324 = p2324 ⊕ i0 p10057 = p10057 ⊕ i0 p2723 = p2723 ⊕ i0 p12739 = p12739 ⊕ i0 p3538 = p3538 ⊕ i0 p17407 = p17407 ⊕ i0 p3576 = p3576 ⊕ i0 p21039 = p21039 ⊕ i0 p6194 = p6194 ⊕ i0 • For the next 359 information bits, i m , m = 1, 2, ..., 359 accumulate im at parity bit addresses {x + m mod 360 × Qldpc } mod( N ldpc − K ldpc ) where x denotes the address of the parity bit accumulator corresponding to the first bit i0 , and Qldpc is a code rate dependent constant specified in table 7(a). Continuing with the example, Qldpc = 60 for rate 2/3. So for example for information bit i1 , the following operations are performed: p377 = p377 ⊕ i1 p6760 = p6760 ⊕ i1 p2315 = p2315 ⊕ i1 p9161 = p9161⊕ i1 p2384 = p2384 ⊕ i1 p10117 = p10117 ⊕ i1 p2783 = p2783 ⊕ i1 p12799 = p12799 ⊕ i1 p3598 = p3598 ⊕ i1 p17467 = p17467 ⊕ i1 p3636 = p3636 ⊕ i1 p21099 = p21099 ⊕ i1 p6254 = p6254 ⊕ i1 ETSI 36 ETSI EN 302 755 V1.1.1 (2009-09) • For the 361st information bit i360 , the addresses of the parity bit accumulators are given in the second row of the tables A.1 through A.6. In a similar manner the addresses of the parity bit accumulators for the following 359 information bits im , m = 361, 362, ..., 719 are obtained using the formula {x + (m mod 360) × Qldpc } mod( N ldpc − K ldpc ) where x denotes the address of the parity bit accumulator corresponding to the information bit i360 , i.e. the entries in the second row of the tables A.1 through A.6. • In a similar manner, for every group of 360 new information bits, a new row from tables A.1 through A.6 are used to find the addresses of the parity bit accumulators. After all of the information bits are exhausted, the final parity bits are obtained as follows: • Sequentially perform the following operations starting with i = 1 . pi = pi ⊕ pi −1 , i = 1,2,..., N ldpc − K ldpc − 1 • Final content of pi , i = 0,1,.., N ldpc − K ldpc − 1 is equal to the parity bit pi . Table 7(a): Qldpc values for normal frames Code Rate Qldpc 1/2 90 3/5 72 2/3 60 3/4 45 4/5 36 5/6 30 6.1.2.2 Inner coding for short FECFRAME K ldpc BCH encoded bits shall be systematically encoded to generate N ldpc bits as described in clause 6.1.2.1, replacing Table 7(a) with table 7(b), the tables of annex A with the tables of annex B. Table 7(b): Qldpc values for short frames Code Rate Qldpc 1/4 36 1/2 25 3/5 18 2/3 15 3/4 12 4/5 10 5/6 8 ETSI 37 ETSI EN 302 755 V1.1.1 (2009-09) 6.1.3 Bit Interleaver (for 16-QAM, 64-QAM and 256-QAM) The output of the LDPC encoder shall be bit interleaved, which consists of parity interleaving followed by column Λ twist interleaving. The parity interleaver output is denoted by U and the column twist interleaver output by V. In the parity interleaving part, parity bits are interleaved by: ui = λi for 0 ≤ i < Kldpc (information bits are not interleaved.) ; u K ldpc + 360t + s = λK ldpc + Qldpc ⋅s + t for 0 ≤ s < 360, 0 ≤ t < Qldpc where Qldpc is defined in table 7(a)/(b). The configuration of the column twist interleaving for each modulation format is specified in table 8. Table 8: Bit Interleaver structure Rows Nr Columns Modulation Nc Nldpc = 64 800 Nldpc = 16 200 16-QAM 8 100 2 025 8 64-QAM 5 400 1 350 12 4 050 - 16 256-QAM - 2 025 8 In the column twist interleaving part, the data bits ui from the parity interleaver are serially written into the column-twist interleaver column-wise, and serially read out row-wise (the MSB of BBHEADER is read out first) as shown in Figure 13, where the write start position of each column is twisted by tc according to table 9. This interleaver is described by the following: The input bit ui with index i, for 0 ≤ i < Nldpc, is written to column ci, row ri of the interleaver, where: ci = i div N r ri = i + tci mod N r The output bit vj with index j, for 0 ≤ j < Nldpc, is read from row rj, column cj, where r j = j div N c c j = j mod N c So for 64-QAM and Nldpc = 64 800, the output bit order of column twist interleaving would be: (v0 , v1, v2 ,...v64799 ) = (u0 , u5400 , u16198 ,..., u53992 , u59231, u64790 ) . A longer list of the indices on the right hand side, illustrating all 12 columns, is: 0, 5 400, 16 198, 21 598, 26 997, 32 396, 37 796, 43 195, 48 595, 53 993, 59 392, 64 791, …… 5 399, 10 799, 16 197, 21 597, 26 996, 32 395, 37 795, 43 194, 48 594, 53 992, 59 391, 64 790. ETSI 38 ETSI EN 302 755 V1.1.1 (2009-09) MSB WRITE READ of BBHeader Row 1 Write start position is twisted by tc Row 8100 Column 1 Column 8 LSB of FECFRAME Figure 13: Bit Interleaving scheme for normal FECFRAME length and 16-QAM Table 9: Column twisting parameter tc Columns Twisting parameter tc Modulation Nldpc Nc Col. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 64 800 0 0 2 4 4 5 7 7 - - - - - - - - 16-QAM 8 16 200 0 0 0 1 7 20 20 21 - - - - - - - - 64 800 0 0 2 2 3 4 4 5 5 7 8 9 - - - - 64-QAM 12 16 200 0 0 0 2 2 2 3 3 3 6 7 7 - - - - 16 64 800 0 2 2 2 2 3 7 15 16 20 22 22 27 27 28 32 256-QAM 8 16 200 0 0 0 1 7 20 20 21 - - - - - - - - 6.2 Mapping bits onto constellations Each FECFRAME (which is a sequence of 64 800 bits for normal FECFRAME, or 16 200 bits for short FECFRAME), shall be mapped to a coded and modulated FEC block by first de-multiplexing the input bits into parallel cell words and then mapping these cell words into constellation values. The number of output data cells and the effective number of bits per cell ηMOD is defined by table 10. De-multiplexing is performed according to clause 6.2.1 and constellation mapping is performed according to clause 6.2.2. Table 10: Parameters for bit-mapping into constellations LDPC block length Number of output Modulation mode ηMOD (Nldpc) data cells 256-QAM 8 8 100 64-QAM 6 10 800 64 800 16-QAM 4 16 200 QPSK 2 32 400 256-QAM 8 2 025 64-QAM 6 2 700 16 200 16-QAM 4 4 050 QPSK 2 8 100 ETSI 39 ETSI EN 302 755 V1.1.1 (2009-09) 6.2.1 Bit to cell word de-multiplexer The bit-stream vdi from the bit interleaver is de-multiplexed into Nsubstreams sub-streams, as shown in figure 14. The value of Nsubstreams is defined in table 11. Table 11: Number of sub-streams in de-multiplexer Number of sub-streams, Modulation Nldpc Nsubstreams QPSK Any 2 16-QAM Any 8 64-QAM Any 12 64 800 16 256-QAM 16 200 8 The de-multiplexing is defined as a mapping of the bit-interleaved input bits, vdi onto the output bits be,do, where: do = di div Nsubstreams; e is the de-multiplexed bit substream number (0 ≤ e < Nsubstreams), which depends on di as defined in table 12; vdi is the input to the de-multiplexer; di is the input bit number; be,do is the output from the de-multiplexer; do is the bit number of a given stream at the output of the de-multiplexer. b0,0, b0,1, b0,2, ... b1,0, b1,1, b1,2, ... v0, v1, v2, ... Demux bNsubstreams-1,0, bNsubstreams-1,1,... Input Outputs Figure 14: De-multiplexing of bits into sub-streams ETSI 40 ETSI EN 302 755 V1.1.1 (2009-09) Table 12(a): Parameters for de-multiplexing of bits to sub-streams for code rates 1/2, 3/4, 4/5 and 5/6 Modulation format QPSK Input bit-number, di mod Nsubstreams 0 1 Output bit-number, 0 1 e Modulation format 16-QAM Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 Output bit-number, 7 1 4 2 5 3 6 0 e Modulation format 64-QAM Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 8 9 10 11 Output bit-number, 11 7 3 10 6 2 9 5 1 8 4 0 e Modulation format 256-QAM (Nldpc = 64 800) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Output bit-number, 15 1 13 3 8 11 9 5 10 6 4 7 12 2 14 0 e Modulation format 256-QAM (Nldpc = 16 200) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 Output bit-number, 7 3 1 5 2 6 4 0 e ETSI 41 ETSI EN 302 755 V1.1.1 (2009-09) Table 12(b): Parameters for de-multiplexing of bits to sub-streams for code rate 3/5 only Modulation format QPSK Input bit-number, di mod Nsubstreams 0 1 Output bit-number, 0 1 e Modulation format 16-QAM (Nldpc = 64 800) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 Output bit-number, 0 5 1 2 4 7 3 6 e Modulation format 16-QAM (Nldpc = 16 200) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 Output bit-number, 7 1 4 2 5 3 6 0 e Modulation format 64-QAM(Nldpc = 64 800) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 8 9 10 11 Output bit-number, 2 7 6 9 0 3 1 8 4 11 5 10 e Modulation format 64-QAM (Nldpc = 16 200) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 8 9 10 11 Output bit-number, 11 7 3 10 6 2 9 5 1 8 4 0 e Modulation format 256-QAM (Nldpc = 64 800) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Output bit-number, 2 11 3 4 0 9 1 8 10 13 7 14 6 15 5 12 e Modulation format 256-QAM (Nldpc = 16 200) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 Output bit-number, 7 3 1 5 2 6 4 0 e ETSI 42 ETSI EN 302 755 V1.1.1 (2009-09) Table 12(c): Parameters for de-multiplexing of bits to sub-streams for code rate 2/3 only Modulation format QPSK Input bit-number, di mod Nsubstreams 0 1 Output bit-number, 0 1 e Modulation format 16-QAM Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 Output bit-number, 7 1 4 2 5 3 6 0 e Modulation format 64-QAM Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 8 9 10 11 Output bit-number, 11 7 3 10 6 2 9 5 1 8 4 0 e Modulation format 256-QAM (Nldpc = 64 800) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Output bit-number, 7 2 9 0 4 6 13 3 14 10 15 5 8 12 11 1 e Modulation format 256-QAM (Nldpc = 16 200) Input bit-number, di mod Nsubstreams 0 1 2 3 4 5 6 7 Output bit-number, 7 3 1 5 2 6 4 0 e NOTE: Table 12(c) is the same as table 12(a) except for the modulation format 256-QAM with Nldpc = 64 800. Except for QPSK (Nldpc = 64 800 or 16 200) and 256-QAM (Nldpc=16 200 only), the words of width Nsubstreams are split into two cell words of width ηMOD= Nsubstreams /2 at the output of the demultiplexer. The first mod =Nsubstreams η /2 bits [b0,do..bNsubstreams/2-1,do] form the first of a pair of output cell words [y0,2do.. y mod-1, 2do] and the remaining η output bits [bNsubstreams/2, do..bNsubstreams-1,do] form the second output cell word [y0, 2do+1..y mod-1,2do+1] fed to the η constellation mapper. In the case of QPSK (Nldpc = 64 800 or 16 200) and 256-QAM (Nldpc=16 200 only), the words of width Nsubstreams from the demultiplexer form the output cell words and are fed directly to the constellation mapper, so: [y0,do..y mod-1,do] = [b0,do..bNsubstreams-1,do] η 6.2.2 Cell word mapping into I/Q constellations Each cell word (y0,q..y mod-1,q) from the demultiplexer in clause 6.2.1 shall be modulated using either QPSK, 16-QAM, η 64-QAM or 256-QAM constellations to give a constellation point zq prior to normalization. BPSK is only used for the L1 signalling (see clause 7.3.3.2) but the constellation mapping is specified here. The exact values of the real and imaginary components Re(zq) and Im(zq) for each combination of the relevant input bits ye,q are given in table 13(a-i) for the various constellations: Table 13(a): Constellation mapping for BPSK y0,q 1 0 Re(zq) -1 1 Im(zq) 0 0 ETSI 43 ETSI EN 302 755 V1.1.1 (2009-09) Table 13(b): Constellation mapping for real part of QPSK y0,q 1 0 Re(zq) -1 1 Table 13(c): Constellation mapping for imaginary part of QPSK y1,q 1 0 Im(zq) -1 1 Table 13(d): Constellation mapping for real part of 16-QAM y0,q 1 1 0 0 y2,q 0 1 1 0 Re(zq) -3 -1 1 3 Table 13(e): Constellation mapping for imaginary part of 16-QAM y1,q 1 1 0 0 y3,q 0 1 1 0 Im(zq) -3 -1 1 3 Table 13(f): Constellation mapping for real part of 64-QAM y0,q 1 1 1 1 0 0 0 0 y2,q 0 0 1 1 1 1 0 0 0 1 1 0 0 1 1 0 y4,q Re(zq) -7 -5 -3 -1 1 3 5 7 Table 13(g): Constellation mapping for imaginary part of 64-QAM y1,q 1 1 1 1 0 0 0 0 y3,q 0 0 1 1 1 1 0 0 0 1 1 0 0 1 1 0 y5,q Im(zq) -7 -5 -3 -1 1 3 5 7 Table 13(h): Constellation mapping for real part of 256-QAM y0,q 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 y2,q 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 y4,q 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 y6,q Re(zq) -15 -13 -11 -9 -7 -5 -3 -1 1 3 5 7 9 11 13 15 Table 13(i): Constellation mapping for imaginary part of 256-QAM y1,q 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 y3,q 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 y5,q 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 y7,q Im(zq) -15 -13 -11 -9 -7 -5 -3 -1 1 3 5 7 9 11 13 15 ETSI 44 ETSI EN 302 755 V1.1.1 (2009-09) The constellations, and the details of the Gray mapping applied to them, are illustrated in figures 15 and 16. Figure 15: The QPSK, 16-QAM and 64-QAM mappings and the corresponding bit patterns ETSI 45 ETSI EN 302 755 V1.1.1 (2009-09) Figure 16: The 256-QAM mapping and the corresponding bit pattern The constellation points zq for each input cell word (y0,q..y mod-1,q) are normalized according to table 14 to obtain the η correct complex cell value fq to be used. Table 14: Normalization factors for data cells Modulation Normalization BPSK f q = zq zq QPSK fq = 2 zq 16-QAM fq = 10 zq 64-QAM fq = 42 zq 256-QAM fq = 170 ETSI 46 ETSI EN 302 755 V1.1.1 (2009-09) 6.3 Constellation Rotation and Cyclic Q Delay When constellation rotation is used, the normalized cell values of each FEC block F=(f0, f1, …, fNcells-1), coming from the constellation mapper (see clause 6.2.2) are rotated in the complex plane and the imaginary part cyclically delayed by one cell within a FEC block. Ncells is the number of cells per FEC block and is given in table 16. The output cells G=(g0, g1, …, gNcells-1) are given by: g0 = Re(RRQD f0) + j Im(RRQD fNcells-1), gq = Re(RRQD fq) + j Im(RRQD fq -1), q=1,2, … Ncells-1, 2πΦ j where the rotation phasor RRQD = e 360 . The rotation angle Φ depends on the modulation and is given in table 15. Table 15: Rotation angle for each modulation type Modulation QPSK 16-QAM 64-QAM 256-QAM Φ (degrees) 29,0 16,8 8,6 atan (1/16) where atan(1/16) denotes the arctangent of 1/16 expressed in degrees. Constellation rotation shall only be used for the common PLPs and the data PLPs and never for the cells of the L1 signalling. When constellation rotation is not used (i.e. PLP_ROTATION=0, see clause 7.2.3.1), the cells are passed onto the cell interleaver unmodified, i.e. gq=fq. 6.4 Cell Interleaver The Pseudo Random Cell Interleaver (CI), which is illustrated in figure 17, shall uniformly spread the cells in the FEC codeword, to ensure in the receiver an uncorrelated distribution of channel distortions and interference along the FEC codewords, and shall differently "rotate" the interleaving sequence in each of the FEC blocks of one Time Interleaver Block (see clause 6.5). The input of the CI, G(r)=(gr,0, gr,1, gr,2,..., gr,Ncells-1) shall be the data cells (g0, g1, g2,..., gNcells-1) of the FEC block of index 'r', generated by the constellation rotation and cyclic Q delay (see clause 6.3), 'r' represents the incremental index of the FEC block within the TI-block and is reset to zero at the beginning of each TI-block. When time interleaving is not used, the value of 'r' shall be 0 for every FEC block. The output of the CI shall be a vector D(r) = (dr,0, dr,1, dr,2,..., dr,Ncells-1) defined by: dr,L (q) = gr,q for each q = 0,1,...,Ncells-1, r where Ncells is the number of output data cells per FEC block as defined by table 16 and Lr(q) is a permutation function applied to FEC block r of the TI-block. Lr(q) is based on a maximum length sequence, of degree (Nd-1), where N d = ⎡log 2 ( N cells )⎤ , plus MSB toggling at each new address generation. When an address is generated larger than or equal to Ncells, it is discarded and a new address is generated. To have different permutations for different FEC blocks, a constant shift (modulo Ncells) is added to the permutation, generated as a bit-reversed Nd-bit sequence, with values greater than or equal to Ncells discarded. The permutation function Lr(q) is given by: Lr(q) = [L0(q) +P(r)] mod Ncells, where L0(q) is the basic permutation function (used for the first FEC block of a TI-block) and P(r) is the shift value to be used in FEC block r of the TI-block. The basic permutation function L0(q) is defined by the following algorithm. ETSI 47 ETSI EN 302 755 V1.1.1 (2009-09) An Nd bit binary word Si is defined as follows: For all i, Si [Nd-1] = (i mod 2) // (toggling of top bit) i = 0,1: Si [Nd-2, Nd-3,...,1,0] = 0,0,...,0,0 i = 2: S2 [Nd-2, Nd-3,...,1,0] = 0,0,...,0,1 2 < i < 2 Nd : Si [Nd-3, Nd-4,...,1,0] = Si-1 [Nd -2, Nd -3,...,2,1]; for Nd = 11: Si [9] = Si-1 [0] ⊕ Si-1 [3] for Nd = 12: Si [10] = Si-1 [0] ⊕ Si-1 [2] for Nd = 13: Si [11] = Si-1 [0] ⊕ Si-1 [1] ⊕ Si-1[4] ⊕ Si-1 [6] for Nd = 14: Si [12] = Si-1 [0] ⊕ Si-1 [1] ⊕ Si-1[4] ⊕ Si-1 [5] ⊕ Si-1 [9] ⊕ Si-1 [11] for Nd = 15: Si [13] = Si-1 [0] ⊕ Si-1 [1] ⊕ Si-1[2] ⊕ Si-1 [12]. The sequence L0(q) is then generated by discarding values of Si greater than or equal to Ncells as defined in the following algorithm: q = 0; for (i = 0; i < 2Nd; i = i + 1) { N d −1 L0 (q) = ∑ S ( j) ⋅ 2 j =0 i j ; if (L0(q) < Ncells) q = q+1; } The shift P(r) to be applied in FEC block index r is calculated by the following algorithm. The FEC block index r is the index of the FEC block within the TI-block and counts up to NFEC_TI (n,s) - 1, where NFEC_TI (n,s) is the number of FEC blocks in TI-block index 's' of Interleaving Frame 'n' (see clause 6.5.2). P(r) is the conversion to decimal of the bit-reversed value of a counter k in binary notation over Nd bits. The counter is incremented if the bit-reversed value is too great. k=0; for (r=0; r=Ncells) ETSI 48 ETSI EN 302 755 V1.1.1 (2009-09) { ⎢ ⎢ k ⎥ j +1 ⎥ ⎢ k − ⎢ 2 j +1 ⎥ 2 ⎥ N d −1 P(r ) = ∑ ⎢ ⎣ ⎦ ⎥ ⋅ 2 Nd −1− j ; j j =0 ⎢ 2 ⎥ ⎢ ⎣ ⎥ ⎦ k= k+1; } } So for Ncells= 10 800, Nd= 14, and the shift P(r) to be added to the permutation for r =0, 1, 2, 3, etc. would be 0, 8 192, 4 096, 2 048, 10 240, 6 144, 1 024, 9 216, etc. FEC block r=0 r=1 r=2 r=3 index Modulation order η dom /CPDLN=llecN e m a rf C E F :ht gnel 00846 00261 Figure 17: Cell Interleaving scheme 6.5 Time Interleaver The time interleaver (TI) shall operate at PLP level. The parameters of the time interleaving may be different for different PLPs within a T2 system. The FEC blocks from the cell interleaver for each PLP shall be grouped into Interleaving Frames (which are mapped onto one or more T2-frames). Each Interleaving Frame shall contain a dynamically variable whole number of FEC blocks. The number of FEC blocks in the Interleaving Frame of index n is denoted by NBLOCKS_IF(n) and is signalled as PLP_NUM_BLOCKS in the L1 dynamic signalling. NBLOCKS may vary from a minimum value of 0 to a maximum value NBLOCKS_IF_MAX. NBLOCKS_IF_MAX is signalled in the configurable L1 signalling as PLP_NUM_BLOCKS_MAX. The largest value this may take is 1023. ETSI 49 ETSI EN 302 755 V1.1.1 (2009-09) Each Interleaving Frame is either mapped directly onto one T2-frame or spread out over several T2-frames as described in clause 6.5.1. Each Interleaving Frame is also divided into one or more (NTI) TI-blocks, where a TI-block corresponds to one usage of the time interleaver memory, as described in clause 6.5.2. The TI-blocks within a Interleaving Frame can contain a slightly different number of FEC blocks. If an Interleaving Frame is divided into multiple TI-blocks, it shall be mapped to only one T2-frame. There are therefore three options for time interleaving for each PLP: 1) Each Interleaving Frame contains one TI-block and is mapped directly to one T2-frame as shown in figure 18(a). This option is signalled in the L1-signalling by TIME_IL_TYPE='0' and TIME_IL_LENGTH='1'. 2) Each Interleaving Frame contains one TI-block and is mapped to more than one T2-frame. Figure 18(b) shows an example in which one Interleaving Frame is mapped to two T2-frames, and FRAME_INTERVAL(IJUMP)=2. This gives a greater time diversity for low data-rate services. This option is signalled in the L1-signalling by TIME_IL_TYPE='1'. 3) Each Interleaving Frame is mapped directly to one T2-frame and the Interleaving Frame is divided into several TI-blocks as shown in figure 18(c). Each of the TI-blocks may use up to the full TI memory, thus increasing the maximum bit-rate for a PLP. This option is signalled in the L1-signalling by TIME_IL_TYPE='0'. Figure 18(a): Time interleaving for PI=1, IJUMP=1, NTI=1 Figure 18(b): Time interleaving for PI=2, IJUMP=2, NTI=1 ETSI 50 ETSI EN 302 755 V1.1.1 (2009-09) Figure 18(c): Time interleaving for PI=1, IJUMP=1, NTI=3 6.5.1 Mapping of Interleaving Frames onto one or more T2-frames Each Interleaving Frame is either mapped directly onto one T2-frame or spread out over several T2-frames. The number of T2-frames in one Interleaving Frame, PI, is signalled in the L1 configurable signalling by TIME_IL_LENGTH in conjunction with TIME_IL_TYPE. The length of the time interleaving period TP shall not exceed one super-frame. The time interleaving period is calculated as: TP = TF × PI(i)× IJUMP (i), where TF is the T2-frame length in time (see clause 8.3.1) and IJUMP (i) is the interval of T2-frames for PLP i, e.g. if the PLP occurs in every third T2-frame IJUMP(i)=3 (see clause 8.2). PI(i) is the value of PI for PLP i. NOTE: There will be an integer number of FEC blocks in an Interleaving Frame, but the number of FEC blocks per T2-frame need not be an integer if the Interleaving Frame extends over several T2-frames. There shall be an integer number of Interleaving Frames in a super-frame so that: NT2 / (PI × IJUMP) = integer number of Interleaving Frames per super-frame, where NT2 is the number of T2-frames in a super-frame. EXAMPLE: The super-frame length of a T2 system is NT2 =20. The system carries among others the following PLPs: PLP1 with interleaving length PI(1) = 1 frame occurring in every T2-frame: IJUMP(1)= 1; PLP2 with interleaving length PI(2) = 2 frames occurring in every second T2-frame: IJUMP(2)= 2; and PLP3 with interleaving length PI(3) = 4 frames occurring in every fifth T2-frame: IJUMP(3) = 5. The number of Interleaving Frames per super-frame is 20 / (1×1) = 20 Interleaving Frames for PLP1, 20 / (2×2) = 5 Interleaving Frames for PLP2 and 20 / (4×5) = 1 Interleaving Frames for PLP3. 6.5.2 Division of Interleaving frames into Time Interleaving Blocks The time interleaver interleaves cells over one TI-block, which contains a dynamically variable integer number of FEC blocks. In one Interleaving Frame there may be one or more TI-blocks. The number of TI-blocks in an Interleaving Frame, denoted by NTI, shall be an integer and is signalled in the L1 configurable signalling by TIME_IL_LENGTH in conjunction with TIME_IL_TYPE. NOTE: If an Interleaving Frame extends over multiple T2-frames, then NTI will be 1, i.e. one Interleaving Frame will contain exactly one TI-block. ETSI 51 ETSI EN 302 755 V1.1.1 (2009-09) The number of FEC blocks in TI-block index 's' of Interleaving Frame 'n' is denoted by NFEC_TI (n,s), where 0 ≤ s< NTI. If NTI =1, then there will be only one TI-block, with index s=0, per Interleaving Frame and NFEC_TI(n,s) shall be equal to the number of FEC blocks in the Interleaving Frame, NBLOCKS_IF(n). If NTI >1, then the value of NFEC_TI(n,s) for each TI-block (index s) within the Interleaving Frame (index n) shall be calculated as follows: ⎧ ⎢ N BLOCKS _ IF (n) ⎥ ⎪ ⎢ ⎥ s < N TI − [ N BLOCKS _ IF (n) mod N TI ] ⎪ ⎣ N TI ⎦ N FEC _ TI (n, s ) = ⎨ ⎪⎢ N BLOCKS _ IF (n) ⎥ + 1 s ≥ N − [ N BLOCKS _ IF ( n ) mod N TI ] ⎪⎢ ⎩⎣ N TI ⎥ ⎦ TI This ensures that the values of NFEC_TI(n,s) for the TI-blocks within an Interleaving Frame differ by at most one FEC block and that the smaller TI-blocks come first. NFEC_TI(n,s) may vary in time from a minimum value of 0 to a maximum value NFEC_TI_MAX. NFEC_TI_MAX may be determined from NBLOCKS_IF_MAX (see clause 6.5) by the following formula: ⎡N ⎤ N FEC _ TI _ MAX = ⎢ BLOCKS _ IF _ MAX ⎥ ⎢ NTI ⎥ The maximum number of TI memory cells per PLP shall be MTI=219+215, but note that this memory shall be shared between the data PLP and its associated common PLP (if any). Therefore, for PLPs without an associated common PLP, NBLOCKS_IF_MAX and NTI shall be chosen such that: NFEC_TI_MAX × NCELLS ≤ MTI, where NCELLS is the number of cells per FEC block and is given in table 16 for the various constellations and FEC lengths. For PLPs having an associated common PLP, the MTI TI cells shall be divided statically between the data PLP and the common PLP, such that for any one data PLP from a group with an associated common PLP: NFEC_TI_MAX (data PLP) × NCELLS(data PLP) + NFEC_TI_MAX (common PLP) ×NCELLS(common PLP) ≤ MTI The FEC blocks at the input shall be assigned to TI-blocks in increasing order of s. Each TI-block shall be interleaved as described in clause 6.5.3 and then the cells of each interleaved TI-block shall be concatenated together to form the output Interleaving Frame. 6.5.3 Interleaving of each TI-block The TI shall store in the TI memories (one per PLP) the cells (dn,s,0,0, dn,s,0,1,…, dn,s,0,Ncells-1, dn,s,1,0, dn,s,1,1,…, dn,s,1,Ncells-1, …, dn,s,NFEC_TI(n,s)-1,0, dn,s, NFEC_TI(n,s)-1,1,…, dn,s, NFEC_TI(n,s)-1, Ncells -1) of the NFEC_TI(n,s) FEC blocks from the output of the cell interleaver, where dn,s,r,q is the output cell dr,q from the cell interleaver belonging to the current TI-block s of the current Interleaving Frame n. Typically, the time interleaver will also act as a buffer for PLP data prior to the process of frame building (see clause 8). This can be achieved by means of two memory banks for each PLP. The first TI-block is written to the first bank. The second TI-block is written to the second bank whilst the first bank is being read from and so on, see figure 19. ETSI 52 ETSI EN 302 755 V1.1.1 (2009-09) PLP1 Memory PLP2 Memory WRITE PLPk Memory Memory Bank A PLP1 Memory PLP2 Memory READ PLPk Memory Memory Bank B Figure 19: Example of operation of time interleaver memory banks The TI shall be a row-column block interleaver: the number of rows Nr in the interleaver is equal to the number of cells in the FEC block (Ncells) divided by 5, and the number of columns Nc = 5×NFEC(n,s). Hence the number of columns filled will vary TI-block by TI-block depending on its cell-rate. The parameters of the interleaver are defined in table 16. Table 16: Parameters for time interleaver LDPC block length Modulation Number of cells Number of rows Nr (Nldpc) mode per LDPC block (NCELLS) 256-QAM 8 100 1 620 64-QAM 10 800 2 160 64 800 16-QAM 16 200 3 240 QPSK 32 400 6 480 256-QAM 2 025 405 64-QAM 2 700 540 16 200 16-QAM 4 050 810 QPSK 8 100 1 620 A graphical representation of the time interleaver is shown in figure 20. The first FEC block is written column-wise into the first 5 columns of the time interleaver, the second FEC block is written column-wise into the next 5 columns and so on. The cells are read out row-wise. ETSI 53 ETSI EN 302 755 V1.1.1 (2009-09) First cell of first WRITE READ FEC block of TI-block Row 1 Row Nr Column 1 Column Nc Figure 20: Time interleaver 6.5.4 Using the three Time Interleaving options with sub-slicing In order to allow the maximum flexibility to select TI characteristics, the Interleaving Frames at the output of the time interleaver may be split into multiple sub-slices, as described in clause 8.3.6.3.2. The case where sub-slicing is used together with time-interleaving option (1) (where PI=1 and NTI=1 as defined above) is shown in figure 21, where the output from the TI-block is split into Nsubslices sub-slices. First cell of first FEC block of T2-frame (for the current PLP) READ Sub-slice 0 Sub-slice 1 Sub-slice Nsubslices-2 Sub-slice Nsubslices-1 Figure 21: An example showing the output from a single TI-block, when interleaving over an integer number of T2-frames for a single RF channel ETSI 54 ETSI EN 302 755 V1.1.1 (2009-09) Sub-slicing may also be used together with time-interleaving option (2), where the output Interleaving Frame is mapped to more than one T2-frame as described in clause 6.5.1. This is similar to case (1), except that the Interleaving Frame is split into a total of Nsubslices×PI sub-slices, as shown in figure 22. First cell of first FEC block of Interleaving Frame READ Sub-slice 0 Sub-slice 1 T2-frame 0 Sub-slice Nsubslices-2 Sub-slice Nsubslices-1 Sub-slice 0 Sub-slice 1 T2-frame PI -1 Sub-slice Nsubslices-2 Sub-slice Nsubslices-1 Figure 22: The output from a single TI-block, split into Nsubslices sub-slices in each of PI T2-frames Finally, sub-slicing may be used in combination with time interleaving option (3), where the Interleaving Frame is divided into multiple TI-blocks. The TI-blocks within the Interleaving Frame may be of different sizes, as described in clause 6.5.2, and the number of sub-slices need not have any particular relationship to the number NTI of TI-blocks in the Interleaving Frame. Therefore, the sub-slices will not necessarily contain a whole number of rows from the time interleaver, and furthermore a sub-slice can contain cells from more than one TI-block. EXAMPLE 1: In figure 23 the data PLPs of type 2 are transmitted in four sub-slices and one Interleaving Frame is mapped to one T2-frame for all PLPs. PLP1 has three TI-blocks, PLP2 has two TI-blocks and PLP4 has four TI-blocks in the Interleaving Frame; the others have one TI-block. PLP1 and PLP2 contain different numbers of FEC blocks in each TI-block of the Interleaving Frame. Some subslices for PLP1 and PLP2 contain cells from different TI-blocks. ETSI 55 ETSI EN 302 755 V1.1.1 (2009-09) Figure 23: PLPs with different interleaving periods EXAMPLE 2: A PLP is interleaved using multiple TI-blocks per Interleaving Frame, so that one T2-frame contains two TI-blocks. The scheduler counts 23 received FEC blocks during a frame (PLP_NUM_BLOCKS = 23 in L1-post signalling). These are divided into two TI-blocks so that the first TI-block is interleaving over 11 FEC blocks and the second TI-block is interleaving over 12 FEC blocks, following the rule of interleaving over the smaller TI-block first. The number of sub-slices per T2-frame for type 2 data PLPs is 240. The first TI-block is then carried in sub-slices 1 to 115, the latter in sub-slices 115 to 240, with sub-slice 115 containing cells from both TI-blocks. Whichever time interleaving option is used, all sub-slices of a PLP in a T2-frame shall contain an equal number of cells. This condition will automatically be satisfied because PI and Nsubslices shall be chosen in order to satisfy a more restrictive condition as described in clause 8.3.6.3.2. For Time-Frequency Slicing using multiple RF channels a different condition applies: see annex E. If time interleaving is not used (i.e. TIME_IL_LENGTH=0), the output of the time interleaver shall consist of the cells presented at the input in the same order and without modification. As explained above, the time interleaver will typically act as a buffer for PLP data and therefore the output may be delayed by a varying amount with respect to the input even when time interleaving is not used. In this case, a compensating delay for the dynamic configuration information from the scheduler will still be required, as shown in figure 2(e). 7 Generation, coding and modulation of Layer 1 signalling 7.1 Introduction This clause describes the layer 1 (L1) signalling. The L1 signalling provides the receiver with a means to access physical layer pipes within the T2-frames. Figure 24 illustrates the L1 signalling structure, which is split into three main sections: the P1 signalling, the L1-pre signalling and L1-post signalling. The purpose of the P1 signalling, which is carried by the P1 symbol, is to indicate the transmission type and basic transmission parameters. The remaining signalling is carried by the P2 symbol(s), which may also carry data. The L1-pre signalling enables the reception and decoding of the L1-post signalling, which in turn conveys the parameters needed by the receiver to access the physical layer pipes. The L1-post signalling is further split into two main parts: configurable and dynamic, and these may be followed by an optional extension field. The L1-post finishes with a CRC and padding (if necessary). For more details of the frame structure, see clause 8. ETSI 56 ETSI EN 302 755 V1.1.1 (2009-09) Figure 24: The L1 signalling structure Throughout the present document, some of the signalling fields or parts of fields are indicated as "reserved for future use" – the meaning of such fields are not defined by the present document and shall be ignored by receivers. Where the value of such a field, or part of the field, is not otherwise defined, it shall be set to '0'. Fields, or parts of fields, whose value is not explicitly defined by the present document shall be treated as though they were defined to be reserved for future use. 7.2 L1 signalling data All L1 signalling data, except for the dynamic L1-post signalling, shall remain unchanged for the entire duration of one super-frame. Hence any changes implemented to the current configuration (i.e. the contents of the L1-pre signalling or the configurable part of the L1-post signalling) shall be always done within the border of two super-frames. 7.2.1 P1 Signalling data The P1 symbol has the capability to convey 7 bits for signalling. Since the preamble (both P1 and P2 symbols) may have different formats, the main use of the P1 signalling is to identify the preamble itself. The information it carries is of two types: the first type (associated to the S1 bits of the P1) is needed to distinguish the preamble format (and, hence, the frame type); the second type helps the receiver to rapidly characterize the basic TX parameters. • The S1 field: Preamble Format: - The preamble format is carried in the S1 field of the P1 symbol. It identifies the format of the P2 symbol(s) that take part of the preamble. Table 17: S1 Field S1 Preamble Format / Description P2 Type 000 T2_SISO The preamble is a T2 preamble and the P2 part is transmitted in its SISO format 001 T2_MISO The preamble is a T2 preamble and the P2 part is transmitted in its MISO format 010 Non-T2 See table 18(b) 011 Reserved for future These combinations may be used for future 100 use systems, including a system containing 101 both T2-frames and FEF parts, as well as 110 future systems not defined in the present 111 document ETSI 57 ETSI EN 302 755 V1.1.1 (2009-09) • The S2 field 1: Complementary information: - The first 3 bits of the S2 field are referred to as S2 field 1. When the preamble format is of the type "T2" (either "T2_MISO" or "T2_SISO"), S2 field 1indicates the FFT size and gives partial information about the guard interval for the remaining symbols in the T2-frame, as described in table 18(a). When the preamble is of the type "Non-T2", S2 field 1 is described by table 18(b). When the S1 field is equal to one of the values reserved for future use, the value of the S2 field 1 shall also be reserved for future use. Table 18(a): S2 Field 1 (for T2 preamble types, S1=00X) S1 S2 FFT/GI size Description 00X 000X FFT Size: 2K – any Indicates the FFT size and guard interval of guard interval the symbols in the T2-frame 00X 001X FFT Size: 8K – guard intervals 1/32; 1/16; 1/8 or 1/4 00X 010X FFT Size: 4K – any guard interval 00X 011X FFT Size: 1K – any guard interval 00X 100X FFT Size: 16K – any guard interval 00X 101X FFT Size: 32K – guard intervals 1/32; 1/16; 1/8 or 1/4 00X 110X FFT Size: 8K – guard intervals 1/128; 19/256 or 19/128 00X 111X FFT Size: 32K – guard intervals 1/128; 19/256 or 19/128 Table 18(b): S2 Field 1 (for Non-T2 preambles, S1=010) S1 S2 field 1 S2 field 2 Meaning Description 010 000 X Undefined FEF part The preamble is the preamble of a FEF part, but the contents of the remainder of the FEF part are not specified by the present document – it may be used in any way for professional applications and is not intended for consumer receivers 010 001 – 111 X Reserved for future use - • The S2 field 2: 'Mixed' bit: - This bit indicates whether the preambles are all of the same type or not. The bit is valid for all values of S1 and S2 field 1. The meaning of this bit is given in table 19. Table 19: S2 field 2 S1 S2 field 1 S2 field 2 Meaning Description XXX XXX 0 Not mixed All preambles in the current transmission are of the same type as this preamble. XXX XXX 1 Mixed Preambles of different types are transmitted The modulation and construction of the P1 symbol is described in clause 9.8. ETSI 58 ETSI EN 302 755 V1.1.1 (2009-09) 7.2.2 L1-Pre Signalling data Figure 25 illustrates the signalling fields of the L1-pre signalling, followed by the detailed definition of each field. Figure 25: The signalling fields of L1-pre signalling TYPE: This 8-bit field indicates the types of the Tx input streams carried within the current T2 super-frame. The mapping of different types is given in table 20. Table 20: The mapping of Tx input stream types Value type 0x00 Transport Stream (TS) [i.1] only Generic Stream (GSE [i.2] and/or GFPS 0x01 and/or GCS) but not TS Both TS and Generic Stream (i.e. TS and 0x02 at least one of GSE, GFPS, GCS) 0x03 to 0xFF Reserved for future use BWT_EXT: This 1-bit field indicates whether the extended carrier mode is used in the case of 8K, 16K and 32K FFT sizes. When this field is set to '1', the extended carrier mode is used. If this field is set to '0', the normal carrier mode is used. See clause 9.5. S1: This 3-bit field has the same value as in the P1 signalling. S2: This 4-bit field has the same value as in the P1 signalling. ETSI 59 ETSI EN 302 755 V1.1.1 (2009-09) L1_REPETITION_FLAG: This 1-bit flag indicates whether the dynamic L1-post signalling is provided also for the next frame. If this field is set to value '1', the dynamic signalling shall be also provided for the next frame within this frame. When this field is set to value '0', dynamic signalling shall not be provided for the next frame within this frame. If dynamic signalling is provided for the next frame within this frame, it shall follow immediately after the dynamic signalling of the current frame, see clause 7.2.3.3. GUARD_INTERVAL: This 3-bit field indicates the guard interval of the current super-frame, according to table 21. Table 21: Signalling format for the guard interval Value Guard interval fraction 000 1/32 001 1/16 010 1/8 011 1/4 100 1/128 101 19/128 110 19/256 111 Reserved for future use PAPR: This 4-bit field describes what kind of PAPR reduction is used, if any. The values shall be signalled according to table 22. Table 22: Signalling format for PAPR reduction Value constellation 0000 No PAPR reduction is used 0001 ACE-PAPR only is used 0010 TR-PAPR only is used 0011 Both ACE and TR are used 0100 to 1111 Reserved for future use L1_MOD: This 4-bit field indicates the constellation of the L1-post signalling data block. The constellation values shall be signalled according to table 23. Table 23: Signalling format for the L1-post constellations Value constellation 0000 BPSK 0001 QPSK 0010 16-QAM 0011 64-QAM 0100 to 1111 Reserved for future use L1_COD: This 2-bit field describes the coding of the L1-post signalling data block. The coding values shall be signalled according to table 24. Table 24: Signalling format for the L1-post code rates Value Code rate 00 1/2 01 to 11 Reserved for future use L1_FEC_TYPE: This 2-bit field indicates the type of the L1 FEC used for the L1-post signalling data block. The L1_FEC_TYPE shall be signalled according to table 25. ETSI 60 ETSI EN 302 755 V1.1.1 (2009-09) Table 25: Signalling format for the L1-post FEC type Value L1 FEC type 00 LDPC 16K 01 to 11 Reserved for future use L1_POST_SIZE: This 18-bit field indicates the size of the coded and modulated L1-post signalling data block, in OFDM cells. L1_POST_INFO_SIZE: This 18-bit field indicates the size of the information part of the L1-post signalling data block, in bits, including the extension field, if present, but excluding the CRC. The value of Kpost_ex_pad (see clause 5.8.2.2.3.2) may be calculated by adding 32 (the length of the CRC) to L1_POST_INFO_SIZE. This is shown in figure 26. L1 padding Configurable Dynamic Extension CRC EZIS_OFNI_TSOP_1L Figure 26: The size indicated by the L1_POST_INFO_SIZE field PILOT_PATTERN: This 4-bit field indicates the scattered pilot pattern used for the data OFDM symbols. Each pilot pattern is defined by the Dx and Dy spacing parameters (see clause 9.2.3). The used pilot pattern is signalled according to table 26. Table 26: Signalling format for the pilot pattern Value Pilot pattern type 0000 PP1 0001 PP2 0010 PP3 0011 PP4 0100 PP5 0101 PP6 0110 PP7 0111 PP8 1000 to 1111 Reserved for future use TX_ID_AVAILABILITY: This 8-bit field is used to signal the availability of transmitter identification signals within the current geographic cell. When no transmitter identification signals are used this field is set to 0x000. All other bit combinations are reserved for future use. CELL_ID: This is a 16-bit field which uniquely identifies a geographic cell in a DVB-T2 network. A DVB-T2 cell coverage area may consist of one or more frequencies, depending on the number of frequencies used per T2 system. If the provision of the CELL_ID is not foreseen, this field shall be set to '0'. NETWORK_ID: This is a 16-bit field which uniquely identifies the current DVB-T2 network. T2_SYSTEM_ID: This 16-bit field uniquely identifies a T2 system within the DVB-T2 network. NUM_T2_FRAMES: This 8-bit field indicates NT2, the number of T2-frames per super-frame. The minimum value of NUM_T2_FRAMES shall be 2. NUM_DATA_SYMBOLS: This 12-bit field indicates Ldata= LF - NP2, the number of data OFDM symbols per T2-frame, excluding P1 and P2. The minimum value of NUM_DATA_SYMBOLS is defined in clause 8.3.1. ETSI 61 ETSI EN 302 755 V1.1.1 (2009-09) REGEN_FLAG: This 3-bit field indicates how many times the DVB-T2 signal has been re-generated. Value '000' indicates that no regeneration has been done. Each time the DVB-T2 signal is regenerated this field is increased by one. L1_POST_EXTENSION: This 1-bit field indicates the presence of the L1-post extension field (see clause 7.2.3.4). When the extension field is present in the L1-post, this bit shall be set to a 1, otherwise it shall be set to a 0. NUM_RF: This 3-bit field indicates NRF, the number of frequencies in the current T2 system. The frequencies are listed within the configurable parameters of the L1-post signalling. CURRENT_RF_IDX: If the TFS mode is supported, this 3-bit field indicates the index of the current RF channel within its TFS structure, between 0 and NUM_RF-1. In case the TFS mode is not supported, this field is set to '0'. RESERVED: This 10-bit field is reserved for future use. CRC-32: This 32-bit error detection code is applied to the entire L1-pre signalling. The CRC-32 code is defined in annex F. 7.2.3 L1-post signalling data The L1-post signalling contains parameters which provide sufficient information for the receiver to decode the desired physical layer pipes. The L1-post signalling further consists of two types of parameters, configurable and dynamic, plus an optional extension field. The configurable parameters shall always remain the same for the duration of one super- frame, whilst the dynamic parameters provide information which is specific for the current T2-frame. The values of the dynamic parameters may change during the duration of one super-frame, while the size of each field shall remain the same. ETSI 62 ETSI EN 302 755 V1.1.1 (2009-09) 7.2.3.1 Configurable L1-post signalling Figure 27 illustrates the signalling fields of the configurable L1-post signalling, followed by the detailed definition of each field. Figure 27: The signalling fields of configurable L1-post signalling ETSI 63 ETSI EN 302 755 V1.1.1 (2009-09) SUB_SLICES_PER_FRAME: This 15-bit field indicates Nsubslices_total, the total number of sub-slices for the type 2 data PLPs across all RF channels in one T2-frame. When TFS is used, this is equal to, Nsubslices×NRF, i.e. the number of sub-slices in each RF channel multiplied by the number of RF channels. When TFS is not used, Nsubslices_total = Nsubslices. If there are no type 2 PLPs, this field shall be set to '1D'. Allowable values of this field are listed in annex K. NUM_PLP: This 8-bit field indicates the number of PLPs carried within the current super-frame. The minimum value of this field shall be '1'. NUM_AUX: This 4-bit field indicates the number of auxiliary streams. Zero means no auxiliary streams are used, and clause 5.8.6 shall be ignored. AUX_CONFIG_RFU: This 8-bit field is reserved for future use. The following fields appear in the frequency loop: RF_IDX: This 3-bit field indicates the index of each FREQUENCY listed within this loop. The RF_IDX value is allocated a unique value between 0 and NUM_RF-1. In case the TFS mode is supported, this field indicates the order of each frequency within the TFS configuration. FREQUENCY: This 32-bit field indicates the centre frequency in Hz of the RF channel whose index is RF_IDX. The order of the frequencies within the TFS configuration is indicated by the RF_IDX. The value of FREQUENCY may be set to '0', meaning that the frequency is not known at the time of constructing the signal. If this field is set to 0, it shall not be interpreted as a frequency by a receiver. The FREQUENCY fields can be used by a receiver to assist in finding the signals which form a part of the TFS system. Since the value will usually be set at a main transmitter but not modified at a transposer, the accuracy of this field shall not be relied upon. The following fields appear only if the LSB of the S2 field is '1' (i.e. S2='xxx1'): FEF_TYPE: This 4-bit field shall indicate the type of the associated FEF part. The FEF types are signalled according to table 27. Table 27: Signalling format for the FEF type Value FEF type 0000 to 1111 Reserved for future use FEF_LENGTH: This 22-bit field indicates the length of the associated FEF part as the number of elementary periods T (see clause 9.5), from the start of the P1 symbol of the FEF part to the start of the P1 symbol of the next T2-frame. FEF_INTERVAL: This 8-bit field indicates the number of T2-frames between two FEF parts (see figure 35). The T2-frame shall always be the first frame in a T2 super-frame which contains both FEF parts and T2-frames. The following fields appear in the PLP loop: PLP_ID: This 8-bit field identifies uniquely a PLP within the T2 system. PLP_TYPE: This 3-bit field indicates the type of the associated PLP. PLP_TYPE shall be signalled according to table 28. Table 28: Signalling format for the PLP_TYPE field Value Type 000 Common PLP 001 Data PLP Type 1 010 Data PLP Type 2 011 to 111 Reserved for future use ETSI 64 ETSI EN 302 755 V1.1.1 (2009-09) If value of the PLP_TYPE field is one of the values reserved for future use, the total number of bits in the PLP loop shall be the same as for the other types, but the meanings of the fields other than PLP_ID and PLP_TYPE shall be reserved for future use and shall be ignored. PLP_PAYLOAD_TYPE: This 5-bit field indicates the type of the payload data carried by the associated PLP. PLP_PAYLOAD_TYPE shall be signalled according to table 29. See clause 5.1.1 for more information. Table 29: Signalling format for the PLP_PAYLOAD_TYPE field Value Payload type 00000 GFPS 00001 GCS 00010 GSE 00011 TS 00100 to 11111 Reserved for future use FF_FLAG: This flag is set to '1' if a PLP of type 1 in a TFS system occurs on the same RF channel in each T2-frame. This flag is set to '0' if inter-frame TFS is applied as described in annex E. When TFS is not used, or when TFS is used but PLP_TYPE is not equal to '001', this field shall be set to 0 and has no meaning. FIRST_RF_IDX: This 3-bit field indicates on which RF channel a type 1 data PLP occurs in the first frame of a super-frame in a TFS system. If FF_FLAG = '1', the field indicates the RF channel the PLP occurs on in every T2-frame. When TFS is not used, or when TFS is used but PLP_TYPE is not equal to '001', this field shall be set to 0 and has no meaning. FIRST_FRAME_IDX: This 8-bit field indicates the IDX of the first frame of the super-frame in which the current PLP occurs. The value of FIRST_FRAME_IDX shall be less than the value of FRAME_INTERVAL. PLP_GROUP_ID: This 8-bit field identifies with which PLP group within the T2 system the current PLP is associated. This can be used by a receiver to link the data PLP to its associated common PLP, which will have the same PLP_GROUP_ID. PLP_COD: This 3-bit field indicates the code rate used by the associated PLP. The code rate shall be signalled according to table 30 for PLP_FEC_TYPE=00 and 01. Table 30: Signalling format for the code rates for PLP_FEC_TYPE=00 and 01 Value Code rate (see note) 000 1/2 001 3/5 010 2/3 011 3/4 100 4/5 101 5/6 110, 111 Reserved for future use PLP_MOD: This 3-bit field indicates the modulation used by the associated PLP. The modulation shall be signalled according to table 31. Table 31: Signalling format for the modulation Value Modulation 000 QPSK 001 16-QAM 010 64-QAM 011 256-QAM 100 to 111 Reserved for future use PLP_ROTATION: This 1-bit flag indicates whether constellation rotation is in use or not by the associated PLP. When this field is set to the value '1', rotation is used. The value '0' indicates that the rotation is not used. ETSI 65 ETSI EN 302 755 V1.1.1 (2009-09) PLP_FEC_TYPE: This 2-bit field indicates the FEC type used by the associated PLP. The FEC types are signalled according to table 32. Table 32: Signalling format for the PLP FEC type Value PLP FEC type 00 16K LDPC 01 64K LDPC 10, 11 Reserved for future use PLP_NUM_BLOCKS_MAX: This 10-bit field indicates the maximum value of PLP_NUM_BLOCKS (see below) for this PLP. FRAME_INTERVAL: This 8-bit field indicates the T2-frame interval (IJUMP) within the super-frame for the associated PLP. For PLPs which do not appear in every frame of the super-frame, the value of this field shall equal the interval between successive frames. For example, if a PLP appears on frames 1, 4, 7 etc, this field would be set to '3'. For PLPs which appear in every frame, this field shall be set to '1'. For further details, see clause 8.2. TIME_IL_LENGTH: The use of this 8-bit field is determined by the values set within the TIME_IL_TYPE -field as follows: - If the TIME_IL_TYPE is set to the value '1', this field shall indicate PI, the number of T2-frames to which each Interleaving Frame is mapped, and there shall be one TI-block per Interleaving Frame (NTI=1). - If the TIME_IL_TYPE is set to the value '0', this field shall indicate NTI, the number of TI-blocks per Interleaving Frame, and there shall be one Interleaving Frame per T2-frame (PI=1). If there is one TI-block per Interleaving Frame and one T2-frame per Interleaving Frame, TIME_IL_LENGTH shall be set to the value '1' and TIME_IL_TYPE shall be set to '0'. If time interleaving is not used for the associated PLP, the TIME_IL_LENGTH-field shall be set to the value '0' and TIME_IL_TYPE shall be set to '0'. TIME_IL_TYPE: This 1-bit field indicates the type of time-interleaving. A value of '0' indicates that one Interleaving Frame corresponds to one T2-frame and contains one or more TI-blocks. A value of '1' indicates that one Interleaving Frame is carried in more than one T2-frame and contains only one TI-block. IN-BAND_FLAG: This 1-bit field indicates whether the current PLP carries in-band signalling information. When this field is set to the value '1' associated PLP carries in-band signalling information. When set to the value '0', in-band signalling information is not carried. RESERVED_1: This 16-bit field is reserved for future use. RESERVED_2: This 32-bit field is reserved for future use. The following fields appear in the auxiliary stream loop: AUX_RFU: This 32-bit field is reserved for future use for signalling auxiliary streams. ETSI 66 ETSI EN 302 755 V1.1.1 (2009-09) 7.2.3.2 Dynamic L1-post signalling The dynamic L1-post signalling is illustrated in figure 28, followed by the detailed definition of each field. L1 L1-pre signalling L1-post signalling padding Configurable Dynamic Extension CRC FRAME_IDX (8 bits) SUB_SLICE_INTERVAL (22 bits) TYPE_2_START (22 bits) L1_CHANGE_COUNTER (8 bits) START_RF_IDX (3 bits) RESERVED_1 (8 bits) for i=0..NUM_PLP-1 { PLP_ID (8 bits) PLP_START (22 bits) PLP_NUM_BLOCKS (10 bits) RESERVED_2 (8 bits) } RESERVED_3 (8 bits) for i=0..NUM_AUX-1 { AUX_RFU (48 bits) } Figure 28: The signalling fields of the dynamic L1-post signalling FRAME_IDX: This 8-bit field is the index of the current T2-frame within a super-frame. The index of the first frame of the super-frame shall be set to '0'. SUB_SLICE_INTERVAL: This 22-bit field indicates the number of OFDM cells from the start of one sub-slice of one PLP to the start of the next sub-slice of the same PLP on the same RF channel for the current T2-frame (or the next T2-frame in the case of TFS). If the number of sub-slices per frame equals the number of RF channels, then the value of this field indicates the number of OFDM cells on one RF channel for the type 2 data PLPs. If there are no type 2 PLPs in the relevant T2-frame, this field shall be set to '0'. The use of this parameter is defined with greater detail in clause 8.3.6.3.2. TYPE_2_START: This 22-bit field indicates the start position of the first of the type 2 PLPs using the cell addressing scheme defined in 8.3.6.2. If there are no type 2 PLPs, this field shall be set to '0'. It has the same value on every RF channel, and with TFS can be used to calculate when the sub-slices of a PLP are 'folded' (see clause E.2.7.2.4). L1_CHANGE_COUNTER: This 8-bit field indicates the number of super-frames ahead where the configuration (i.e. the contents of the fields in the L1-pre signalling or the configurable part of the L1-post signalling) will change. The next super-frame with changes in the configuration is indicated by the value signalled within this field. If this field is set to the value '0', it means that no scheduled change is foreseen. E.g. value '1' indicates that there is change in the next super-frame. This counter shall always start counting down from a minimum value of 2. START_RF_IDX: This 3-bit field indicates the ID of the starting frequency of the TFS scheduled frame, for the next T2-frame, as described in annex E. The starting frequency within the TFS scheduled frame may change dynamically. When TFS is not used, the value of this field shall be set to '0'. ETSI 67 ETSI EN 302 755 V1.1.1 (2009-09) RESERVED_1: This 8-bit field is reserved for future use. The following fields appear in the PLP loop: PLP_ID: This 8-bit field identifies uniquely a PLP within the T2 system. The order of the PLPs within this loop shall be the same as the order within the PLP loop in the L1-post configurable signalling (see clause 7.2.3.1). NOTE: The PLP_ID is provided again within this loop to provide an additional check that the correct PLP has been located. If the PLP_ID corresponds to a PLP whose PLP_TYPE is one of the values reserved for future use, the total number of bits in the PLP loop shall be the same as for the other types, but the meanings of the fields other than PLP_ID shall be reserved for future use and shall be ignored. PLP_START: This 22-bit field indicates the start position of the associated PLP within the current T2-frame (the next T2-frame in the case of TFS) using the cell addressing scheme defined in clause 8.3.6.2. For type 2 PLPs, this refers to the start position of the first sub-slice of the associated PLP. The first PLP starts immediately after the L1-post signalling. The PLP_START of the first PLP of the frame shall be always set to value '0'. When the current PLP is not mapped to the current T2-frame, or when there are no FEC blocks in the current Interleaving Frame for the current PLP, this field shall be set to '0'. PLP_NUM_BLOCKS: This 10-bit field indicates the number of FEC blocks contained in the current Interleaving Frame for the current PLP (in the case of TFS, this refers to the Interleaving Frame which is mapped to the next T2-frame). It shall have the same value for every T2-frame to which the Interleaving Frame is mapped. When the current PLP is not mapped to the current T2-frame (or the next T2-frame in the case of TFS), this field shall be set to '0'. RESERVED_2: This 8-bit field is reserved for future use. RESERVED_3: This 8-bit field is reserved for future use. The following field appears in the auxiliary stream loop: AUX_RFU: This 48-bit field is reserved for future use for auxiliary signalling. The protection of L1 dynamic signalling is further enhanced by transmitting the L1 signalling also in a form of in-band signalling, see clause 5.2.3. 7.2.3.3 Repetition of L1-post dynamic data To obtain increased robustness for the dynamic part of L1-post signalling, the information may be repeated in the preambles of two successive T2-frames. The use of this repetition is signalled in L1-pre parameter L1_REPETITION_FLAG. If the flag is set to '1', dynamic L1-post signalling for the current and next T2-frames are present in the P2 symbol(s) as illustrated in figure 29. Thus, if repetition of L1-post dynamic data is used, the L1-post signalling consists of one configurable and two dynamic parts as depicted. When TFS is used, these two parts shall signal the information for the next T2-frame and the next-but-one T2-frame respectively. Figure 29: Repetition of L1-post dynamic information ETSI 68 ETSI EN 302 755 V1.1.1 (2009-09) The L1-post signalling shall not change size between the frames of one super-frame. If there is to be a configuration change at the start of super-frame j, the loops of both parts of the dynamic information of the last T2-frame of super-frame j-1 shall contain only the PLPs and AUXILIARY_STREAMs present in super-frame j-1. If a PLP or AUXILIARY_STREAM is not present in super-frame j, the fields of the relevant loop shall be set to '0' in super-frame j-1. EXAMPLE: Super-frame 7 contains 4 PLPs, with PLP_IDs 0, 1, 2 and 3. A configuration change means that super-frame 8 will contain PLP_IDs 0, 1, 3 and 4 (i.e. PLP_ID 2 is to be dropped and replaced by PLP_ID 4). The last T2-frame of super-frame 7 contains 'current frame' and 'next frame' dynamic information where the PLP loop signals PLP_IDs 0, 1, 2 and 3 in both cases, even though this is not the correct set of PLP_IDs for the next frame. In this case the receiver will need to read all of the new configuration information at the start of the new super-frame. 7.2.3.4 L1-post extension field The L1-post extension field allows for the possibility for future expansion of the L1 signalling. Its presence is indicated by the L1-pre field L1_POST_EXTENSION. Receivers not aware of the meaning of this field shall ignore its contents. 7.2.3.5 CRC for the L1-post signalling A 32-bit error detection code is applied to the entire L1-post signalling including the configurable, the dynamic for the current T2-frame, the dynamic for the next T2-frame, if present, and the L1-post extension field, if present. The location of the CRC field can be found from the length of the L1-post, which is signalled by L1_POST_INFO_SIZE. The CRC-32 is defined in annex F. 7.2.3.6 L1 padding This variable-length field is inserted following the L1-post CRC field to ensure that multiple LDPC blocks of the L1-post signalling have the same information size when the L1-post signalling is segmented into multiple blocks and these blocks are separately encoded. Details of how to determine the length of this field are described in clause 7.3.1.2. The values of the L1 padding bits, if any, are set to 0. 7.3 Modulation and error correction coding of the L1 data 7.3.1 Overview 7.3.1.1 Error correction coding and modulation of the L1-pre signalling The L1-pre signalling is protected by a concatenation of BCH outer code and LDPC inner code. The L1-pre signalling bits have a fixed length and they shall be first BCH-encoded, where the BCH parity check bits of the L1-pre signalling shall be appended to the L1-pre signalling. The concatenated L1-pre-signalling and BCH parity check bits are further protected by a shortened and punctured 16K LDPC code with code rate 1/4 (Nldpc=16 200). Note that effective code rate of the 16K LDPC code with code rate 1/4 is 1/5, where the effective code rate is defined as the information length over the encoder output length. Details of how to shorten and puncture the 16K LDPC code are described in clauses 7.3.2.1, 7.3.2.4 and 7.3.2.5. Note that an input parameter used for defining the shortening operation, Ksig shall be 200, equivalent to the information length of the L1-pre signalling, Kpre. An input parameter used for defining the puncturing operation, Npunc shall be as follows: ⎛ 1 ⎞ N punc = (K bch − K sig ) × ⎜ − 1⎟ = 11 488 ⎜R ⎟ ⎝ eff ⎠ where Kbch denotes the number of BCH information bits, 3 072, and Reff denotes the effective LDPC code rate 1/5 for L1-pre signalling. Note that Npunc indicates the number of LDPC parity bits to be punctured. ETSI 69 ETSI EN 302 755 V1.1.1 (2009-09) After the shortening and puncturing, the encoded bits of the L1-pre signalling shall be mapped to: (K sig + N bch _ parity ) × 1 = 1 840 BPSK symbols where Nbch_parity denotes the number of BCH parity bits, 168 Reff for 16K LDPC codes. Finally, the BPSK symbols are mapped to OFDM cells as described in clause 7.3.3. 7.3.1.2 Error correction coding and modulation of the L1-post signalling The number of L1-post signalling bits is variable, and the bits shall be transmitted over one or multiple 16K LDPC blocks depending on the length of the L1-post signalling. The number of LDPC blocks for the L1-post signalling, Npost_FEC_Block shall be determined as follows: ⎡ K post _ ex _ pad ⎤ N post _ FEC _ Block = ⎢ ⎥ , ⎢ Kbch ⎥ where ⎤ ⎡ ⎥ ⎢ x means the smallest integer larger than or equal to x, Kbch is 7 032 for the 16K LDPC code with code rate 1/2 (effective code rate is 4/9), and Kpost_ex_pad, which can be found by adding 32 to the parameter L1_POST_INFO_SIZE, denotes the number of information bits of the L1-post signalling excluding the padding field, L1_PADDING (see clause 7.2.3.6). Then, the length of L1_PADDING field, KL1_PADDING shall be calculated as: ⎡ K post _ ex _ pad ⎤ K L1_ PADDING = ⎢ ⎥ × N post _ FEC _ Block − K post _ ex _ pad . ⎢ N post _ FEC _ Block ⎥ The final length of the whole L1-post signalling including the padding field, Kpost shall be set as follows: K post = K post _ ex _ pad + K L1_ PADDING . The number of information bits in each of Npost_FEC_Block blocks, Ksig is then defined by: K post K sig = N post _ FEC _ Block . Each block with information size of Ksig is protected by a concatenation of BCH outer codes and LDPC inner codes. Each block shall be first BCH-encoded, where its Nbch_parity (= 168) BCH parity check bits shall be appended to information bits of each block. The concatenated information bits of each block and BCH parity check bits are further protected by a shortened and punctured 16K LDPC code with code rate 1/2 (effective code rate of the 16K LDPC with code rate 1/2, Reff_16K_LDPC_1_2 is 4/9). Details of how to shorten and puncture the 16K LDPC code are described in clauses 7.3.2.1, 7.3.2.4 and 7.3.2.5. For a given Ksig and modulation order (BPSK, QPSK, 16-QAM, or 64-QAM are used for the L1-post signalling), Npunc shall be determined by the following steps: ⎛ ⎢6 ⎥⎞ • Step 1) N punc _ temp = max⎜ N L1_ mult − 1, ⎜ ⎢ 5 × ( K bch − K sig )⎥ ⎟ where ⎟ ⎝ ⎣ ⎦⎠ ⎧ If N P 2 = 1, 2 × η mod N L1_ mult = ⎨ , ⎩ Otherwise, N P 2 ×η mod and the operation x ⎥ ⎢ ⎦ ⎣ means the largest integer less than or equal to x and ⎧ x, if x >= y max( x, y ) = ⎨ . ⎩ y, if y > x ETSI 70 ETSI EN 302 755 V1.1.1 (2009-09) This makes sure that the effective LDPC code rate of the L1-post signalling, Reff_post is always lower than or equal to Reff_16K_LDPC_1_2 (= 4/9). Furthermore, Reff_post tends to decrease as the information length Ksig decreases. • Step 2) N post _ temp = K sig + N bch _ parity + N ldpc × (1 − Reff _ 16 K _ LDPC _ 1 _ 2 ) − N punc _ temp For the 16K LDPC code with effective code rate 4/9, N ldpc × (1 − Reff _ 16 K _ LDPC _ 1 _ 2 ) = 9 000 . ⎧ ⎡ N post _ temp ⎤ If N P 2 = 1, × 2η MOD , 2η MOD ⎪ ⎢ ⎥ N post = ⎪ ⎢ ⎥ ⎨ ⎡ N post _ temp ⎤ ×η MOD × N P 2 , ⎪ Otherwise, η MOD × N P 2 ⎪ ⎢ ⎥ • Step 3) ⎩ ⎢ ⎥ where ηMOD denotes the modulation order and it is 1, 2, 4, and 6 for BPSK, QPSK, 16-QAM, and 64-QAM, respectively, and NP2 is the number of P2 symbols of a given FFT size as shown in table 45 in clause 8.3.2. This step guarantees that Npost is a multiple of the number of columns of the bit interleaver (described in clause 7.3.2.6) and that Npost/ηMOD is a multiple NP2. Step 4) N punc = N punc _ temp − ( N post − N post _ temp ) . Npost means the number of the encoded bits for each information block. After the shortening and puncturing, the N post encoded bits of each block shall be mapped to N MOD _ per _ Block = modulated symbols. The total number of the η MOD modulation symbols of Npost_FEC_Block blocks, N MOD _ Total is N MOD _ Total = N MOD _ per _ Block × N post _ FEC _ Block . Note that L1_POST_SIZE (an L1-pre signalling field) shall be set to N MOD _ Total . When 16-QAM or 64-QAM is used, a bit interleaving shall be applied across each LDPC block. Details of how to interleave the encoded bits are described in clause 7.3.2.6. When BPSK or QPSK is used, bit interleaving shall not be applied. Demultiplexing is then performed as described in clause 7.3.3.1. The demultiplexer output is then mapped to either BPSK, QPSK, 16-QAM, or 64-QAM constellation, as described in clause 6.2.2. Finally, the modulation symbols are then mapped to carriers as described in clause 8.3.5. 7.3.2 FEC Encoding 7.3.2.1 Zero padding of BCH information bits Ksig bits defined in clauses 7.3.1.1 and 7.3.1.2 shall be encoded into a 16K (Nldpc=16 200) LDPC codeword after BCH encoding. If the Ksig is less than the number of BCH information bits (= Kbch) for a given code rate, the BCH code will be shortened. A part of the information bits of the 16K LDPC code shall be padded with zeros in order to fill Kbch information bits. The padding bits shall not be transmitted. All Kbch BCH information bits, denoted by {m0, m1, …, mKbch-1 }, are divided into Ngroup (= Kldpc/360) groups as follows: ⎧ ⎢ k ⎥ ⎫ X j = ⎨mk j = ⎢ ⎥ ,0 ≤ k < K bch ⎬ for 0 ≤ j < N group , ⎩ ⎣ 360 ⎦ ⎭ where Xj represents the jth bit group. The code parameters (Kbch, Kldpc) are given in table 33 for L1-pre and L1-post. ETSI 71 ETSI EN 302 755 V1.1.1 (2009-09) Table 33: Code parameters (Kbch, Kldpc) for L1-pre and L1-post Kbch Kldpc L1-pre signalling 3 072 3 240 L1-post signalling 7 032 7 200 For 0 ≤ j ≤ N group − 2 , each bit group X j has 360 bits and the last bit group X N −1 has 360 - (Kldpc - Kbch)=192 group bits, as illustrated in figure 30. Figure 30: Format of data after LDPC encoding of L1 signalling For the given Ksig, the number of zero-padding bits is calculated as (Kbch - Ksig). Then, the shortening procedure is as follows: • Step 1) Compute the number of groups in which all the bits shall be padded, Npad such that: If 0 < K sig ≤ 360 , N pad = N group − 1 ⎢ K bch − K sig ⎥ Otherwise, N pad =⎢ ⎥ ⎣ 360 ⎦ • Step 2) For Npad groups X π S (0) , X π S (1) , …, X π S ( m−1) X π S ( N pad −1) , all information bits of the groups shall be padded with zeros. Here, πS is a permutation operator depending on the code rate and modulation order, described in tables 34 and 35. • Step 3) If N pad = N group − 1 , (360 − K sig ) information bits in the last part of the bit group X π S ( N group −1) shall be additionally padded. Otherwise, for the group X π S ( N pad ) , (K bch − K sig − 360 × N pad ) information bits in the last part of X π S ( N pad ) shall be additionally padded. • Step 4) Finally, Ksig information bits are sequentially mapped to bit positions which are not padded in Kbch BCH information bits, {m0, m1, …, mKbch-1 }by the above procedure. EXAMPLE: Suppose for example the value of Ksig is 1 172 and Kbch is 3 072. In this case, from step (1), 5 groups would have all zero padded bits, and from step (2) these groups would be those with numbers 7, 3, 6, 5, 2. From step (3), an additional 100 bits would be zero padded in group 4. Finally from step (4) the 1172 bits would be mapped sequentially to groups 0, 1 (360 bits each), the first part of group 4 (260 bits) and group 8 (192 bits). Figure 31 illustrates the shortening of the BCH information part in this case, i.e. filling BCH information bit positions not zero padded with Ksig information bits. ETSI 72 ETSI EN 302 755 V1.1.1 (2009-09) Kbch BCH Information bits BCHFEC th 0th 1st 2nd 3rd 4th 5th 6th 7th 8 Bit Bit Group Bit Group Bit Group Bit Group Bit Group Bit Group Bit Group Bit Group Group Mapping of Ksig information bits Ksig information bits Zero padded bits to BCH information part Figure 31: Example of Shortening of BCH information part Table 34: Permutation sequence of information bit group to be padded for L1-pre signalling Modulation π S ( j) (0 ≤ j < Ngroup) Ngroup and Code rate π S (0) π S (1) π S (2) π S (3) π S (4) π S (5) π S (6) π S (7) π S (8) BPSK 1/4 9 7 3 6 5 2 4 1 8 0 Table 35: Permutation sequence of information bit group to be padded for L1-post signalling π S ( j) (0 ≤ j < Ngroup) Modulation and Code rate Ngroup π S (0) π S (1) π S (2) π S (3) π S (4) π S (5) π S (6) π S (7) π S (8) π S (9) π S (10) π S (11) π S (12) π S (13) π S (14) π S (15) π S (16) π S (17) π S (18) π S (19) BPSK 18 17 16 15 14 13 12 11 4 10 1/2 20 / QPSK 9 8 3 2 7 6 5 1 19 0 18 17 16 15 14 13 12 11 4 10 16-QAM 1/2 20 9 8 7 3 2 1 6 5 19 0 18 17 16 4 15 14 13 12 3 11 64-QAM 1/2 20 10 9 2 8 7 1 6 5 19 0 7.3.2.2 BCH encoding The Kbch information bits (including the Kbch - Ksig zero padding bits) shall first be BCH encoded according to clause 6.1.1 to generate Nbch = Kldpc output bits (i0… iNbch-1). 7.3.2.3 LDPC encoding The Nbch=Kldpc output bits (i0… iNbch-1) from the BCH encoder, including the (Kbch - Ksig) zero padding bits and the (Kldpc - Kbch) BCH parity bits form the Kldpc information bits I = (i0, i1, …, iKldpc-1) for the LDPC encoder. The LDPC encoder shall systematically encode the Kldpc information bits onto a codeword of size Nldpc: Λ Λ = (i0, i1, …, iKldpc-1, p0, p1, …, p Nldpc- Kldpc-1) according to clause 6.1.2. 7.3.2.4 Puncturing of LDPC parity bits When the shortening is applied to encoding of the signalling bits, some LDPC parity bits shall be punctured after the LDPC encoding. These punctured bits shall not be transmitted. All Nldpc - Kldpc LDPC parity bits, denoted by {p0, p1, …, pNldpc- Kldpc -1}, are divided into Qldpc parity groups where each parity group is formed from a sub-set of the Nldpc - Kldpc LDPC parity bits as follows: { Pj = p k k mod q = j , 0 ≤ k < N ldpc − K ldpc } for 0≤ j Re{X k } ′ { } AND Re{X c′, k }⋅ Re{X k } > 0 ′ ⎪ Re X ACE , k = ⎪ ⎨ ⎪ ⎪ Re{X k } else ⎪ ⎪ ⎩ ⎧ if Im{X k } is extendable ⎪ ⎪ { Im X c′, k ′ } { } AND Im X c′, k > Im{X k } ′ { } AND Im{X c′, k }⋅ Im{X k } > 0 ′ ⎪ Im X ACE , k = ⎪ ⎨ ⎪ ⎪ Im{X k } else ⎪ ⎪ ⎩ x ACE is obtained from X ACE through IFFT. A component is defined as extendable if it belongs to a data modulated cell, and if its absolute value is equal to the maximal component value associated to the modulation constellation used for that cell. As an example, a component belonging to a 256 QAM modulated cell is extendable if it value is ± 15 sqrt (170) . The value for the gain G shall be selectable in the range between 0 and 31 in steps of 1. The clipping threshold Vclip shall be selectable in the range between +0 dB and +12,7 dB in 0,1 dB steps above the standard deviation of the original time-domain signal. The maximal extension value L shall be selectable in the range between 0,7 and 1,4 in 0,1 steps. NOTE: If L is set to 0,7 there will be no modification of the original signal. When L is set to its maximum value, the maximal power increase per carrier after extension is obtained for QPSK and bounded to +6 dB. 9.6.2 PAPR reduction using tone reservation The reserved carriers described in clause 9.3 shall not carry data nor L1/L2 signalling, but arbitrary complex values to be used for PAPR reduction. The signal power of each reserved carrier shall not exceed 10 times the average power of data carriers. ETSI 109 ETSI EN 302 755 V1.1.1 (2009-09) 9.6.2.1 Algorithm of PAPR reduction using tone reservation Signal peaks in the time domain are iteratively cancelled out by a set of impulse-like kernels made using the reserved carriers. A reference kernel signal, is defined as: N FFT p= IFFT (1TR ) N TR where NFFT and NTR indicate the FFT size and the number of reserved carriers, respectively. The (NFFT, 1) vector 1TR has NTR elements of ones at the positions corresponding to the reserved carrier indices and has (NFFT - NTR) elements of zeros at the others. IFFT represents the inverse Fast Fourier Transform defined by: 2πik 1 N −1 j X (k ) = IFFT ( x) = ∑ N i =0 x (i ) × e N Denote the vector of peak reduction signal by c, and the vector of time domain data signal by x, then the procedures of the PAPR reduction algorithm are as follows: Initialization: The initial values for peak reduction signal are set to zeros: c( 0 ) = [ 0 0] T L where c(i) means the vector of the peak reduction signal computed in ith iteration. Iteration: 1) i starts from 1. 2) Find the maximum magnitude of (x+ c(i)), yi and the corresponding sample index, mi in the ith iteration. ⎧ yi = max x n + c ni −1) ( for n = 0,1,...N FFT − 1, ⎪ n , mi = arg max xn + cni −1) ⎨ ( ⎪ ⎩ n where xn and cn(i) represent the nth element of vector x and c(i), respectively. If yi is less than or equal to a desired clipping magnitude level, Vclip then decrease i by 1 and go to the step 5. 3) Update the vector of peak reduction signal c(i) as: xmi + cmii−1) ( c( ) = c( i i −1) − α i p ( mi ) , where α i = yi ( y −V ) , i clip pk ( mi ) = p( k −mi ) mod N FFT where p(mi) denotes the vector circularly shifted by mi, of which k-th element is 4) If i is less than a maximum allowed number of iterations, increase i by 1and return to step 2. Otherwise, go to step 5. 5) Terminate the iterations. Transmitted signal, x′ is obtained by adding the peak reduction signal to the data signal: x′ = x + c ( ) i ETSI 110 ETSI EN 302 755 V1.1.1 (2009-09) 9.7 Guard interval insertion Seven different guard interval fractions (Δ/Tu) are defined. Table 61 gives the absolute guard interval duration Δ, expressed in multiples of the elementary period T (see clause 9.5) for each combination of FFT size and guard interval fraction. Some combinations of guard interval fraction and FFT size shall not be used and are marked 'NA' in table 59. Table 61: Duration of the guard interval in terms of the elementary period T Guard interval fraction (Δ/Tu) FFT size 1/128 1/32 1/16 19/256 1/8 19/128 1/4 32K 256T 1 024T 2 048T 2 432T 4 096T 4 864T NA 16K 128T 512T 1 024T 1 216T 2 048T 2 432T 4 096T 8K 64T 256T 512T 608T 1 024T 1 216T 2 048T 4K NA 128T 256T NA 512T NA 1 024T 2K NA 64T 128T NA 256T NA 512T 1K NA NA 64T NA 128T NA 256T The emitted signal, as described in clause 9.5, includes the insertion of guard intervals when PAPR reduction is not used. If PAPR reduction is used, the guard intervals shall be inserted following PAPR reduction. 9.8 P1 Symbol insertion 9.8.1 P1 Symbol overview Preamble symbol P1 has four main purposes. First it is used during the initial signal scan for fast recognition of the T2 signal, for which just the detection of the P1 is enough. Construction of the symbol is such that any frequency offsets can be detected directly even if the receiver is tuned to the nominal centre frequency. This saves scanning time as the receiver does not have to test all the possible offsets separately. The second purpose for P1 is to identify the preamble itself as a T2 preamble. The P1 symbol is such that it can be used to distinguish itself from other formats used in the FEF parts coexisting in the same super-frame. The third task is to signal basic TX parameters that are needed to decode the rest of the preamble which can help during the initialization process. The fourth purpose of P1 is to enable the receiver to detect and correct frequency and timing synchronization. 9.8.2 P1 Symbol description P1 is a 1K OFDM symbol with two 1/2 "guard interval-like" portions added. The total symbol lasts 224 μs in 8 MHz system, comprising 112 μs, the duration of the useful part 'A' of the symbol plus two modified 'guard-interval' sections 'C' and 'B' of roughly 59 μs (542 samples) and 53 μs (482 samples), see figure 49. BODY P1 P2 BODY 1K Symbol C A B fSH fSH TP1C = 59µs TP1A = 112 µs TP1B = 53µs Figure 49: P1 symbol structure ETSI 111 ETSI EN 302 755 V1.1.1 (2009-09) Out of the 853 useful carriers of a 1K symbol, only 384 are used, leaving others set to zero. The used carriers occupy roughly 6,83 MHz band from the middle of the nominal 7,61 MHz signal bandwidth. Design of the symbol is such that even if a maximum offset of 500 kHz is used, most of the used carriers in P1 symbol are still within the 7,61 MHz nominal bandwidth and the symbol can be recovered with the receiver tuned to nominal centre frequency. The first active carrier corresponds to 44, while the last one is 809 (see figure 50). 7.61 MHz 6.83 MHz … … … … Carrier 0 1 4 4 4 4 4 4 4 8 8 8 8 8 8 3 4 5 7 2 2 2 0 0 0 0 1 5 index 5 6 7 5 6 7 9 0 2 Active Unused Carrier Carrier Figure 50: Active carriers of the P1 symbol The scheme in figure 51 shows how the P1 symbol is generated. Later clauses describe each functional step in detail. CDS Table DBPSK Padding to IFFT C-A-B Scrambling Structure Mapping 1K carriers 1K (fSH) P1 Signalling S1 to MSS S2 Figure 51: Block diagram of the P1 symbol generation 9.8.2.1 Carrier Distribution in P1 symbol The active carriers are distributed using the following algorithm: out of the 853 carriers of the 1K symbol, the 766 carriers from the middle are considered. From these 766 carriers, only 384 carry pilots; the others are set to zero. In order to identify which of the 766 carriers are active, three complementary sequences are concatenated: the length of the two sequences at the ends is 128, while the sequence in the middle is 512 chips long. The last two bits of the third concatenated sequence are zero, resulting in 766 carriers where 384 of them are active carriers. The resulting carrier distribution is shown in table 62. ETSI 112 ETSI EN 302 755 V1.1.1 (2009-09) Table 62: Distribution of active carriers in the P1 symbol Modulation Active Carriers in P1 Sequence kP1(0)..kP1(383) (see clause 9.8.2.2) kP1(0)..kP1(63) 44 45 47 51 54 59 62 64 65 66 70 75 78 80 81 82 84 85 87 88 89 90 94 96 97 98 102 107 110 112 113 114 116 117 119 120 121 122 124 CSSS1 125 127 131 132 133 135 136 137 138 142 144 145 146 148 149 151 152 153 154 158 160 161 162 166 171 kP1(64)..kP1(319) 172 173 175 179 182 187 190 192 193 194 198 203 206 208 209 210 212 213 215 216 217 218 222 224 225 226 230 235 238 240 241 242 CSSS2 244 245 247 248 249 250 252 253 255 259 260 261 263 264 265 266 270 272 273 274 276 277 279 280 281 282 286 288 289 290 294 299 300 301 303 307 310 315 318 320 321 322 326 331 334 336 337 338 340 341 343 344 345 346 350 352 353 354 358 363 364 365 367 371 374 379 382 384 385 386 390 395 396 397 399 403 406 411 412 413 415 419 420 421 423 424 425 426 428 429 431 435 438 443 446 448 449 450 454 459 462 464 465 466 468 469 471 472 473 474 478 480 481 482 486 491 494 496 497 498 500 501 503 504 505 506 508 509 511 515 516 517 519 520 521 522 526 528 529 530 532 533 535 536 537 538 542 544 545 546 550 555 558 560 561 562 564 565 567 568 569 570 572 573 575 579 580 581 583 584 585 586 588 589 591 595 598 603 604 605 607 611 612 613 615 616 617 618 622 624 625 626 628 629 631 632 633 634 636 637 639 643 644 645 647 648 649 650 654 656 657 658 660 661 663 664 665 666 670 672 673 674 678 683 kP1(320)..kP1(383) 684 689 692 696 698 699 701 702 703 704 706 707 708 712 714 715 717 718 719 720 722 723 725 726 727 729 CSSS1 733 734 735 736 738 739 740 744 746 747 748 753 756 760 762 763 765 766 767 768 770 771 772 776 778 779 780 785 788 792 794 795 796 801 805 806 807 809 9.8.2.2 Modulation of the Active Carriers in P1 Active carriers are DBPSK modulated with a modulation pattern. The patterns, described later, encode two signalling fields S1 and S2. Up to 8 values (can encode 3 bits) and 16 values (can encode 4 bits) can be signalled in each field, respectively. Patterns to encode S1 are based on 8 orthogonal sets of 8 complementary sequences of length 8 (total length of each S1 pattern is 64), while patterns to encode S2 are based of 16 orthogonal sets of 16 complementary sequences of length 16 (total length of each S2 pattern is 256). The two main properties of these patterns are: a) The sum of the auto-correlations (SoAC) of all the sequences of the set is equal to a Krönecker delta, multiplied by KN factor, being K the number of the sequences of each set and N the length of each sequence. In the case of S1 K=N=8; in the case of S2, K=N=16. b) Each set of sequences are mutually uncorrelated (also called "mates"). The S1 and S2 modulation patterns are shown in table 63. ETSI 113 ETSI EN 302 755 V1.1.1 (2009-09) Table 63: S1 and S2 Modulation patterns Field Val Sequence (Hexadecimal notation) S1 000 124721741D482E7B 001 47127421481D7B2E 010 217412472E7B1D48 011 742147127B2E481D 100 1D482E7B12472174 101 481D7B2E47127421 110 2E7B1D4821741247 111 7B2E481D74214712 S2 0000 121D4748212E747B1D1248472E217B7412E247B721D174841DED48B82EDE7B8B 0001 4748121D747B212E48471D127B742E2147B712E2748421D148B81DED7B8B2EDE 0010 212E747B121D47482E217B741D12484721D1748412E247B72EDE7B8B1DED48B8 0011 747B212E4748121D7B742E2148471D12748421D147B712E27B8B2EDE48B81DED 0100 1D1248472E217B74121D4748212E747B1DED48B82EDE7B8B12E247B721D17484 0101 48471D127B742E214748121D747B212E48B81DED7B8B2EDE47B712E2748421D1 0110 2E217B741D124847212E747B121D47482EDE7B8B1DED48B821D1748412E247B7 0111 7B742E2148471D12747B212E4748121D7B8B2EDE48B81DED748421D147B712E2 1000 12E247B721D174841DED48B82EDE7B8B121D4748212E747B1D1248472E217B74 1001 47B712E2748421D148B81DED7B8B2EDE4748121D747B212E48471D127B742E21 1010 21D1748412E247B72EDE7B8B1DED48B8212E747B121D47482E217B741D124847 1011 748421D147B712E27B8B2EDE48B81DED747B212E4748121D7B742E2148471D12 1100 1DED48B82EDE7B8B12E247B721D174841D1248472E217B74121D4748212E747B 1101 48B81DED7B8B2EDE47B712E2748421D148471D127B742E214748121D747B212E 1110 2EDE7B8B1DED48B821D1748412E247B72E217B741D124847212E747B121D4748 1111 7B8B2EDE48B81DED748421D147B712E27B742E2148471D12747B212E4748121D The bit sequences CSSS1 =(CSSS1,0 … CSSS1,63) and CSSS2=(CSSS2,0 … CSSS2,255) for given values of S1 and S2 respectively is obtained by taking the corresponding hexadecimal sequence from left to right and from MSB to LSB, i.e. CSSS1,0 is the MSB of the first hexadecimal digit and CSSS1,63 is the LSB of the last digit of the S1 sequence. The final modulation signal is obtained as follows: 1) The Modulation sequence is obtained by concatenating the two CSSS1 and CSSS2 sequences; the CSSS1 sequence is attached at both sides of the CSSS2: {MSS _ SEQ0 ..MSS _ SEQ383 } = {CSS S1 , CSS S 2 , CSS S 1} = {CSS S1, 0 ,..., CSS S1, 63 , CSS S 2,0 , ..., CSS S 2, 255 , CSS S1, 0 ,..., CSS S1, 63} 2) Then, the sequence is modulated using DBPSK: MSS _ DIFF = DBPSK ( MSS _ SEQ) The following rule applies for the differential modulation of element i of the MSS_SEQ: ⎧ MSS _ DIFFi−1 MSS _ SEQi = 0 MSS _ DIFFi = ⎨ ⎩− MSS _ DIFFi−1 MSS _ SEQi = 1 The differential encoding is started from "dummy" value of +1, i.e. MSS_DIFF-1 = +1 by definition. This bit is not applied to any carrier. 3) A scrambling is applied on the MSS_DIFF by bit-by-bit multiplying by a 384-bit scrambler sequence: MSS _ SCR = SCRAMBLING MSS _ DIFF} { The scrambler sequence shall be equal to the 384-length sequence of '+1' or '-1' converted from the first 384 bits (PRBS0...PRBS383) of the PRBS generator described in clause 5.2.4 with initial state '100111001000110', where a PRBS generator output bit with a value of '0' is converted into '+1' and a PRBS generator output bit with a value of '1' is converted into '-1'. ⎛1 ⎞ MSS _ SCRi = MSS _ DIFFi × 2⎜ − PRBS i ⎟ ⎝2 ⎠ ETSI 114 ETSI EN 302 755 V1.1.1 (2009-09) 4) The scrambled modulation pattern is applied to the active carriers. EXAMPLE: If S1=000 and S2=0000, then: The sequence is: MSS _ SEQ = { 4 22E4 , 1214 7B8B , 1247...244} 1 4... 47B 14243 14 2E73 1247 3 D... 4 4 B CSS S 1 CSS S 2 CSS S 1 = {0,0,0,1,...,1,0,1,1 , 0,0,0,1240,3 , 0,0,0,1,...,1,0,1,1} 4,...,1, 4,1 144 44 1 144 44 14 2 3 2 3 CSS S 1 CSS S 2 CSS S 1 Then, DBPSK is applied: MSS _ DIFF = { ,1,1,−1,...,1,1,−1,1 , 1,1,442443 , 1,1,1,−1,...,1,1,−1,1} 1 1,−1,...,1,1,−1,1 1442443 1 1442443 CSS S 1 CSS S 2 CSS S 1 The DBPSK output is scrambled by the scrambling sequence, SCR_SEQ. 1 SCR _ SEQ = 2( − PRBSi ) 2 = {− 1,1,−1,1,...,−1,−1,1,1 , − 141,−4−244441 , 1,1,−1,−1,...,1,1,−1,1} ,− 1, 1,...,1,−1,−3 1, 1444 444 1 4 4 2 3 144 2444 4 3 64 256 64 after scrambling: MSS _ SCR = {− 1,1,−1,−1,...,−1,−1,−1,1 , − 141,−12444,1 , 1,1,−1,1,...,1,1,1,1} ,− 41,...,1,−1,3 , 1 1444 24444 1 4 4 3 144 44 2 3 CSS S 1 CSS S 2 CSS S 1 The scrambled modulation MSS is mapped to the active carriers, MSB first: c44 = −1, c45 = 1, c47 = −1, c51 = −1,..., c171 = 1 c172 = −1, c173 = −1, c175 = −1,..., c683 = 1 c684 = 1,..., c805 = 1, c806 = 1, c807 = 1, c809 = 1 where ck is the modulation applied to carrier k. The equation for the modulation of the P1 carriers is given in clause 9.8.2.4. 9.8.2.3 Boosting of the Active Carriers Taking into account that in a 1K OFDM symbol only 853 carriers are used, and in P1 there are only 384 active carriers, the boosting applied to the P1 active carriers is a voltage ratio of (853 / 384) or 3,47 dB, relative to the mean value of all Ktotal of the used carriers of a 1K normal symbol. 9.8.2.4 Generation of the time domain P1 signal 9.8.2.4.1 Generation of the main part of the P1 signal The useful part 'A' of the P1 signal is generated from the carrier modulation values, according to the following equation: kP 1 ( i )− 426 1 383 j 2π p1 A (t ) = ∑ MSS _ SCRi × e t 1024T 384 i =0 ETSI 115 ETSI EN 302 755 V1.1.1 (2009-09) where kp1(i) for i=0,1,…, 383 are the indices of the 384 active carriers, in increasing order, as defined in clause 9.8.2.1. MSS_SCRi for i=0,1,… , 383 are the modulation values for the active carriers as defined in clause 9.8.2.2, and T is the elementary time period and is defined in table 59. NOTE: This equation, taken together with the equation in clause 9.5, includes the effect of the boosting described in clause 9.8.2.3, which ensures the power of the P1 symbol is virtually the same as the power of the remaining symbols. 9.8.2.4.2 Frequency Shifted repetition in Guard Intervals In order to improve the robustness of the P1, two guard intervals are defined at both sides of the useful part of the symbol. Instead of cyclic continuation like normal OFDM symbols, a frequency shift version of the symbol is used. Thus, denoting P1[C], the first guard interval, P1[A] the main part of the symbol and P1[B] the last guard interval of the symbol, P1[C] carries the frequency shifted version of the first 542T of P1[A], while P1[B] conveys the frequency shifted version of the last 482T of P1[A] (see figure 49). The frequency shift fSH applied to P1[C] and P1[B] is: f SH = 1 /(1 024T ) The time-domain baseband waveform p1(t) of the P1 symbol is therefore defined as follows: ⎧ 2π j t ⎪ p1 A (t )e 1024T 0 ≤ t < 542T p1 A (t − 542T ) ⎪ 542T ≤ t < 1 566T p1 (t ) = ⎪ ⎨ 2π j t p1 A (t − 1 024T )e ⎪ 1 024T ⎪ 1 566 ≤ t < 2 048T ⎪ 0 otherwise ⎩ 10 Spectrum characteristics The OFDM symbols constitute a juxtaposition of equally-spaced orthogonal carriers. The amplitudes and phases of the data cell carriers are varying symbol by symbol according to the mapping process previously described. The power spectral density Pk' (f) of each carrier at frequency: k' ⎛ K −1⎞ K −1 fk ' = fc + for ⎜ − total ⎟ ≤ k ' ≤ total Tu ⎝ 2 ⎠ 2 is defined by the following expression: 2 ⎡ sin π ( f − f k ' )Ts ⎤ Pk ' ( f ) = ⎢ ⎥ ⎣ π ( f − f k ' )Ts ⎦ The overall power spectral density of the modulated data cell carriers is the sum of the power spectral densities of all these carriers. A theoretical DVB transmission signal spectrum is illustrated in figure 52 (for 8 MHz channels). Because the OFDM symbol duration is larger than the inverse of the carrier spacing, the main lobe of the power spectral density of each carrier is narrower than twice the carrier spacing. Therefore the spectral density is not constant within the nominal bandwidth. NOTE 1: This theoretical spectrum takes no account of the variations in power from carrier to carrier caused by the boosting of the pilot carriers. ETSI 116 ETSI EN 302 755 V1.1.1 (2009-09) Figure 52(a): Theoretical DVB-T2 signal spectrum for guard interval fraction 1/8 (for 8 MHz channels and with extended carrier mode for 8K, 16K and 32K) Figure 52(b): Detail of theoretical DVB-T2 spectrum for guard interval fraction 1/8 (for 8 MHz channels) No specific requirements are set in terms of the spectrum characteristics after amplification and filtering, since it is considered to be more appropriately defined by the relevant national or international authority, depending on both the region and the frequency band in which the T2 system is to be deployed. NOTE 2: The use of PAPR reduction techniques described here can significantly help to reduce the level of out-of-band emissions following high power amplification. It is assumed that these techniques are likely to be needed when the extended carrier modes are being used. ETSI 117 ETSI EN 302 755 V1.1.1 (2009-09) Annex A (normative): Addresses of parity bit accumulators for Nldpc = 64 800 Example of interpretation of the table A.1. p54 = p54 ⊕ i0 p9318 = p9318 ⊕ i0 p14392 = p14392 ⊕ i0 p27561 = p27561 ⊕ i0 p26909 = p26909 ⊕ i0 p10219 = p10219 ⊕ i0 p2534 = p2534 ⊕ i0 p8597 = p8597 ⊕ i0 p144 = p144 ⊕ i1 p9408 = p9408 ⊕ i1 p14482 = p14482 ⊕ i1 p27651 = p27651 ⊕ i1 p26999 = p26999 ⊕ i1 p10309 = p10309 ⊕ i1 p2624 = p2624 ⊕ i1 p8687 = p8687 ⊕ i1 : : : : : : : : : : : : : : : : : : p32364 = p32364 ⊕ i359 p9228 = p9228 ⊕ i359 p14302 = p14302 ⊕ i359 p27471 = p27471 ⊕ i359 p26819 = p26819 ⊕ i359 p10129 = p10129 ⊕ i359 p2444 = p2444 ⊕ i359 p8507 = p8507 ⊕ i359 p55 = p55 ⊕ i360 p7263 = p7263 ⊕ i360 p4635 = p4635 ⊕ i360 p2530 = p2530 ⊕ i360 p28130 = p28130 ⊕ i360 p3033 = p3033 ⊕ i360 p23830 = p23830 ⊕ i360 p3651 = p3651 ⊕ i360 : : : : : : : : : : : : : : : : : : ETSI 118 ETSI EN 302 755 V1.1.1 (2009-09) Table A.1: Rate 1/2 (Nldpc = 64 800) 54 9318 14392 27561 26909 10219 2534 8597 20 19978 27197 55 7263 4635 2530 28130 3033 23830 3651 21 27060 15071 56 24731 23583 26036 17299 5750 792 9169 22 6071 26649 57 5811 26154 18653 11551 15447 13685 16264 23 10393 11176 58 12610 11347 28768 2792 3174 29371 12997 24 9597 13370 59 16789 16018 21449 6165 21202 15850 3186 25 7081 17677 60 31016 21449 17618 6213 12166 8334 18212 26 1433 19513 61 22836 14213 11327 5896 718 11727 9308 27 26925 9014 62 2091 24941 29966 23634 9013 15587 5444 28 19202 8900 63 22207 3983 16904 28534 21415 27524 25912 29 18152 30647 64 25687 4501 22193 14665 14798 16158 5491 30 20803 1737 65 4520 17094 23397 4264 22370 16941 21526 31 11804 25221 66 10490 6182 32370 9597 30841 25954 2762 32 31683 17783 67 22120 22865 29870 15147 13668 14955 19235 33 29694 9345 68 6689 18408 18346 9918 25746 5443 20645 34 12280 26611 69 29982 12529 13858 4746 30370 10023 24828 35 6526 26122 70 1262 28032 29888 13063 24033 21951 7863 36 26165 11241 71 6594 29642 31451 14831 9509 9335 31552 37 7666 26962 72 1358 6454 16633 20354 24598 624 5265 38 16290 8480 73 19529 295 18011 3080 13364 8032 15323 39 11774 10120 74 11981 1510 7960 21462 9129 11370 25741 40 30051 30426 75 9276 29656 4543 30699 20646 21921 28050 41 1335 15424 76 15975 25634 5520 31119 13715 21949 19605 42 6865 17742 77 18688 4608 31755 30165 13103 10706 29224 43 31779 12489 78 21514 23117 12245 26035 31656 25631 30699 44 32120 21001 79 9674 24966 31285 29908 17042 24588 31857 45 14508 6996 80 21856 27777 29919 27000 14897 11409 7122 46 979 25024 81 29773 23310 263 4877 28622 20545 22092 47 4554 21896 82 15605 5651 21864 3967 14419 22757 15896 48 7989 21777 83 30145 1759 10139 29223 26086 10556 5098 49 4972 20661 84 18815 16575 2936 24457 26738 6030 505 50 6612 2730 85 30326 22298 27562 20131 26390 6247 24791 51 12742 4418 86 928 29246 21246 12400 15311 32309 18608 52 29194 595 87 20314 6025 26689 16302 2296 3244 19613 53 19267 20113 88 6237 11943 22851 15642 23857 15112 20947 89 26403 25168 19038 18384 8882 12719 7093 0 14567 24965 1 3908 100 2 10279 240 3 24102 764 4 12383 4173 5 13861 15918 6 21327 1046 7 5288 14579 8 28158 8069 9 16583 11098 10 16681 28363 11 13980 24725 12 32169 17989 13 10907 2767 14 21557 3818 15 26676 12422 16 7676 8754 17 14905 20232 18 15719 24646 19 31942 8589 ETSI 119 ETSI EN 302 755 V1.1.1 (2009-09) Table A.2: Rate 3/5 (Nldpc = 64 800) 22422 10282 11626 19997 11161 2922 3122 99 5625 17064 8270 179 16 6079 21122 25087 16218 17015 828 20041 25656 4186 11629 22599 17305 22515 6463 17 22782 5828 11049 22853 25706 14388 5500 19245 8732 2177 13555 11346 17265 3069 18 19775 4247 16581 22225 12563 19717 23577 11555 25496 6853 25403 5218 15925 21766 19 1660 19413 16529 14487 7643 10715 17442 11119 5679 14155 24213 21000 1116 15620 20 4403 3649 5340 8636 16693 1434 5635 6516 9482 20189 1066 15013 25361 14243 21 13371 25851 18506 22236 20912 8952 5421 15691 6126 21595 500 6904 13059 6802 22 22770 21784 8433 4694 5524 14216 3685 19721 25420 9937 23813 9047 25651 16826 23 10757 14131 21500 24814 6344 17382 7064 13929 4004 16552 12818 8720 5286 2206 24 16071 21617 22517 2429 19065 2921 21611 1873 7507 5661 23006 23128 20543 19777 25 6393 3725 1770 4636 20900 14931 9247 12340 11008 12966 4471 2731 16445 791 26 597 19968 6635 14556 18865 22421 22124 12697 9803 25485 7744 18254 11313 9004 27 5743 8084 19982 23963 18912 7206 12500 4382 20067 6177 21007 1195 23547 24837 28 6770 9548 756 11158 14646 20534 3647 17728 11676 11843 12937 4402 8261 22944 29 4285 17542 9306 24009 10012 11081 3746 24325 8060 19826 842 8836 2898 5019 30 13568 22599 7575 7455 25244 4736 14400 22981 5543 8006 24203 13053 1120 5128 31 1786 4617 3482 9270 13059 15825 7453 23747 3656 24585 16542 17507 22462 14670 32 23238 11648 15627 15290 4198 22748 5842 13395 23918 16985 14929 3726 25350 24157 33 19627 2030 24896 16365 16423 13461 16615 8107 24741 3604 25904 8716 9604 20365 34 13601 13458 3729 17245 18448 9862 20831 25326 20517 24618 13282 5099 14183 8804 35 13740 17328 16455 17646 15376 18194 25528 1777 6066 21855 14372 12517 4488 17490 36 25012 13944 1400 8135 23375 20879 8476 4084 12936 25536 22309 16582 6402 24360 37 22513 6687 25119 23586 128 4761 10443 22536 8607 9752 25446 15053 1856 4040 38 4934 12587 377 21160 13474 5451 17170 5938 10256 11972 24210 17833 22047 16108 39 21197 5133 13075 9648 24546 13150 23867 7309 19798 2988 16858 4825 23950 15125 40 22705 6938 20526 3553 11525 23366 2452 17626 19265 20172 18060 24593 13255 1552 41 7534 24633 18839 21132 20119 15214 14705 7096 10174 5663 18651 19700 12524 14033 42 24400 12797 4127 2971 17499 16287 22368 21463 7943 18880 5567 8047 23363 6797 43 21911 25712 10651 24471 14325 4081 7258 4949 7044 1078 797 22910 20474 4318 44 12039 1140 21374 13231 22985 5056 3821 23718 14178 9978 19030 23594 8895 25358 45 24306 1021 6199 22056 7749 13310 3999 23697 16445 22636 5225 22437 24153 9442 46 14012 20747 7978 12177 2893 20778 3175 8645 11863 24623 10311 25767 17057 3691 47 11265 15219 20473 11294 9914 22815 2574 8439 3699 5431 24840 21908 16088 18244 48 4670 15531 8208 5755 19059 8541 24924 6454 11234 10492 16406 10831 11436 9649 49 9417 14359 16264 11275 24953 2347 12667 19190 7257 7174 24819 2938 2522 11749 50 2415 6504 3627 5969 13862 1538 23176 6353 2855 17720 2472 7428 573 15036 51 24964 24690 0 18539 18661 52 14443 8816 1 10502 3002 53 6926 1291 2 9368 10761 54 6209 20806 3 12299 7828 55 13915 4079 4 15048 13362 56 24410 13196 5 18444 24640 57 13505 6117 6 20775 19175 58 9869 8220 7 18970 10971 59 1570 6044 8 5329 19982 60 25780 17387 9 11296 18655 61 20671 24913 10 15046 20659 62 24558 20591 11 7300 22140 63 12402 3702 12 22029 14477 64 8314 1357 13 11129 742 65 20071 14616 14 13254 13813 66 17014 3688 15 19234 13273 67 19837 946 68 15195 12136 69 7758 22808 70 3564 2925 71 3434 7769 ETSI 120 ETSI EN 302 755 V1.1.1 (2009-09) Table A.3: Rate 2/3 (Nldpc = 64 800) 317 2255 2324 2723 3538 3576 6194 6700 9101 10057 12739 17407 21039 10574 11268 17932 1958 2007 3294 4394 12762 14505 14593 14692 16522 17737 19245 21272 21379 15442 17266 20482 127 860 5001 5633 8644 9282 12690 14644 17553 19511 19681 20954 21002 390 3371 8781 2514 2822 5781 6297 8063 9469 9551 11407 11837 12985 15710 20236 20393 10512 12216 17180 1565 3106 4659 4926 6495 6872 7343 8720 15785 16434 16727 19884 21325 4309 14068 15783 706 3220 8568 10896 12486 13663 16398 16599 19475 19781 20625 20961 21335 3971 11673 20009 4257 10449 12406 14561 16049 16522 17214 18029 18033 18802 19062 19526 20748 9259 14270 17199 412 433 558 2614 2978 4157 6584 9320 11683 11819 13024 14486 16860 2947 5852 20101 777 5906 7403 8550 8717 8770 11436 12846 13629 14755 15688 16392 16419 3965 9722 15363 4093 5045 6037 7248 8633 9771 10260 10809 11326 12072 17516 19344 19938 1429 5689 16771 2120 2648 3155 3852 6888 12258 14821 15359 16378 16437 17791 20614 21025 6101 6849 12781 1085 2434 5816 7151 8050 9422 10884 12728 15353 17733 18140 18729 20920 3676 9347 18761 856 1690 12787 350 11659 18342 6532 7357 9151 5961 14803 16123 4210 16615 18152 2113 9163 13443 11494 14036 17470 2155 9808 12885 2474 10291 10323 2861 7988 11031 1778 6973 10739 7309 9220 20745 4347 9570 18748 6834 8742 11977 2189 11942 20666 2133 12908 14704 3868 7526 17706 10170 13809 18153 8780 14796 18268 13464 14787 14975 160 16232 17399 799 1107 3789 1285 2003 18922 3571 8176 10165 4658 17331 20361 5433 13446 15481 2765 4862 5875 3351 6767 12840 4565 5521 8759 8950 8974 11650 3484 7305 15829 1430 4250 21332 5024 17730 17879 6283 10628 15050 7031 12346 15024 8632 14404 16916 179 6365 11352 6509 10702 16278 2490 3143 5098 15900 16395 17995 2643 3101 21259 8031 18420 19733 4315 4724 13130 3747 4634 17087 594 17365 18322 4453 6297 16262 5983 8597 9627 2792 3513 17031 10837 15102 20876 14846 20893 21563 10448 20418 21478 17220 20436 21337 3848 12029 15228 275 4107 10497 708 5652 13146 3536 7520 10027 5998 7534 16117 14089 14943 19455 2098 13201 18317 1965 3931 21104 9186 14548 17776 2439 11565 17932 5246 10398 18597 154 15279 21414 3083 4944 21021 10017 11269 16546 13726 18495 19921 7169 10161 16928 6736 10811 17545 10284 16791 20655 10084 12411 14432 36 3175 8475 1064 13555 17033 2605 16269 19290 679 9878 13547 8947 9178 15420 3422 9910 20194 5687 9156 12408 3640 3701 10046 8096 9738 14711 5862 10134 11498 4935 8093 19266 5923 9580 15060 2667 10062 15972 1073 3012 16427 6389 11318 14417 5527 20113 20883 8800 18137 18434 7058 12924 15151 5824 5927 15314 9764 12230 17375 6056 13168 15179 772 7711 12723 3284 13138 18919 555 13816 15376 13115 17259 17332 ETSI 121 ETSI EN 302 755 V1.1.1 (2009-09) Table A.4: Rate 3/4 (Nldpc = 64 800) 0 6385 7901 14611 13389 11200 3252 5243 2504 2722 821 7374 23 5865 1768 1 11359 2698 357 13824 12772 7244 6752 15310 852 2001 11417 24 2655 14957 2 7862 7977 6321 13612 12197 14449 15137 13860 1708 6399 13444 25 5565 6332 3 1560 11804 6975 13292 3646 3812 8772 7306 5795 14327 7866 26 4303 12631 4 7626 11407 14599 9689 1628 2113 10809 9283 1230 15241 4870 27 11653 12236 5 1610 5699 15876 9446 12515 1400 6303 5411 14181 13925 7358 28 16025 7632 6 4059 8836 3405 7853 7992 15336 5970 10368 10278 9675 4651 29 4655 14128 7 4441 3963 9153 2109 12683 7459 12030 12221 629 15212 406 30 9584 13123 8 6007 8411 5771 3497 543 14202 875 9186 6235 13908 3563 31 13987 9597 9 3232 6625 4795 546 9781 2071 7312 3399 7250 4932 12652 32 15409 12110 10 8820 10088 11090 7069 6585 13134 10158 7183 488 7455 9238 33 8754 15490 11 1903 10818 119 215 7558 11046 10615 11545 14784 7961 15619 34 7416 15325 12 3655 8736 4917 15874 5129 2134 15944 14768 7150 2692 1469 35 2909 15549 13 8316 3820 505 8923 6757 806 7957 4216 15589 13244 2622 36 2995 8257 14 14463 4852 15733 3041 11193 12860 13673 8152 6551 15108 8758 37 9406 4791 15 3149 11981 38 11111 4854 16 13416 6906 39 2812 8521 17 13098 13352 40 8476 14717 18 2009 14460 41 7820 15360 19 7207 4314 42 1179 7939 20 3312 3945 43 2357 8678 21 4418 6248 44 7703 6216 22 2669 13975 0 3477 7067 23 7571 9023 1 3931 13845 24 14172 2967 2 7675 12899 25 7271 7138 3 1754 8187 26 6135 13670 4 7785 1400 27 7490 14559 5 9213 5891 28 8657 2466 6 2494 7703 29 8599 12834 7 2576 7902 30 3470 3152 8 4821 15682 31 13917 4365 9 10426 11935 32 6024 13730 10 1810 904 33 10973 14182 11 11332 9264 34 2464 13167 12 11312 3570 35 5281 15049 13 14916 2650 36 1103 1849 14 7679 7842 37 2058 1069 15 6089 13084 38 9654 6095 16 3938 2751 39 14311 7667 17 8509 4648 40 15617 8146 18 12204 8917 41 4588 11218 19 5749 12443 42 13660 6243 20 12613 4431 43 8578 7874 21 1344 4014 44 11741 2686 22 8488 13850 0 1022 1264 23 1730 14896 1 12604 9965 24 14942 7126 2 8217 2707 25 14983 8863 3 3156 11793 26 6578 8564 4 354 1514 27 4947 396 5 6978 14058 28 297 12805 6 7922 16079 29 13878 6692 7 15087 12138 30 11857 11186 8 5053 6470 31 14395 11493 9 12687 14932 32 16145 12251 10 15458 1763 33 13462 7428 11 8121 1721 34 14526 13119 12 12431 549 35 2535 11243 13 4129 7091 36 6465 12690 14 1426 8415 37 6872 9334 15 9783 7604 38 15371 14023 16 6295 11329 39 8101 10187 17 1409 12061 40 11963 4848 18 8065 9087 41 15125 6119 19 2918 8438 42 8051 14465 20 1293 14115 43 11139 5167 21 3922 13851 44 2883 14521 22 3851 4000 ETSI 122 ETSI EN 302 755 V1.1.1 (2009-09) Table A.5: Rate 4/5 (Nldpc = 64 800) 0 149 11212 5575 6360 12559 8108 8505 408 10026 12828 0 5647 4935 1 5237 490 10677 4998 3869 3734 3092 3509 7703 10305 1 4219 1870 2 8742 5553 2820 7085 12116 10485 564 7795 2972 2157 2 10968 8054 3 2699 4304 8350 712 2841 3250 4731 10105 517 7516 3 6970 5447 4 12067 1351 11992 12191 11267 5161 537 6166 4246 2363 4 3217 5638 5 6828 7107 2127 3724 5743 11040 10756 4073 1011 3422 5 8972 669 6 11259 1216 9526 1466 10816 940 3744 2815 11506 11573 6 5618 12472 7 4549 11507 1118 1274 11751 5207 7854 12803 4047 6484 7 1457 1280 8 8430 4115 9440 413 4455 2262 7915 12402 8579 7052 8 8868 3883 9 3885 9126 5665 4505 2343 253 4707 3742 4166 1556 9 8866 1224 10 1704 8936 6775 8639 8179 7954 8234 7850 8883 8713 10 8371 5972 11 11716 4344 9087 11264 2274 8832 9147 11930 6054 5455 11 266 4405 12 7323 3970 10329 2170 8262 3854 2087 12899 9497 11700 12 3706 3244 13 4418 1467 2490 5841 817 11453 533 11217 11962 5251 13 6039 5844 14 1541 4525 7976 3457 9536 7725 3788 2982 6307 5997 14 7200 3283 15 11484 2739 4023 12107 6516 551 2572 6628 8150 9852 15 1502 11282 16 6070 1761 4627 6534 7913 3730 11866 1813 12306 8249 16 12318 2202 17 12441 5489 8748 7837 7660 2102 11341 2936 6712 11977 17 4523 965 18 10155 4210 18 9587 7011 19 1010 10483 19 2552 2051 20 8900 10250 20 12045 10306 21 10243 12278 21 11070 5104 22 7070 4397 22 6627 6906 23 12271 3887 23 9889 2121 24 11980 6836 24 829 9701 25 9514 4356 25 2201 1819 26 7137 10281 26 6689 12925 27 11881 2526 27 2139 8757 28 1969 11477 28 12004 5948 29 3044 10921 29 8704 3191 30 2236 8724 30 8171 10933 31 9104 6340 31 6297 7116 32 7342 8582 32 616 7146 33 11675 10405 33 5142 9761 34 6467 12775 34 10377 8138 35 3186 12198 35 7616 5811 0 9621 11445 0 7285 9863 1 7486 5611 1 7764 10867 2 4319 4879 2 12343 9019 3 2196 344 3 4414 8331 4 7527 6650 4 3464 642 5 10693 2440 5 6960 2039 6 6755 2706 6 786 3021 7 5144 5998 7 710 2086 8 11043 8033 8 7423 5601 9 4846 4435 9 8120 4885 10 4157 9228 10 12385 11990 11 12270 6562 11 9739 10034 12 11954 7592 12 424 10162 13 7420 2592 13 1347 7597 14 8810 9636 14 1450 112 15 689 5430 15 7965 8478 16 920 1304 16 8945 7397 17 1253 11934 17 6590 8316 18 9559 6016 18 6838 9011 19 312 7589 19 6174 9410 20 4439 4197 20 255 113 21 4002 9555 21 6197 5835 22 12232 7779 22 12902 3844 23 1494 8782 23 4377 3505 24 10749 3969 24 5478 8672 25 4368 3479 25 4453 2132 26 6316 5342 26 9724 1380 27 2455 3493 27 12131 11526 28 12157 7405 28 12323 9511 29 6598 11495 29 8231 1752 30 11805 4455 30 497 9022 31 9625 2090 31 9288 3080 32 4731 2321 32 2481 7515 33 3578 2608 33 2696 268 34 8504 1849 34 4023 12341 35 4027 1151 35 7108 5553 ETSI 123 ETSI EN 302 755 V1.1.1 (2009-09) Table A.6: Rate 5/6 (Nldpc = 64 800) 0 4362 416 8909 4156 3216 3112 2560 2912 6405 8593 4969 6723 20 4766 2697 10 7868 5731 1 2479 1786 8978 3011 4339 9313 6397 2957 7288 5484 6031 10217 21 4069 6675 11 6121 10732 2 10175 9009 9889 3091 4985 7267 4092 8874 5671 2777 2189 8716 22 1117 1016 12 4843 9132 3 9052 4795 3924 3370 10058 1128 9996 10165 9360 4297 434 5138 23 5619 3085 13 580 9591 4 2379 7834 4835 2327 9843 804 329 8353 7167 3070 1528 7311 24 8483 8400 14 6267 9290 5 3435 7871 348 3693 1876 6585 10340 7144 5870 2084 4052 2780 25 8255 394 15 3009 2268 6 3917 3111 3476 1304 10331 5939 5199 1611 1991 699 8316 9960 26 6338 5042 16 195 2419 7 6883 3237 1717 10752 7891 9764 4745 3888 10009 4176 4614 1567 27 6174 5119 17 8016 1557 8 10587 2195 1689 2968 5420 2580 2883 6496 111 6023 1024 4449 28 7203 1989 18 1516 9195 9 3786 8593 2074 3321 5057 1450 3840 5444 6572 3094 9892 1512 29 1781 5174 19 8062 9064 10 8548 1848 10372 4585 7313 6536 6379 1766 9462 2456 5606 9975 0 1464 3559 20 2095 8968 11 8204 10593 7935 3636 3882 394 5968 8561 2395 7289 9267 9978 1 3376 4214 21 753 7326 12 7795 74 1633 9542 6867 7352 6417 7568 10623 725 2531 9115 2 7238 67 22 6291 3833 13 7151 2482 4260 5003 10105 7419 9203 6691 8798 2092 8263 3755 3 10595 8831 23 2614 7844 14 3600 570 4527 200 9718 6771 1995 8902 5446 768 1103 6520 4 1221 6513 24 2303 646 15 6304 7621 5 5300 4652 25 2075 611 16 6498 9209 6 1429 9749 26 4687 362 17 7293 6786 7 7878 5131 27 8684 9940 18 5950 1708 8 4435 10284 28 4830 2065 19 8521 1793 9 6331 5507 29 7038 1363 20 6174 7854 10 6662 4941 0 1769 7837 21 9773 1190 11 9614 10238 1 3801 1689 22 9517 10268 12 8400 8025 2 10070 2359 23 2181 9349 13 9156 5630 3 3667 9918 24 1949 5560 14 7067 8878 4 1914 6920 25 1556 555 15 9027 3415 5 4244 5669 26 8600 3827 16 1690 3866 6 10245 7821 27 5072 1057 17 2854 8469 7 7648 3944 28 7928 3542 18 6206 630 8 3310 5488 29 3226 3762 19 363 5453 9 6346 9666 0 7045 2420 20 4125 7008 10 7088 6122 1 9645 2641 21 1612 6702 11 1291 7827 2 2774 2452 22 9069 9226 12 10592 8945 3 5331 2031 23 5767 4060 13 3609 7120 4 9400 7503 24 3743 9237 14 9168 9112 5 1850 2338 25 7018 5572 15 6203 8052 6 10456 9774 26 8892 4536 16 3330 2895 7 1692 9276 27 853 6064 17 4264 10563 8 10037 4038 28 8069 5893 18 10556 6496 9 3964 338 29 2051 2885 19 8807 7645 10 2640 5087 0 10691 3153 20 1999 4530 11 858 3473 1 3602 4055 21 9202 6818 12 5582 5683 2 328 1717 22 3403 1734 13 9523 916 3 2219 9299 23 2106 9023 14 4107 1559 4 1939 7898 24 6881 3883 15 4506 3491 5 617 206 25 3895 2171 16 8191 4182 6 8544 1374 26 4062 6424 17 10192 6157 7 10676 3240 27 3755 9536 18 5668 3305 8 6672 9489 28 4683 2131 19 3449 1540 9 3170 7457 29 7347 8027 ETSI 124 ETSI EN 302 755 V1.1.1 (2009-09) Annex B (normative): Addresses of parity bit accumulators for Nldpc = 16 200 Table B.1: Rate 1/4 (Nldpc = 16 200) 6295 9626 304 7695 4839 4936 1660 144 11203 5567 6347 12557 10691 4988 3859 3734 3071 3494 7687 10313 5964 8069 8296 11090 10774 3613 5208 11177 7676 3549 8746 6583 7239 12265 2674 4292 11869 3708 5981 8718 4908 10650 6805 3334 2627 10461 9285 11120 7844 3079 10773 3385 10854 5747 1360 12010 12202 6189 4241 2343 9840 12726 4977 Table B.2: Rate 1/2 (Nldpc = 16 200) 20 712 2386 6354 4061 1062 5045 5158 5 5924 290 21 2543 5748 4822 2348 3089 6328 5876 6 1467 4049 22 926 5701 269 3693 2438 3190 3507 7 7820 2242 23 2802 4520 3577 5324 1091 4667 4449 8 4606 3080 24 5140 2003 1263 4742 6497 1185 6202 9 4633 7877 0 4046 6934 10 3884 6868 1 2855 66 11 8935 4996 2 6694 212 12 3028 764 3 3439 1158 13 5988 1057 4 3850 4422 14 7411 3450 Table B.3: Rate 3/5 (Nldpc = 16 200) 71 1478 1901 2240 2649 2725 3592 3708 3965 4080 5733 6198 2820 4109 5307 393 1384 1435 1878 2773 3182 3586 5465 6091 6110 6114 6327 2088 5834 5988 160 1149 1281 1526 1566 2129 2929 3095 3223 4250 4276 4612 3725 3945 4010 289 1446 1602 2421 3559 3796 5590 5750 5763 6168 6271 6340 1081 2780 3389 947 1227 2008 2020 2266 3365 3588 3867 4172 4250 4865 6290 659 2221 4822 3324 3704 4447 3033 6060 6160 1206 2565 3089 756 1489 2350 529 4027 5891 3350 3624 5470 141 1187 3206 357 1825 5242 1990 2972 5120 585 3372 6062 752 796 5976 561 1417 2348 1129 2377 4030 971 3719 5567 6077 6108 6231 1005 1675 2062 61 1053 1781 Table B.4: Rate 2/3 (Nldpc = 16 200) 0 2084 1613 1548 1286 1460 3196 4297 2481 3369 3451 4620 2622 1 2583 1180 1 122 1516 3448 2880 1407 1847 3799 3529 373 971 4358 3108 2 1542 509 2 259 3399 929 2650 864 3996 3833 107 5287 164 3125 2350 3 4418 1005 3 342 3529 4 5212 5117 4 4198 2147 5 2155 2922 5 1880 4836 6 347 2696 6 3864 4910 7 226 4296 7 243 1542 8 1560 487 8 3011 1436 9 3926 1640 9 2167 2512 10 149 2928 10 4606 1003 11 2364 563 11 2835 705 12 635 688 12 3426 2365 13 231 1684 13 3848 2474 14 1129 3894 14 1360 1743 0 163 2536 ETSI 125 ETSI EN 302 755 V1.1.1 (2009-09) Table B.5: Rate 3/4 (Nldpc = 16 200) 3 3198 478 4207 1481 1009 2616 1924 3437 554 683 1801 8 1015 1945 4 2681 2135 9 1948 412 5 3107 4027 10 995 2238 6 2637 3373 11 4141 1907 7 3830 3449 0 2480 3079 8 4129 2060 1 3021 1088 9 4184 2742 2 713 1379 10 3946 1070 3 997 3903 11 2239 984 4 2323 3361 0 1458 3031 5 1110 986 1 3003 1328 6 2532 142 2 1137 1716 7 1690 2405 3 132 3725 8 1298 1881 4 1817 638 9 615 174 5 1774 3447 10 1648 3112 6 3632 1257 11 1415 2808 7 542 3694 Table B.6: Rate 4/5 (Nldpc = 16 200) 5 896 1565 3 465 2552 6 2493 184 4 1038 2479 7 212 3210 5 1383 343 8 727 1339 6 94 236 9 3428 612 7 2619 121 0 2663 1947 8 1497 2774 1 230 2695 9 2116 1855 2 2025 2794 0 722 1584 3 3039 283 1 2767 1881 4 862 2889 2 2701 1610 5 376 2110 3 3283 1732 6 2034 2286 4 168 1099 7 951 2068 5 3074 243 8 3108 3542 6 3460 945 9 307 1421 7 2049 1746 0 2272 1197 8 566 1427 1 1800 3280 9 3545 1168 2 331 2308 Table B.7: Rate 5/6 (Nldpc = 16 200) 3 2409 499 1481 908 559 716 1270 333 2508 2264 1702 2805 6 497 2228 4 2447 1926 7 2326 1579 5 414 1224 0 2482 256 6 2114 842 1 1117 1261 7 212 573 2 1257 1658 0 2383 2112 3 1478 1225 1 2286 2348 4 2511 980 2 545 819 5 2320 2675 3 1264 143 6 435 1278 4 1701 2258 7 228 503 5 964 166 0 1885 2369 6 114 2413 1 57 483 7 2243 81 2 838 1050 0 1245 1581 3 1231 1990 1 775 169 4 1738 68 2 1696 1104 5 2392 951 3 1914 2831 6 163 645 4 532 1450 7 2644 1704 5 91 974 ETSI 126 ETSI EN 302 755 V1.1.1 (2009-09) Annex C (normative): Additional Mode Adaptation tools C.1 Input stream synchronizer Delays and packet jitter introduced by DVB-T2 modems may depend on the transmitted bit-rate and may change in time during bit and/or code rate switching. The "Input Stream Synchronizer" (see figure C.1) shall provide a mechanism to regenerate, in the receiver, the clock of the Transport Stream (or packetized Generic Stream) at the modulator Mode Adapter input, in order to guarantee end-to-end constant bit rates and delays (see also figure I.1, example receiver implementation). Table C.1 gives the details of the coding of the ISSY field generated by the input stream synchronizer. When ISSYI = 1 in MATYPE field (see clause 5.1.7) a counter shall be activated (22 bits), clocked by the modulator sampling rate (frequency Rs=1/T, where T is defined in clause 9.5). The Input Stream SYnchronization field (ISSY, 2 or 3 bytes) shall be transmitted according to clause 5.1.8. ISSY shall be coded according to table C.1, sending the following variables: • ISCR (short: 15 bits; long: 22 bits) (ISCR = Input Stream Time Reference), loaded with the LSBs of the counter content at the instant the relevant input packet is processed (at constant rate RIN), and specifically the instant the MSB of the relevant packet arrives at the modulator input stream interface. In case of continuous streams the content of the counter is loaded when the MSB of the Data Field is processed. • BUFS (2+10 bits) (BUFS = maximum size of the requested receiver buffer to compensate delay variations). This variable indicates the size of the receiver buffer assumed by the modulator for the relevant PLP. It shall have a maximum value of 2 Mbit. When a group of data PLPs share a common PLP, the sum of the buffer size for any data PLP in the group plus the buffer size for the common PLP shall not exceed 2 Mbit. • BUFSTAT (2+10 bits) This variable is retained for compatibility with DVB-S2 [i.3]. It need not be transmitted in DVB-T2 and may be ignored by a receiver. • TTO (7/15 bits mantissa + 5 bits exponent). This provides a mechanism to manage the de-jitter buffer in DVB-T2. The value of TTO is transmitted in a mantissa+exponent form and is calculated from the transmitted fields TTO_M, TTO_L and TTO_E by the formula: TTO=(TTO_M+TTO_L/256)×2TTO_E. If ISCRshort is used, TTO_L is not sent and shall equal zero in the above calculation. TTO defines the time, in units of T (see clause 9.5), between the beginning of the P1 symbol of the first T2- frame to which the Interleaving Frame carrying the relevant User Packet is mapped, and the time at which the MSB of the User Packet should be output, for a receiver implementing the model defined in clause C.1.1. This value may be used to set the receiver buffer status during reception start-up procedure, and to verify normal functioning in steady state. TTO shall be transmitted at least with the first transmitted UP of an Interleaving Frame for each PLP. The choice of the parameters of a DVB-T2 system and the use of TTO shall be such that, if a receiver obeys the TTO signalling and implements the model of buffer management defined in clause C.1.1, the receiver's de-jitter buffer and time de-interleaver memory shall neither overflow nor underflow. NOTE: Particular attention should be paid to the frame length, the PLP type, the number of sub-slices per frame, the number of TI-blocks per Interleaving Frame and number of T2-frames to which an Interleaving Frame is mapped, the scheduling of subslices within the frame, the peak bit-rate, and the frequency and duration of FEFs. ETSI 127 ETSI EN 302 755 V1.1.1 (2009-09) Input Stream Synchroniser Mod 222 Rs Counter S Y UP Packetised N C Input Stream 15 or 22 LSBs BUFSTAT BUFS ISCR TTO S Y UP I S N S CKIN C Y Input ISSY (2 or 3 bytes) Packets Insertion after Packet (optional) Figure C.1: Input stream synchronizer block diagram Table C.1: ISSY field coding (2 or 3 bytes) First Byte Second Byte Third Byte bit-7 (MSB) bit-6 bit-5 and bit-4 bit-3 and bit-2 bit-1 and bit-0 bit-7 to bit-0 bit-7 bit-0 0 = ISCRshort MSB of next 6 bits of ISCRshort next 8 bits of not present ISCRshort ISCRshort 1 0= 6 MSBs of ISCRlong next 8 bits of next 8 bits of ISCRlong ISCRlong ISCRlong 1 1 00 = BUFS BUFS unit 2 MSBs of BUFS next 8 bits of BUFS not present 00 = bits when ISCRshort 01 = Kbits is used; else 10 = Mbits reserved for 11 = 8Kbits future use 1 1 10 = BUFSTAT BUFSTAT unit 2 MSBs of BUFSTAT next 8 bits of not present 00 = bits BUFSTAT when ISCRshort 01 = Kbits is used; else 10 = Mbits reserved for 11 = BUFS/1 024 future use 1 1 01 = TTO 4 MSBs of TTO_E Bit 7:LSB of not present TTO_E when ISCRshort Bit 6-Bit0: TTO_M is used; else TTO_L 1 1 others = reserved reserved for Reserved for future Reserved for future not present for future use future use use use when ISCRshort is used; else reserved for future use ETSI 128 ETSI EN 302 755 V1.1.1 (2009-09) C.1.1 Receiver Buffer Model The following receiver buffer model, illustrated in figure C.2, shall be assumed. The receiver consists of an RF input, followed by a number of stages of demodulation including the FFT, channel ˆ equalization and frequency de-interleaving producing output cells xm,l , p representing estimates of the cells xm,l , p produced by the frame builder (see clause 8.3.2). The equalized cells from the frequency de-interleaver belonging to the selected PLP are then extracted and written into the time de-interleaver (TDI) memory. Cells are later read out of the time de-interleaver and fed to further processing stages including LDPC decoding and extraction of the user packets. Decoded bits are then written into a de-jitter buffer (DJB), which also provides an efficient way of recording the position of deleted null packets. Bits are read out from the buffer according to a read clock and the de-jitter buffer inserts deleted null packets at the output. When the receiver is decoding a data PLP together with its associated common PLP, it shall be assumed that the Time De-interleaver, other processing stages, and de-jitter buffer are duplicated as shown in figure C.2. NOTE: In this case, although separate time de-interleaving and de-jitter operations are applied to the data PLP and the common PLP, the total memory for the time de-interleaver and the total memory for the de-jitter buffer are shared between the data PLP and the common PLP. The following assumptions shall be made about the receiver: • The receiver will not be required to store the cells from more than two TI-blocks at any one time in its time de- interleaver memory (where the cells from one TI-block are being written into the memory and the cells from the previous TI-block are being read out). • ˆ The demodulation stages have no delay, and the cells xm,l , p carried in a particular OFDM symbol 'l' are output from the frequency de-interleaver at a uniform rate and in order of the cell index p during the time (Ts) that the OFDM symbol is being received. • The cells at the output of the demodulation stages belonging to a particular PLP are written immediately into the TDI memory. • As soon as all the cells of a TI-block have been written to the TDI memory, the TDI will start to read and output the de-interleaved cells of that block. • The TDI will read out cells at a rate of 7,6×106 cells/s, as long as cells remain from the TI-block being read, and unless doing so would cause the de-jitter buffer to overflow. • If this maximum rate of reading would cause the de-jitter buffer to overflow, the TDI will read out cells as fast as possible without causing the DJB to overflow. • The de-jitter buffer will initially discard all input bits until it receives a bit for which a value of TTO is indicated. • Subsequent input bits will be written to the de-jitter buffer. • Any deleted null packets output from the decoding stages will conceptually be stored in the de-jitter buffer, but will not occupy any memory space. • No bits will be output until the time indicated by the value of TTO for the first bit written. • The bits will then be read and output from the de-jitter buffer at a constant rate calculated from the received ISCR values, using a read clock generated from a recovered clock perfectly synchronized to the modulator's sampling rate clock. • The size of the de-jitter buffer is 2Mbit. When a group of data PLPs share a common PLP, the sum of the buffer size for any one data PLP in the group plus the buffer size for the common PLP shall not exceed 2 Mbit. • The size of the TDI memory is 219+215 OFDM cells. When a group of data PLPs share a common PLP, the sum of the memory size for time de-interleaving any one data PLP and the memory size for time de-interleaving the common PLP shall not exceed 219+215 OFDM cells - see clause 6.5.2). ETSI 129 ETSI EN 302 755 V1.1.1 (2009-09) RF De- Time Other De-jitter Output input modulation de-Interleaver processing buffer stream (TDI) (DJB) (Data PLP) Time Other De-jitter Output de-Interleaver processing buffer stream (TDI) (DJB) (Common PLP) Figure C.2: receiver buffer model The following features of a real receiver need not be taken into account by the modulator and should be considered by receiver implementers when interpreting the TTO values and choosing the exact size of the memory to allocate to the de-jitter buffer: • Additional delays incurred in the various processing stages for practical reasons. • Error in the regenerated output read-clock frequency and phase. • Adjustments made to the read-clock frequency and phase in order to track successive ISCR and TTO values. A possible mechanism for doing this is outlined in annex I. • The limited precision of the TTO signalling. An example receiver scheme to regenerate the output packet stream and the relevant clock R'IN is given in figure I.1. ETSI 130 ETSI EN 302 755 V1.1.1 (2009-09) Annex D (normative): Splitting of input MPEG-2 TSs into the data PLPs and common PLP of a group of PLPs D.1 Overview This annex defines an extension of the DVB-T2 system in the case of MPEG-2 Transport Streams [i.1], which allows the separation of data to be carried in the common PLP for a group of TSs. It includes the processing (demultiplexing) that shall be applied for transporting N (N 2) MPEG-2 TSs (TS_1 to TS_N) over N+1 data PLPs (PLP1 to PLPN)), one ≥ of which is the common PLP (CPLP) of a group of PLPs, see figure D.1. If this processing is not applied to a group of Transport Streams, there shall be no common PLP for this group, and each PLP of the group shall carry the input TS without modification. When several groups of PLPs are used to carry TSs, each such group has its own independent extension functionality. This annex also describes the processing that can be carried out by the receiver to reconstruct a single input TS from the received data PLP and its corresponding common PLP. 1_ST )1PLP( 1SPST )1PLP( 1SPST 1_ST 2_ST )2PLP( 2SPST DVB-T2 )2PLP( 2SPST 2_ST 2_ST Physical llamroN amroN Layer GEPM GEPM xumeR xumeR xuM xuM xumed xumed & & gnidulcni( redoceD redoceD tekcap LLUN tekcap LLUN N_ST N_ST )NPLP( NSPST )NPLP( NSPST /lavomer )NPLP( NSPST )NPLP( NSPST N_ST N_ST )noiitresnii )no tresn )PLPC( CSPST )PLPC( CSPST )PLPC( CSPST )PLPC( CSPST gn ssecorp krowteN gniissecorp krowteN gn ssecorp rev eceR gniissecorp reviieceR no snetxe ht w LP 2T-BVD noiisnetxe htiiw LP 2T-BVD Figure D.1: Multiple TS input/output to/from the extended DVB-T2 PL The extension consists on the network side conceptually of a remultiplexer and on the receiver side of a multiplexer. In-between the remultiplexer and the multiplexer we have the DVB-T2 system, as described in other parts of the present document. The inputs/outputs to the DVB-T2 system are syntactically correct TSs, each with unique transport_stream_ids, containing all relevant layer 2 (L2) signalling information (i.e. PSI/SI - see [i.1] and [i.4]). The various input TSs may have PSI/SI tables, or other L2 data, in common with other input TSs. When the extension is used the generated TSPS (Transport Stream Partial Stream) and TSPSC (Transport Stream Partial Stream Common) streams are however typically not syntactically correct MPEG-2 TSs. NOTE: The parallel TSs may only exist internally in equipment generating the DVB-T2 signal. The parallel TSs may e.g. be generated from a single high bit rate TS source, or may alternatively be generated by centrally-controlled parallel encoders, each producing a constant bit rate TS, with variable proportion of null packets. The bit rates of the input TSs may be significantly higher than the capacity of the respective PLPs, because of the existence of a certain proportion of null packets, which are removed by the DNP procedure. ETSI 131 ETSI EN 302 755 V1.1.1 (2009-09) An input MPEG-2 TS shall be transported either: • in its entirety within a single PLP, in which case the TS does not belong to any group of PLPs (and there is no common PLP); or • split into a TSPS stream, carried in a data PLP, and a TSPSC stream, carried in the common PLP. This annex specifies the splitting and describes how the recombination of the output streams from a data PLP and a common PLP can conceptually be achieved by the receiver to form the output TS. D.2 Splitting of input TS into a TSPS stream and a TSPSC stream D.2.1 General When a set of N TSs (TS_1, …, TS_N, N 2) are sent through a group of N+1 PLPs, one being the common PLP of a ≥ group, all TSs shall have the same input bit rate, including null packets. All input TS streams shall also be packet-wise time synchronized. All TSPSs and the TSPSC shall have the same bit rate as the input TSs and maintain the same time synchronization. For the purpose of describing the split operation this is assumed to be instantaneous so that TSPSs and the TSPSC are still co-timed with input TSs after the split. NOTE: The input TSs may contain a certain proportion of null packets. The split operation will introduce further null packets into the TSPSs and the TSPSC. Null packets will however be removed in the modulator and reinserted in the demodulator in a transparent way, so that the DVB-T2 system will be transparent for the TSPSs and the TSPSC, despite null packets not being transmitted. Furthermore, the DNP and ISSY mechanism of the DVB-T2 system will ensure that time synchronization of the TSPSs and the TSPSC at the output of the demodulator is maintained. When reference is made to TS packets carrying SDT or EIT in the current Annex the intended meaning is TS packets carrying sections carrying SDT or EIT, i.e. the data being carried within the TS packet is not limited to the SDT or EIT itself but includes the full section (i.e. with CRC). For the purpose of specifying the split operation the TS packets that may be transmitted in the common PLP fall into the following three categories: 1) TS packets carrying any other type of data than Service Description Table (SDT) or Event Information Table (EIT), i.e. with PID values not equal to 0x0011 or 0x0012. 2) TS packets carrying Service Description Table (SDT), i.e. with PID value of 0x0011. 3) TS packets carrying Event Information Table (EIT), i.e. with PID value of 0x0012. For reference to SDT and EIT see [i.4]. Figures D.2 to D.6 are simplified insofar as they do not show any data packets or null packets in the input TSs. In real input TSs these are of course to be expected. The absence of these packets in the figures does however not in any way affect the general applicability of the splitting/re-combining process, as described in this annex. ETSI 132 ETSI EN 302 755 V1.1.1 (2009-09) D.2.2 TS packets carrying any other type of content than Service Description Table (SDT) or Event Information Table (EIT), i.e. with PID values not equal to 0x0011 or 0x0012 TS packets that are co-timed and identical on all input TSs of the group before the split may, after the split, appear at the same time positions in the TSPSC and, if so, shall be replaced by null packets in the respective TSPS at the same time positions. The receiver can recreate the input TS when any packets other than null packets, or packets carrying SDT or EIT, appear in the TSPSC, by replacing null packets in the currently received TSPS with the corresponding TS packets in the TSPSC at the same time positions, see figure D.2. CSPST CSPST CSPST TIN TIN TIN 3 atad nommoC 2 atad nommoC 3 atad nommoC 2 atad nommoC 3 atad nommoC 2 atad nommoC … … … M atad nommoC M atad nommoC M atad nommoC )PLP nommoc( 3_SPST tekcap lluN tekcap lluN tekcap lluN tekcap lluN tekcap lluN )PLP atad( )PLP atad( )PLP atad( lluN lluN lluN lluN lluN lluN lluN lluN tekcap tekcap tekcap tekcap tekcap tekcap tekcap .lper .lper .lper .lper .lper 3_ST tuptuO TIN 3 atad nommoC 2 atad nommoC … M atad nommoC Figure D.2: Example of recombination of input TS from TSPS and TSPSC for category 1 D.2.3 TS packets carrying Service Description Table (SDT), i.e. with PID=0x0011 Sections with table_id=0x42 (HEX) are referred to as SDT actual TS. Sections with table_id=0x46 (HEX) are referred to as SDT other TS. TS packets with PID=0x0011 and table_id of all carried sections equal to 0x46 (HEX), may be carried in the TSPSC provided the following conditions are fulfilled: 1) At a given time position there is in one input TS a TS packet which is not a null packet. 2) In all the other input TSs of the group there are, at this time position, mutually identical TS packets, not equal to that in condition (1), with PID=0x0011, with the section header table_id field of all carried section headers equal to 0x46 and with the value of the transport_stream_id field in all carried sections equal to the transport_stream_id of the TS in condition (1). 3) Sections with table_id 0x42 and 0x46 are never partly or fully carried in the same TS packet with PID=0x0011. If these conditions are met, the input TS packets carrying the SDT actual shall not be modified, but copied directly to the corresponding TSPS at the same time position. The input TS packets carrying SDT other may be replaced by null packets in the corresponding TSPS, in which case the TS packets carrying SDT other shall be carried in the TSPSC, as shown in figure D.3. ETSI 133 ETSI EN 302 755 V1.1.1 (2009-09) ”nmuloc 3 ST“ 1_ST tekcap llun oN rehto TDS rehto TDS … rehto TDS 2_ST rehto TDS tekcap llun oN rehto TDS … rehto TDS 3_ST rehto TDS rehto TDS tekcap llun oN … rehto TDS N_ST rehto TDS rehto TDS rehto TDS … tekcap llun oN ni dettimsnarT CSPST rehto TDS rehto TDS rehto TDS … rehto TDS )PLP nommoC( Figure D.3: Arrangement of SDT other in input TSs and relationship with TSPSC As a result of the split all TS packets carrying SDT actual are therefore left unmodified in the respective TSPS at the same time position as in the input TS, whereas all TS packets carrying SDT other are found in the TSPSC at the same time position as in the input TS. The receiver can recreate the input TS when SDT other packets appear in the TSPSC, by replacing null packets in the currently received TSPS with the corresponding SDT other packets from the TSPSC at the same time positions. When there is not a co-timed null packet in the TSPS, the receiver shall not modify the TSPS to achieve full transparency. This is shown in figure D.4. )3ST( rehto TDS )2ST( rehto TDS )1ST( rehto TDS )PLPCnomT oc( SPS )PLP nommoc( m … )NST( rehto TDS 3_SPST tekcap lluN tekcap lluN tekcap llun oN tekcap lluN tekcap lluN )PLP atad( )PLP atad( ll u N ll u N lluN lluN oN oN lluN lluN lluN tekcap tekcap tek cap tek cap tekcap tek cap tekcap .lper .lper .lper .lper .lper .lper tekcap un oN )2ST( rehto TDS )1ST( rehto TDS 3_ST tuptuO tekcap llllllun oN )2ST( rehto TDS )1ST( rehto TDS 3_ST tuptuO tekcap un oN )2ST( rehto TDS )1ST( rehto TDS … … … )NST( rehto TDS )NST( rehto TDS )NST( rehto TDS Figure D.4: Receiver operation to re-combine of TSPS and TSPSC into output TS for SDT D.2.4 TS packets carrying Event Information Table (EIT), i.e. with PID=0x0012 • Sections with table_id=0x4E (HEX) are referred to as EIT actual TS, present/following. • Sections with table_id=0x4F (HEX) are referred to as EIT other TS, present/following. • Sections with table_id=0x50 to 0x5F (HEX) are referred to as EIT actual TS, schedule. ETSI 134 ETSI EN 302 755 V1.1.1 (2009-09) • Sections with table_id=0x60 to 0x6F (HEX) are referred to as EIT other TS, schedule. The operations described in clause D.2.4.1 may be performed when the conditions described in clause D.2.4.2 are fulfilled. D.2.4.1 Required operations At a particular time position a TS packet carrying EIT other may be copied into the same time position in the TSPSC. If this is done, the input TS packets of all TSPSs of the group at the same time position shall be replaced by a null packets and the same operation shall apply for all other time positions where input TSs of the group carry EIT actual or other. D.2.4.2 Conditions In all input TSs of the group except one there shall, at this time position, be identical TS packets carrying EIT other, with value of the section header transport_stream_id field equal to the transport_stream_id of the remaining input TS. At the same time position there shall be, in the remaining input TS, a TS packet carrying EIT actual, with the value of the section header transport_stream_id field equal to the transport_stream_id of the same input TS. At this time position, the TS packet carrying EIT actual shall be identical to those carrying EIT other, except for the table_id of the carried section and the CRC. The table_ids of co-timed TS packets carrying EIT actual and EIT other shall have the 1-to-1 mapping given in table D.1. Sections with table_id 0x42 and 0x46, or with different transport_stream_id, shall never partly or fully be carried in the same TS packet with PID=0x0012, i.e. a particular TS packet shall always carry either EIT actual or EIT other data referring to a single TS of the group. Table D.1: Correspondence between table_ids of co-timed EIT actual and EIT other in input TSs table_id of EIT actual in input TS table_id of co-timed EIT other in input TS 0x4E 0x4F 0x50 0x60 0x51 0x61 0x52 0x62 0x53 0x63 0x54 0x64 0x55 0x65 0x56 0x66 0x57 0x67 0x58 0x68 0x59 0x69 0x5A 0x6A 0x5B 0x6B 0x5C 0x6C 0x5D 0x6D 0x5E 0x6E 0x5F 0x6F This means that at a particular time position with TS packets carrying EIT all these TSs carry identical TS packets with the exception of section table_id in one TS being set to "actual" rather than "other" and the CRC of the corresponding sections being different for EIT actual and other, see table D.1 and figure D.5. ETSI 135 ETSI EN 302 755 V1.1.1 (2009-09) ”nmuloc 3ST“ 1_ST lautca TIE rehto TIE rehto TIE … rehto TIE 2_ST rehto TIE lautca TIE rehto TIE … rehto TIE 3_ST rehto TIE rehto TIE lautca TIE … rehto TIE N_ST rehto TIE rehto TIE rehto TIE … lautca TIE ni dettimsnarT CSPST rehto TIE rehto TIE rehto TIE … rehto TIE Figure D.5: Example of arrangement of EIT actual/other in input TSs and relationship with TSPSC As a result of the split all TS packets carrying EIT actual and EIT other are replaced by null packets in the respective TSPS at the same time position. All TS packets carrying a section or sections with EIT other in the input TSs are copied to the TSPSC at the same time position as in the input TS. The receiver can recreate the input TS when EIT other packets appear in the TSPSC, by replacing null packets in the currently received TSPS with the corresponding EIT other packets from the TSPSC at the same time positions. For TS packets carrying EIT other, with the value of the section header transport_stream_id field equal to the transport_stream_id of the currently decoded TS, the receiver should also modify the table_id from "other" to "actual" and modify the CRC to achieve full TS transparency, see table D.1 and figure D.6. )3ST( rehto TIE )2ST( rehto TIE )1ST( rehto TIE )PLPCnomT oc( SPS )PLP nommoc( m … )NST( rehto TIE 3_SPST 3_SPST tekcap LLUN tekcap LLUN tekcap LLUN tekcap LLUN tekcap LLUN tekcap LLUN tekcap LLUN tekcap LLUN tekcap LLUN tekcap LLUN )PLP atad( )PLP atad( LL UN tekcap LL UN LL UN .lper LL UN LL UN LL UN tekcap tekcap + + tekcap tekcap .lper .lper fo egnahc .lper .lper .lper C RC & di_elba t )3ST( autca TIE )2ST( rehto TIE )1ST( rehto TIE 3_ST tuptuO )3ST( lllautca TIE )2ST( rehto TIE )1ST( rehto TIE 3_ST tuptuO )3ST( autca TIE )2ST( rehto TIE )1ST( rehto TIE … … … )NST( rehto TIE )NST( rehto TIE )NST( rehto TIE Figure D.6: Receiver operation to re-combine of TSPS and TSPSC into output TS for EIT NOTE: For TS packets carrying scrambled EIT schedule it may be difficult to perform the above-mentioned modification of table_id from "other" to "actual" and change of CRC. Therefore, in such cases the output TS may contain only EIT other. The information of the EIT actual of the input TS, referring to the currently decoded TS, is however available in the EIT other, referring to the same TS. ETSI 136 ETSI EN 302 755 V1.1.1 (2009-09) D.3 Receiver Implementation Considerations In view of the key role played by the transport stream as a physical interface in many existing and future receivers it is strongly recommended that at least the core of the merging function as described in this annex is implemented in a channel decoder silicon. In particular this applies to the generic merging function between TSPSC and TSPS to form a transport stream: • for category-1 (generic data) as defined in clause D.2.2 illustrated in figure D.2; • for category-2 (SDT) as defined in clause D.2.3 and illustrated in figure D.4, and • for category-3 (EIT) as defined in clause D.2.4 and illustrated in figure D.6. It may be possible that the change of table_id and CRC, as defined for category-3 data (to reconstruct EIT_actual from EIT_other) could be handled by software on an MPEG system processor (which avoids that channel decoders would have to implement section level processing). The channel decoder implementations as defined above should ensure correct integration of many existing DVB system hardware and software solutions for DVB with such channel decoders. ETSI 137 ETSI EN 302 755 V1.1.1 (2009-09) Annex E (informative): T2-frame structure for Time-Frequency Slicing E.1 General Time-Frequency-Slicing (TFS) is a method where the sub-slices of a PLP are sent over multiple RF frequencies during the T2-frame. Interleaving is thus applied both over time and frequency. Although the present document describes a single profile which does not include TFS, this annex describes those features which would allow a future implementation of TFS, assuming that a receiver has two tuners/front-ends. Receivers with one tuner are not expected to be TFS compatible. It is not required that receivers implement the contents of this annex. The present document includes all elements needed to support the use of TFS. In addition to what is required for single RF-frequency emission, this includes mainly signalling and associated frame structure for Time-Frequency slicing. Thus a full TFS system can be built based on the normative parts of the present document. To fully support TFS, it is expected that a receiver will have to have two tuners to receive a single service. This annex gives the formal rules for building the T2-frame when TFS is used. The basic block diagrams given in figure 2 broadly apply when TFS is used, but the frame builder and OFDM generation modules are modified to include additional chains so that there is one branch for each of the NRF RF channels of the TFS system, as shown in figure E.1. Assembly of PLP0 common PLP cells Cell Mapper (assembles To OFDM PLP1 modulated cells of Sub-slice generation PLPs and L1 processor Frequency signalling into interleaver Channel 1 arrays corresponding to Assembly of OFDM symbols. data PLP Operates cells according to PLPn dynamic scheduling Frequency information interleaver produced by Channel NRF scheduler) compensating Assembly of delay L1 cells L1 Signalling Compensates for frame delay in input module and delay in time interleaver Figure E.1(a): Frame builder for TFS ETSI 138 ETSI EN 302 755 V1.1.1 (2009-09) Pilot insertion & Guard P1 Channel 1, Tx1 MISO IFFT PAPR DAC processing dummy tone reduction interval Symbol reservation insertion insertion Channel 1, Tx2 (optional) To transmitter(s) Pilot insertion & Guard P1 Channel NRF, Tx1 MISO IFFT PAPR DAC processing dummy tone reduction interval Symbol reservation insertion insertion Channel NRF, Tx2 (optional) Figure E.1(b): OFDM generation for TFS NOTE: The maximum bit rates mentioned in clause 4.1 also apply in the case of TFS. E.2 T2-frame structure E.2.1 Duration and capacity of the T2-frame The duration of the T2-frame using Time-Frequency slicing (TFS) is calculated with the same formula as with one RF channel: TF = (NP2+Ldata)×Ts+TP1, where NP2 is the number of P2 symbols on one RF channel and Ldata is the number of data symbols on one RF channel. The rules for the frame length defined in clause 8.3.1 apply. Also, the number of P2 symbols NP2 is calculated as defined in table 45. The number of active OFDM carriers in one T2-frame for all RF channels is given by: ⎧( N × C P 2 + ( Ldata − 1) × Cdata + C LS ) × N RF when there is a frame closing symbol Ctot = ⎨ P 2 ⎩ ( N P 2 × C P 2 + Ldata × Cdata ) × N RF otherwise E.2.2 Overall structure of the T2-frame When using TFS the T2-frame has a similar structure as with one RF channel, except that the sub-slices of type 2 data PLPs are distributed over all RF channels during one T2-frame. P1 symbols, L1 signalling and common PLPs are repeated simultaneously on each RF channel, as these should always be available while receiving any type 2 data PLP. Each type 1 data PLP only occurs on one RF channel in one T2-frame but different type 1 data PLPs are transmitted on different RF channels. The RF channel for a type 1 PLP may change from frame to frame (inter-frame TFS) or may be the same in every frame (Fixed Frequency) according to the L1 configurable signalling parameter FF_FLAG. The structure of the T2-frame with TFS is depicted in figure E.2. The number of OFDM cells needed to carry all common PLPs in one T2-frame on one RF channel is denoted by Dcommon. The number of OFDM cells needed to carry all L1 signalling in one T2-frame on one RF channel is denoted by DL1. The number of OFDM cells available for transmission of data PLPs in one T2-frame for all RF channels is given by: Ddata = Ctot − Dcommon × N RF − DL1 × N RF . ETSI 139 ETSI EN 302 755 V1.1.1 (2009-09) Figure E.2: Structure of the T2-frame in a TFS system In a TFS system a T2-frame will start at the same point in time on all RF channels, i.e. in all transmitters. This means that the P1 symbols occur at the same point in time on all RF channels, followed by the P2 symbol(s) and data symbols. The L1-pre and L1-post signalling will be generated, coded and mapped to each channel individually as for the single RF case. The L1-pre signalling will be different on each channel because the CURRENT_RF_IDX and consequently the CRC-32 will both be different. The L1-post signalling will be identical on each RF channel. The addressing scheme for the data cells will be applied to each RF channel individually exactly as for the single RF case. E.2.3 Structure of the Type-2 part of the T2-frame The type 2 data PLPs will be carried in a total of Nsubslices_total sub-slices across all RF channels; Nsubslices_total is signalled by the configurable L1 signalling parameter NUM_SUB_SLICES. The structure of the TF-sliced part (type 2 data PLPs) of a T2-frame is depicted in figure E.3. The sub-slices of type 2 data PLPs are shifted in relation to each other on the different RF channels to enable jumping between the RF channels during a T2-frame. If a sub-slice is divided on one RF channel, as in the case of PLP2 on RF3 and PLP4 on RF2, this is still considered to be the same sub-slice for the definition of Nsubslices_total. For example, Nsubslices_total = 6 in figure E.3. The beginning of the area for type 2 PLPs will be the same OFDM cell address, denoted by A2, on each RF channel. ETSI 140 ETSI EN 302 755 V1.1.1 (2009-09) Figure E.3(a): The structure of the type 2 part of a T2-frame with NRF = 3 and Nsubslices_total = 6 before folding, showing the sub-slices exceeding the frame Figure E.3(b): The structure of the type 2 part after folding of the sub-slices E.2.4 Restrictions on frame structure to allow tuner switching time When using Time-Frequency Slicing (TFS) there are more restrictions to frame length to enable enough time for switching between the RF channels. The restrictions apply when the number of RF channels (NRF) is greater than the number of tuners in the receiver. In practical applications the number of tuners is two.. When using two tuners in the receiver, TFS with two RF channels does not require additional limitations to the one RF configuration, as it is not necessary to perform frequency hopping. When NRF > 2 the following restrictions for the T2-frame structure apply: • The time between two sub-slices to be received with the same tuner should be guaranteed, both between sub-slices and at the frame edge. • The minimum frequency hopping time between sub-slices on different RF channels for a tuner is 2 * S CHE + ⎡S tuning ⎤ , where SCHE is the number of symbols needed for channel estimation and ⎡Stuning ⎤ is the number of symbols needed for tuning rounded up to the nearest integer (figure E.4). • The minimum tuning time is 5 ms, so that Stuning×TS≥5ms. The values for ⎡Stuning ⎤ are presented in table E.1. • The value for SCHE is dependent on the used pilot pattern. SCHE = DY - 1, where DY is the number of symbols forming one scattered pilot sequence defined in table 51. ETSI 141 ETSI EN 302 755 V1.1.1 (2009-09) Figure E.4: Minimum required frequency hopping time between two sub-slices to be received with the same tuner Table E.1: Values for ⎡Stuning ⎤ (number of symbols needed for tuning, rounded up, for 8 MHz bandwidth), when minimum tuning time = 5 ms Guard interval FFT size Tu [ms] 1/128 1/32 1/16 19/256 1/8 19/128 1/4 32K 3,584 2 2 2 2 2 2 NA 16K 1,792 3 3 3 3 3 3 3 8K 0,896 6 6 6 6 5 5 5 4K 0,448 NA 11 11 NA 10 NA 9 2K 0,224 NA 22 22 NA 20 NA 18 1K 0,112 NA NA 10 NA 9 NA 8 E.2.5 Signalling of the dynamic parameters in a TFS configuration In a TFS system the L1-post dynamic signalling transmitted in P2 will refer to the next T2-frame and the in-band signalling for the current PLP will refer to the next-but-one Interleaving Frame, as depicted in figure E.5 and described in detail in clauses 7.2.3 and 5.2.3 respectively. Figure E.5: L1 signalling for a TFS system E.2.6 Indexing of RF channels Each RF channel in a T2 system is allocated an index between 0 and NUM_RF-1. The indexing of the RF channels is signalled in the CURRENT_RF_IDX parameter in the L1-pre signalling (for the current frequency) and the RF_IDX parameter in the configurable part of the L1-post signalling (in the loop for all NRF channels) as described in clauses 7.2.2 and 7.2.3.1 respectively. In TFS mode, the index indicates the order of each frequency within the TFS configuration. The 'next' RF channel will be the one whose index is one greater than the current channel; the 'next' channel after the RF channel whose index is NUM_RF - 1 will be the RF channel with RF_IDX = 0. ETSI 142 ETSI EN 302 755 V1.1.1 (2009-09) The RF indexing scheme is used for the configurable and PLP-specific parameter FIRST_RF_IDX for the type 1 data PLPs. This parameter indicates on which RF channel the PLP occurs in the first T2-frame of the super-frame to which that PLP is mapped; see clause E.2.7.1. The indexing of the RF channels is also used in the signalling for the type 2 PLPs. The RF channel whose index is equal to the dynamic L1 parameter START_RF_IDX is designated as RFstart, and is the RF channel on which the first subslice for each PLP starts at the address given by the PLP_START parameter. The subslices on the RF channel with the next index are shifted by 1×RF_SHIFT, the next by 2×RF_SHIFT, etc. as described in clause E.2.7.2.3. E.2.7 Mapping the PLPs The allocation of sub-slices to the T2-frame is done by the scheduler as in the single-RF case. The scheduler may use any method to perform the allocation and may map the PLPs to the T2-frame in any order, provided: • that the locations of the cells of the PLPs are as described by the L1 signalling, interpreted as described in the following clauses, and also; • that the requirements for tuner switching time described in clause E.2.4 are met. E.2.7.1 Mapping the Common and Type 1 PLPs For the common and type 1 PLPs, the address range of the cells for each PLP in a given T2-frame will be signalled exactly as for the single RF case. Each of the cells of a common PLP will be carried on all of the RF channels and will be mapped to the same cell address in each channel. Each of the Type 1 PLPs will be mapped to only one RF channel in a given T2-frame. For Type 1 PLPs which are Fixed Frequency (FF_FLAG='1'), the RF channel to which the PLP is mapped will be signalled directly by the L1 signalling parameter FIRST_RF_IDX. For Type 1 PLPs which are not Fixed-Frequency (FF_FLAG='0'), the index of the RF channel on which each Type 1 PLP appears in a given frame is denoted by PLP_channel and can be determined by: ⎛ FRAME _ IDX − FIRST _ FRAME _ IDX ⎞ PLP _ channel = ⎜ ⎜ + FIRST _ RF _ IDX ⎟ mod N RF , ⎟ ⎝ FRAME _ INTERVAL ⎠ where FRAME_IDX, FIRST_FRAME_IDX, FRAME_INTERVAL and FIRST_RF_IDX are the corresponding L1-signalling parameters. E.2.7.2 Mapping the Type 2 PLPs Type 2 data PLPs will be mapped starting from the cell address immediately following the last address allocated to Type 1 PLPs. The Type 2 PLPs start from the same active cell address in every RF. The Type 1 PLPs should therefore be allocated such that they all end at the same address in every RF. E.2.7.2.1 Allocating the cells of the Interleaving Frame to the T2-Frames The scheduler allocates an integer number of LDPC blocks NBLOCKS_IF(i,n) to each Interleaving Frame n, for each PLP i. The number of LDPC blocks allocated is used to inform the frame builder of the size of the sub-slices required within each T2-frame. The slice size Di,2, i.e. the number of OFDM cells required for Type-2 PLP i in each T2-frame to which the Interleaving Frame is mapped, is calculated as: N BLOCKS _ IF (i, n) × N LDPC (i ) Di , 2 = , PI (i ) × η MOD (i ) ETSI 143 ETSI EN 302 755 V1.1.1 (2009-09) where NBLOCKS_IF(i,n) is the number of LDPC blocks NBLOCKS_IF(n) in the current Interleaving Frame (index n) for PLP i; Nldpc(i) is the LDPC block length and MOD(i) is the number of bits per cell for PLP i. PI(i) is the number of T2- η frames to which the Interleaving Frame is mapped, and NBLOCKS_IF(n) was defined in clause 6.5 for the Time Interleaver. As for the single RF case, the value of PI will be chosen such that Di is an integer for all PLPs, and also that PI and Nsubslices_total meet the additional constraints given in clause E.2.7.2.2. EXAMPLE: Figure E.6 depicts the OFDM cells for data PLPs of a T2-frame. In this example, there are five type 2 data PLPs carried in the frame. The restrictions for capacity allocation for type 2 data PLPs are dependent on Ddata (the total number of data cells available in the T2-frame), the number of data cells used by type 1 data PLPs, the number of data PLPs carried in the T2-frame, and the number of sub-slices Nsubslices_total. The sum of all cells of all type 1 and type 2 data PLPs cannot exceed the number of cells reserved for data PLPs: M1 M2 ∑ i =1 Di,1 + ∑D i =1 i,2 ≤ Ddata , where Di,1 is the size of type 1 data PLP i in OFDM cells. fo noiger 2-epyT emarf-2T 1 2 3 4 5 Figure E.6: Capacity allocation of five type 2 data PLPs to one T2-frame E.2.7.2.2 Size of the sub-slices The size of each sub-slice is given by Di,2/ Nsubslices_total, where Di,2 is the total number of data cells mapped to the current T2-frame for type 2 data PLP i. Nsubslices_total is the same for all type 2 data PLPs and it is given by: Nsubslices_total = NRF Nsubslices, where NRF is the number of RF channels and Nsubslices is the number of sub-slices per RF channel. Figure E.3 shows an example of sub-slicing for NRF = 3 and Nsubslices = 2. NOTE 1: Because sub-slices can be divided between the beginning and end of the frame as a result of the cyclic rotation, the allocation of data cells to the sub-slices is not as straightforward as in the single-RF case and occurs as a result of the mapping described in clause E.2.7.2.5. ETSI 144 ETSI EN 302 755 V1.1.1 (2009-09) The value of Nsubslices_total should be chosen such that: (Ncells) mod (5 PI(i)×Nsubslices_total) = 0, for all i. Suitable values for Nsubslices_total are listed in annex K for the case where PI=1. The value of Nsubslices_total is signalled in L1-post signalling field SUB_SLICES_PER_FRAME. NOTE 2: The number of OFDM cells for each PLP, Di,2, may be different but every Di,2 will be a multiple of Nsubslices_total, so that all sub-slices carrying the same PLP have equal size. This is guaranteed provided the above requirement, which is more restrictive, is met. The cell addresses to which each Type 2 PLP is mapped should be determined as follows. E.2.7.2.3 Allocation of cell addresses to the sub-slices on RFstart The dynamic L1 signalling parameter PLP_START indicates the address of the first cell of the first sub-slice in RFstart. RFstart is the RF channel whose index CURRENT_RF_IDX is equal to the dynamic L1 signalling parameter START_RF_IDX, and is the channel on which the sub-slices are not shifted or folded. The RF channel that is referred to as RFstart may change between T2-frames. The locations of the other sub-slices of each PLP are calculated in the receiver based on the first sub-slice of RFstart. If there is more than one sub-slice per RF channel per T2-frame, then the addresses of the first cells of the successive sub-slices on RFstart should be spaced by SUB_SLICE_INTERVAL as for the single RF case. The cells of each sub-slice of each PLP will be mapped one after the other into the T2-frame on RFstart as described in clause 8.3.6.3.2 for the single RF case. DType 2 NOTE: With the mapping described, SUB_SLICE_INTERVAL will be equal to , where N subslices _ total M2 DType 2 = ∑ Di , 2 is the number of OFDM cells on all RF channels carrying type 2 PLPs; and i =1 Nsubslices_total is the number of sub-slices per T2-frame across all RF channels. A receiver cannot assume that SUB_SLICE_INTERVAL can be calculated as described in the note above, but instead should use the signalled value (see clause 7.2.3.2). The address of the first and last cell for the sub-slice j on RFstart of a type 2 data PLP are therefore given by: Sub_slice_start(j) = PLP_START + j × SUB_SLICE_INTERVAL PLP_NUM_BLOCKS × N cells Sub_slice_end(j) = Sub_slice_start(j) + −1. N subslices_total × PI for j=0, 1, …, Nsubslices-1. Here Nsubslices_total = SUB_SLICES_PER_FRAME and Ncells is the number of OFDM cells in an LDPC block as given in table 16 and PI is the number of T2-frames to which an Interleaving Frame is mapped. PLP_START, SUB_SLICE_INTERVAL, and PLP_NUM_BLOCKS are the L1 signalling parameters defined in clause 7.2.3.2. The sub-slice allocation consists of all of the cells in this range. E.2.7.2.4 Allocation of cell addresses to the sub-slices on the other RF channels The sub-slice allocations on each of the other RF channels are shifted by RF_shift cells with respect to the corresponding allocations on the previous RF channel. The shift is performed cyclically, i.e. addresses exceeding the range of (Dtype2/NRF) addresses allocated to the Type 2 PLPs will be "folded back" to the beginning of the Type 2 region. ETSI 145 ETSI EN 302 755 V1.1.1 (2009-09) RF_shift is not signalled directly but can be determined by: SUB _ SLICE _ INTERVAL RF _ shift = , N RF where SUB_SLICE_INTERVAL is the L1-signalling parameter. Therefore, for each address A0 allocated to a particular PLP on RFstart, the corresponding address An should be allocated to the same PLP on the RF channel whose index is [(START_RF_IDX+n) mod NRF], for each n, 0 < n < NRF, where: An=ASTART2+[(A0-ASTART2+n×RF_shift) mod Dtype2/NRF], and ASTART2 is the address of the start of the Type 2 region. The value of Dtype2 itself is equal to NUM_RF ×SUB_SLICE_INTERVAL. The value of ASTART2 is signalled by the dynamic L1 signalling parameter TYPE_2_START. Figure E.7 illustrates the sub-slice locations before the folding has been applied, and figure E.8 illustrates the allocations after the folding. For simplicity, START_RF_IDX=0 in the figure so that RF 0 is RFstart. Figure E.7: Cell allocations for the sub-slices prior to "folding" Figure E.8: Cell allocations for the sub-slices after folding NOTE 1: For the mapping described, RF_shift will be given by: DType 2 DType 2 RF _ shift = 2 = , N RF N subslices N RF N subslices _ total where NRF is the number of RF channels, Nsubslices is the number of sub-slices in one RF channel, and DType2 is the number of cells allocated to Type 2 data PLPs in one T2-frame across all RF channels as defined above. ETSI 146 ETSI EN 302 755 V1.1.1 (2009-09) A receiver should not assume that RF_shift can be calculated as described in note 1 but instead should calculate RF_shift from the signalling fields SUB_SLICE_INTERVAL and NUM_RF. NOTE 2: Both SUB_SLICE_INTERVAL and RF_SHIFT will be integer numbers as a result of the constraint specified in clause E.2.7.2.2. E.2.7.2.5 Mapping the PLP cells to the allocated cell addresses The data cells from the time interleaver will be mapped to the cells allocated to the sub-slices in order of increasing cell address irrespective of the RF index on which the cells are mapped. The data will be written first to the sub-slice or part of a sub-slice that occurs first in the T2-frame. This means that the receiver will start filling the time deinterleaver starting from the first row. The writing order is illustrated in figure E.9 for data PLP 4, which has a divided sub-slice on RF2. The maximum number of FEC blocks PLP_NUM_BLOCKS_MAX which can be allocated by the scheduler to one PLP in one Interleaving Frame will be such that the number of cells Di,2 for one Type-2 PLP in one T2-frame does not exceed Dtype2/NRF. Consequently the same cell address will not be mapped to the same PLP on more than one RF channel in the same T2-frame. Figure E.9: Writing order of mapping of data PLP 4 to OFDM symbols E.2.8 Auxiliary streams and dummy cells Following the type 2 PLPs, the auxiliary streams (if any) and dummy cells will be added on each RF channel as described in clauses 8.3.7 and 8.3.8. Taken together, the data PLPs of both types, auxiliary streams and dummy cells will exactly fill the available capacity of the T2-frame on each RF channel. ETSI 147 ETSI EN 302 755 V1.1.1 (2009-09) Annex F (normative): Calculation of the CRC word The implementation of Cyclic Redundancy Check codes (CRC-codes) allows the detection of transmission errors at the receiver side. For this purpose CRC words shall be included in the transmitted data. These CRC words shall be defined by the result of the procedure described in this annex. A CRC code is defined by a polynomial of degree n: Gn (x ) = x n + g n −1 x n −1 + K + g 2 x 2 + g1 x + 1 with n ≥ 1 : and: g i ∈ {0,1} , i = 1.....n − 1 The CRC calculation may be performed by means of a shift register containing n register stages, equivalent to the degree of the polynomial (see figure F.1). The stages are denoted by b0... bn-1, where b0 corresponds to 1, b1 to x, b2 to x2,..., bn-1 to xn-1. The shift register is tapped by inserting XORs at the input of those stages, where the corresponding coefficients gi of the polynomial are '1'. Data Input g1 g2 g n-2 g n-1 LSb b0 b1 bn-2 bn-1 MSb Figure F.1: General CRC block diagram At the beginning of the CRC-8 calculation (used for GFPS and TS, NM only and BBHEADER), all register stage contents are initialized to zeros. At the beginning of the CRC-32 calculation (used for the L1-pre and L1-post signalling), all register stage contents are initialized to ones. After applying the first bit of the data block (MSB first) to the input, the shift clock causes the register to shift its content by one stage towards the MSB stage (bn-1), while loading the tapped stages with the result of the appropriate XOR operations. The procedure is then repeated for each data bit. Following the shift after applying the last bit (LSB) of the data block to the input, the shift register contains the CRC word which is then read out. Data and CRC word are transmitted with MSB first. The CRC codes used in the DVB-T2 system are based on the following polynomials: • G32 ( x ) = x 32 + x 26 + x 23 + x 22 + x16 + x12 + x11 + x10 + x8 + x 7 + x 5 + x 4 + x 2 + x + 1 • G8 ( x) = x 8 + x 7 + x 6 + x 4 + x 2 + 1 The assignment of the polynomials to the respective applications is given in each clause. NOTE: The CRC-32 coder defined in this annex is identical to the implicit encoder defined in [i.4]. ETSI 148 ETSI EN 302 755 V1.1.1 (2009-09) Annex G (normative): Locations of the continual pilots Table G.1 gives the carrier indices for the continual pilots for each of the pilot patterns in 32K. Table G.2 gives the carrier indices for the additional continual pilots in extended carrier mode. For further details of the use of these, see clause 9.2.4.1. Table G.1: Continual pilot groups for each pilot pattern Group PP1 PP2 PP3 PP4 PP5 PP6 PP7 PP8 CP1 116 255 116 318 116 318 108 116 108 116 264 360 [All modes] 285 430 390 430 342 426 144 264 228 430 1848 2088 518 546 474 518 430 518 288 430 518 601 2112 2160 601 646 601 646 582 601 518 564 646 804 2256 2280 744 1662 708 726 646 816 636 646 1644 1680 3936 3960 1893 1995 1752 1758 1758 1764 828 2184 1752 1800 3984 5016 2322 3309 1944 2100 2400 3450 3360 3396 1836 3288 5136 5208 3351 3567 2208 2466 3504 3888 3912 4032 3660 4080 5664 3813 4032 3792 5322 4020 4932 4932 5220 4932 4968 5568 5706 5454 5640 5154 5250 5676 5688 5472 5292 5334 CP2 1022 1224 1022 1092 1022 1495 601 1022 852 1022 116 430 [2K-32K] 1302 1371 1369 1416 2261 2551 1092 1164 1495 2508 518 601 1495 2261 1446 1495 2802 2820 1369 1392 2551 2604 646 1022 2551 2583 2598 2833 2833 2922 1452 1495 2664 2736 1296 1368 2649 2833 2928 3144 4422 4752 2261 2580 2833 3120 1369 1495 2925 3192 4410 4800 4884 5710 2833 3072 4248 4512 2833 3024 4266 5395 5710 5881 8164 4320 4452 4836 5710 4416 4608 5710 5881 6018 6126 10568 5710 5881 5940 6108 4776 5710 8164 10568 11069 6048 8164 5881 6168 10568 11515 11560 10568 10568 7013 8164 11069 12946 12631 11515 11069 10568 11560 13954 12946 12946 11560 10709 12631 15559 16745 13954 12946 11515 12946 16681 21494 15559 13954 12946 13954 16681 21494 15559 16745 23239 21494 24934 25879 26308 26674 CP3 2261 8164 13954 8164 648 4644 456 480 [4K-32K] 16745 2261 6072 17500 ETSI 149 ETSI EN 302 755 V1.1.1 (2009-09) Group PP1 PP2 PP3 PP4 PP5 PP6 PP7 PP8 CP4 10709 10709 12631 1008 6120 116 132 [8K-32K] 19930 19930 13954 180 430 518 601 646 1022 1266 1369 1495 2261 2490 2551 2712 2833 3372 3438 4086 4098 4368 4572 4614 4746 4830 4968 5395 5710 5881 7649 8164 10568 11069 11560 12631 12946 13954 15760 16612 16745 17500 19078 19930 21494 22867 25879 26308 CP5 1369 7013 6744 7013 1369 5395 6612 6708 1369 2261 116 384 6984 7032 6720 6954 [16K-32K] 7215 7284 7020 7122 5881 6564 7013 7068 5395 5881 408 518 7056 7080 7013 7026 7649 7818 7308 7649 6684 7013 7164 7224 6552 6636 601 646 7152 7320 7092 7512 8025 8382 7674 7752 7649 8376 7308 7464 6744 6900 672 960 7392 7536 7536 7596 8733 8880 7764 8154 8544 8718 7649 7656 7032 7296 1022 1272 7649 7704 7746 7758 9249 9432 8190 8856 8856 9024 7716 7752 7344 7464 1344 1369 7728 7752 7818 7986 9771 8922 9504 9132 9498 7812 7860 7644 7649 1495 1800 8088 8952 8160 8628 10107 9702 9882 9774 9840 8568 8808 7668 7956 2040 2261 9240 9288 9054 9096 10110 9924 10302 8880 9072 8124 8244 2833 3192 9312 9480 9852 9924 10398 10032 10512 9228 9516 8904 8940 3240 3768 9504 9840 10146 10659 10092 10566 9696 9996 8976 9216 3864 3984 9960 10254 10709 10266 10770 10560 9672 9780 4104 4632 10320 10428 10785 10302 10914 10608 10224 4728 4752 10368 10704 10872 10494 11340 10728 10332 4944 5184 10728 11418 11115 10530 11418 11148 10709 5232 5256 10752 11436 11373 10716 11730 11232 10776 5376 5592 11448 11496 11515 11016 11742 11244 10944 5616 5710 11640 11550 11649 11076 12180 11496 11100 5808 5881 11688 11766 11652 11160 12276 11520 11292 6360 6792 11808 11862 12594 11286 12474 11664 11364 6960 7013 12192 12006 12627 11436 12486 11676 11496 7272 7344 12240 12132 12822 11586 15760 11724 11532 7392 7536 12480 12216 12984 12582 16612 11916 11904 7649 7680 12816 12486 15760 13002 17500 17500 12228 7800 8064 16681 12762 16612 17500 18358 18358 12372 8160 8164 22124 18358 17500 18358 19078 19078 12816 8184 8400 20261 18358 19078 19930 21284 15760 8808 8832 20422 19078 22124 20261 22124 16612 9144 9648 22124 19930 23239 20422 23239 17500 9696 9912 23239 20261 24073 22124 24073 19078 10008 24934 20422 24934 22867 24934 22867 10200 22124 25879 23239 25879 25879 10488 22867 26308 24934 26308 10568 23239 25879 10656 24934 26308 10709 ETSI 150 ETSI EN 302 755 V1.1.1 (2009-09) Group PP1 PP2 PP3 PP4 PP5 PP6 PP7 PP8 25879 26674 11088 26308 11160 26674 11515 11592 12048 12264 12288 12312 12552 12672 12946 13954 15559 16681 17500 19078 20422 21284 22124 23239 24934 25879 26308 26674 ETSI 151 ETSI EN 302 755 V1.1.1 (2009-09) Group PP1 PP2 PP3 PP4 PP5 PP6 PP7 PP8 CP6 13164 13080 13080 13416 10709 [32K only] 13206 13152 13368 13440 11515 13476 13260 13464 13536 13254 13530 13380 13536 13608 13440 13536 13428 13656 13704 13614 13764 13572 13728 13752 13818 13848 13884 13824 14016 14166 13938 13956 14112 14040 14274 13968 14004 14232 14112 14304 14028 14016 14448 14208 14364 14190 14088 14472 14304 14586 14316 14232 14712 14376 14664 14526 14304 14808 14448 15030 14556 14532 14952 14616 15300 14562 14568 15000 14712 15468 14658 14760 15336 14760 15474 14910 14940 15360 14832 15559 14946 15168 15408 14976 15732 15048 15288 15600 15096 15774 15186 15612 15624 15312 16272 15252 15684 15648 15336 16302 15468 15888 16128 15552 16428 15540 16236 16296 15816 16500 15576 16320 16320 15984 16662 15630 16428 16416 16224 16681 15738 16680 16536 16464 16872 15840 16812 16632 16560 17112 16350 16908 16824 17088 17208 16572 17184 16848 17136 17862 16806 17472 17184 17256 18036 17028 17508 17208 17352 18282 17064 17580 17280 17400 18342 17250 17892 17352 17448 18396 17472 17988 17520 17544 18420 17784 18000 17664 17928 18426 17838 18336 17736 18048 18732 18180 18480 17784 18336 19050 18246 18516 18048 18456 19296 18480 19020 18768 18576 19434 18900 19176 18816 18864 19602 18960 19188 18840 19032 19668 19254 19320 19296 19078 19686 19482 19776 19392 19104 19728 19638 19848 19584 19320 19938 19680 20112 19728 19344 20034 20082 20124 19752 19416 21042 20310 20184 19776 19488 21120 20422 20388 20136 19920 21168 20454 20532 20184 19930 21258 20682 20556 20208 19992 21284 20874 20676 20256 20424 21528 21240 20772 21096 20664 21594 21284 21156 21216 20808 21678 21444 21240 21360 21168 21930 21450 21276 21408 21284 21936 21522 21336 21744 21360 21990 21594 21384 21768 21456 22290 21648 21816 22200 21816 22632 21696 21888 22224 22128 22788 21738 22068 22320 22200 23052 22416 22092 22344 22584 23358 22824 22512 22416 22608 23448 23016 22680 22848 22824 23454 23124 22740 22968 22848 23706 23196 22800 23016 22944 23772 23238 22836 23040 22992 24048 23316 22884 23496 23016 24072 ETSI 152 ETSI EN 302 755 V1.1.1 (2009-09) Group PP1 PP2 PP3 PP4 PP5 PP6 PP7 PP8 23418 23304 23688 23064 24073 23922 23496 23904 23424 24222 23940 23568 24048 23448 24384 24090 23640 24168 23472 24402 24168 24120 24360 23592 24444 24222 24168 24408 24192 24462 24324 24420 24984 24312 24600 24342 24444 25152 24360 24738 24378 24456 25176 24504 24804 24384 24492 25224 24552 24840 24540 24708 25272 24624 24918 24744 24864 25344 24648 24996 24894 25332 25416 24672 25038 24990 25536 25488 24768 25164 25002 25764 25512 24792 25314 25194 25992 25536 25080 25380 25218 26004 25656 25176 25470 25260 26674 25680 25224 25974 25566 26944 25752 25320 26076 26674 25992 25344 26674 26944 26016 25584 26753 25680 26944 25824 26064 26944 Table G.2: Locations of additional continual pilots in extended carrier mode FFT size PP1 PP2 PP3 PP4 PP5 PP6 PP7 PP8 8K None 6820 6847 6820 6869 6820 6869 None NA 6820 6833 6820 6833 6869 6898 6869 6887 6869 6887 6898 6898 16K 13636 13636 13636 13636 13636 13636 13636 13636 13724 13790 13790 13790 13790 13790 13724 13724 13790 13879 13879 13879 32K NA 27268 27268 NA 27268 27268 27268 27688 27688 27448 27688 27368 27688 27448 27758 27580 27688 27758 ETSI 153 ETSI EN 302 755 V1.1.1 (2009-09) Annex H (normative): Reserved carrier indices for PAPR reduction Table H.1 gives the indices of the reserved carriers for the P2 symbol. Table H.2 gives the starting indices for the reserved carriers for pilot patterns PP1-8. For further details of the use of these, see clauses 9.3 and 9.6.2. Table H.1: Reserved carrier indices for P2 symbol FFT size (Number of Reserved Carrier Indices reserved carriers) 1K (10) 116, 130, 134, 157, 182, 256, 346, 478, 479, 532 2K (18) 113, 124, 262, 467, 479, 727, 803, 862, 910, 946, 980, 1201, 1322, 1342, 1396, 1397, 1562, 1565 104, 116, 119, 163, 170, 173, 664, 886, 1064, 1151, 1196, 1264, 1531, 1736, 1951, 1960, 2069, 2098, 4K (36) 2311, 2366, 2473, 2552, 2584, 2585, 2645, 2774, 2846, 2882, 3004, 3034, 3107, 3127, 3148, 3191, 3283, 3289 106, 109, 110, 112, 115, 118, 133, 142, 163, 184, 206, 247, 445, 461, 503, 565, 602, 656, 766, 800, 922, 1094, 1108, 1199, 1258, 1726, 1793, 1939, 2128, 2714, 3185, 3365, 3541, 3655, 3770, 3863, 4066, 4190, 8K (72) 4282, 4565, 4628, 4727, 4882, 4885, 5143, 5192, 5210, 5257, 5261, 5459, 5651, 5809, 5830, 5986, 6020, 6076, 6253, 6269, 6410, 6436, 6467, 6475, 6509, 6556, 6611, 6674, 6685, 6689, 6691, 6695, 6698, 6701 104, 106, 107, 109, 110, 112, 113, 115, 116, 118, 119, 121, 122, 125, 128, 131, 134, 137, 140, 143, 161, 223, 230, 398, 482, 497, 733, 809, 850, 922, 962, 1196, 1256, 1262, 1559, 1691, 1801, 1819, 1937, 2005, 2095, 2308, 2383, 2408, 2425, 2428, 2479, 2579, 2893, 2902, 3086, 3554, 4085, 4127, 4139, 4151, 4163, 4373, 4400, 4576, 4609, 4952, 4961, 5444, 5756, 5800, 6094, 6208, 6658, 6673, 6799, 7208, 7682, 8101, 16K (144) 8135, 8230, 8692, 8788, 8933, 9323, 9449, 9478, 9868, 10192, 10261, 10430, 10630, 10685, 10828, 10915, 10930, 10942, 11053, 11185, 11324, 11369, 11468, 11507, 11542, 11561, 11794, 11912, 11974, 11978, 12085, 12179, 12193, 12269, 12311, 12758, 12767, 12866, 12938, 12962, 12971, 13099, 13102, 13105, 13120, 13150, 13280, 13282, 13309, 13312, 13321, 13381, 13402, 13448, 13456, 13462, 13463, 13466, 13478, 13492, 13495, 13498, 13501, 13502, 13504, 13507, 13510, 13513, 13514, 13516 104, 106, 107, 109, 110, 112, 113, 115, 118, 121, 124, 127, 130, 133, 136, 139, 142, 145, 148, 151, 154, 157, 160, 163, 166, 169, 172, 175, 178, 181, 184, 187, 190, 193, 196, 199, 202, 205, 208, 211, 404, 452, 455, 467, 509, 539, 568, 650, 749, 1001, 1087, 1286, 1637, 1823, 1835, 1841, 1889, 1898, 1901, 2111, 2225, 2252, 2279, 2309, 2315, 2428, 2452, 2497, 2519, 3109, 3154, 3160, 3170, 3193, 3214, 3298, 3331, 3346, 3388, 3397, 3404, 3416, 3466, 3491, 3500, 3572, 4181, 4411, 4594, 4970, 5042, 5069, 5081, 5086, 5095, 5104, 5320, 5465, 5491, 6193, 6541, 6778, 6853, 6928, 6934, 7030, 7198, 7351, 7712, 7826, 7922, 8194, 8347, 8350, 8435, 8518, 8671, 8861, 8887, 9199, 9980, 10031, 10240, 10519, 10537, 10573, 10589, 11078, 11278, 11324, 11489, 11642, 12034, 12107, 12184, 12295, 12635, 12643, 12941, 12995, 13001, 13133, 13172, 13246, 13514, 13522, 13939, 14362, 14720, 14926, 15338, 15524, 15565, 15662, 15775, 32K (288) 16358, 16613, 16688, 16760, 17003, 17267, 17596, 17705, 18157, 18272, 18715, 18994, 19249, 19348, 20221, 20855, 21400, 21412, 21418, 21430, 21478, 21559, 21983, 21986, 22331, 22367, 22370, 22402, 22447, 22535, 22567, 22571, 22660, 22780, 22802, 22844, 22888, 22907, 23021, 23057, 23086, 23213, 23240, 23263, 23333, 23369, 23453, 23594, 24143, 24176, 24319, 24325, 24565, 24587, 24641, 24965, 25067, 25094, 25142, 25331, 25379, 25465, 25553, 25589, 25594, 25655, 25664, 25807, 25823, 25873, 25925, 25948, 26002, 26008, 26102, 26138, 26141, 26377, 26468, 26498, 26510, 26512, 26578, 26579, 26588, 26594, 26597, 26608, 26627, 26642, 26767, 26776, 26800, 26876, 26882, 26900, 26917, 26927, 26951, 26957, 26960, 26974, 26986, 27010, 27013, 27038, 27044, 27053, 27059, 27061, 27074, 27076, 27083, 27086, 27092, 27094, 27098, 27103, 27110, 27115, 27118, 27119, 27125, 27128, 27130, 27133, 27134, 27140, 27143, 27145, 27146, 27148, 27149 ETSI 154 ETSI EN 302 755 V1.1.1 (2009-09) Table H.2: Reserved carrier indices for PP 1, 2, 3, 4, 5, 6, 7 and 8 FFT size (Number of Reserved Carrier Indices reserved carriers) 1K (10) 109, 117, 122, 129, 139, 321, 350, 403, 459, 465 2K (18) 250, 404, 638, 677, 700, 712, 755, 952, 1125, 1145, 1190, 1276, 1325, 1335, 1406, 1431, 1472, 1481 170, 219, 405, 501, 597, 654, 661, 745, 995, 1025, 1319, 1361, 1394, 1623, 1658, 1913, 1961, 1971, 2106, 4K (36) 2117, 2222, 2228, 2246, 2254, 2361, 2468, 2469, 2482, 2637, 2679, 2708, 2825, 2915, 2996, 3033, 3119 111, 115, 123, 215, 229, 392, 613, 658, 831, 842, 997, 1503, 1626, 1916, 1924, 1961, 2233, 2246, 2302, 2331, 2778, 2822, 2913, 2927, 2963, 2994, 3087, 3162, 3226, 3270, 3503, 3585, 3711, 3738, 3874, 3902, 8K (72) 4013, 4017, 4186, 4253, 4292, 4339, 4412, 4453, 4669, 4910, 5015, 5030, 5061, 5170, 5263, 5313, 5360, 5384, 5394, 5493, 5550, 5847, 5901, 5999, 6020, 6165, 6174, 6227, 6245, 6314, 6316, 6327, 6503, 6507, 6545, 6565 109, 122, 139, 171, 213, 214, 251, 585, 763, 1012, 1021, 1077, 1148, 1472, 1792, 1883, 1889, 1895, 1900, 2013, 2311, 2582, 2860, 2980, 3011, 3099, 3143, 3171, 3197, 3243, 3257, 3270, 3315, 3436, 3470, 3582, 3681, 3712, 3767, 3802, 3979, 4045, 4112, 4197, 4409, 4462, 4756, 5003, 5007, 5036, 5246, 5483, 5535, 5584, 5787, 5789, 6047, 6349, 6392, 6498, 6526, 6542, 6591, 6680, 6688, 6785, 6860, 7134, 7286, 7387, 16K (144) 7415, 7417, 7505, 7526, 7541, 7551, 7556, 7747, 7814, 7861, 7880, 8045, 8179, 8374, 8451, 8514, 8684, 8698, 8804, 8924, 9027, 9113, 9211, 9330, 9479, 9482, 9487, 9619, 9829, 10326, 10394, 10407, 10450, 10528, 10671, 10746, 10774, 10799, 10801, 10912, 11113, 11128, 11205, 11379, 11459, 11468, 11658, 11776, 11791, 11953, 11959, 12021, 12028, 12135, 12233, 12407, 12441, 12448, 12470, 12501, 12548, 12642, 12679, 12770, 12788, 12899, 12923, 12939, 13050, 13103, 13147, 13256, 13339, 13409 164, 320, 350, 521, 527, 578, 590, 619, 635, 651, 662, 664, 676, 691, 723, 940, 1280, 1326, 1509, 1520, 1638, 1682, 1805, 1833, 1861, 1891, 1900, 1902, 1949, 1967, 1978, 1998, 2006, 2087, 2134, 2165, 2212, 2427, 2475, 2555, 2874, 3067, 3091, 3101, 3146, 3188, 3322, 3353, 3383, 3503, 3523, 3654, 3856, 4150, 4158, 4159, 4174, 4206, 4318, 4417, 4629, 4631, 4875, 5104, 5106, 5111, 5131, 5145, 5146, 5177, 5181, 5246, 5269, 5458, 5474, 5500, 5509, 5579, 5810, 5823, 6058, 6066, 6098, 6411, 6741, 6775, 6932, 7103, 7258, 7303, 7413, 7586, 7591, 7634, 7636, 7655, 7671, 7675, 7756, 7760, 7826, 7931, 7937, 7951, 8017, 8061, 8071, 8117, 8317, 8321, 8353, 8806, 9010, 9237, 9427, 9453, 9469, 9525, 9558, 9574, 9584, 9820, 9973, 10011, 10043, 10064, 10066, 10081, 10136, 10193, 10249, 10511, 10537, 11083, 11350, 11369, 11428, 11622, 11720, 11924, 11974, 11979, 12944, 12945, 13009, 13070, 13110, 13257, 13364, 13370, 32K (288) 13449, 13503, 13514, 13520, 13583, 13593, 13708, 13925, 14192, 14228, 14235, 14279, 14284, 14370, 14393, 14407, 14422, 14471, 14494, 14536, 14617, 14829, 14915, 15094, 15138, 15155, 15170, 15260, 15283, 15435, 15594, 15634, 15810, 16178, 16192, 16196, 16297, 16366, 16498, 16501, 16861, 16966, 17039, 17057, 17240, 17523, 17767, 18094, 18130, 18218, 18344, 18374, 18657, 18679, 18746, 18772, 18779, 18786, 18874, 18884, 18955, 19143, 19497, 19534, 19679, 19729, 19738, 19751, 19910, 19913, 20144, 20188, 20194, 20359, 20490, 20500, 20555, 20594, 20633, 20656, 21099, 21115, 21597, 22139, 22208, 22244, 22530, 22547, 22562, 22567, 22696, 22757, 22798, 22854, 22877, 23068, 23102, 23141, 23154, 23170, 23202, 23368, 23864, 24057, 24215, 24219, 24257, 24271, 24325, 24447, 25137, 25590, 25702, 25706, 25744, 25763, 25811, 25842, 25853, 25954, 26079, 26158, 26285, 26346, 26488, 26598, 26812, 26845, 26852, 26869, 26898, 26909, 26927, 26931, 26946, 26975, 26991, 27039 ETSI 155 ETSI EN 302 755 V1.1.1 (2009-09) Annex I (informative): Transport Stream regeneration and clock recovery using ISCR When the modulator operates in a mode that employs null-packet deletion, the receiver may regenerate the Transport Stream by inserting, before each useful packet, DNP in the reception FIFO buffer. As shown in figure I.1, the Transport Stream clock R'IN may be recovered by means of a Phase Locked Loop (PLL). The recovered modulator sampling rate Rs may be used to clock a local counter (which by definition runs synchronously with the input stream synchronization counter of figure C.1). The PLL compares the local counter content with the transmitted ISCR of each TS packet, and the phase difference may be used to adjust the R'IN clock. In this way R'IN remains constant, and the reception FIFO buffer automatically compensates the chain delay variations. Since the reception FIFO buffer is not self-balancing, the TTO and the BUFS information may be used to set its initial state. As an alternative, when dynamic variations of the end-to-end delay and bit-rate may be acceptable by the source decoders, the receiver buffer filling condition may be used to drive the PLL. In this case the reception buffer is self-balancing (in steady state half of cells are filled), and the ISSY field may be omitted at the transmitting side. Rs Local Counter PLL Transmitted ISCR DNP R’IN Null-packet Write TS FIFO Read TS packets Re-insertion packets BUFFER Useful packets Figure I.1: Example receiver block diagram for Null-packet re-insertion and RTS clock recovery ETSI 156 ETSI EN 302 755 V1.1.1 (2009-09) Annex J (informative): Pilot patterns This annex illustrates each of the scattered pilot patterns, showing the pattern of pilots at the low frequency edge of the ensemble and for the last few symbols of a frame. It shows first the patterns in SISO mode (figures J.1 to J.8) and then the patterns in MISO mode (figures J.9 to J.16). Continual pilots and reserved carriers are not shown. The patterns of pilots around the P2 symbol(s) are shown in figures J.17 and J.18. Figure J.1: Scattered pilot pattern PP1 (SISO) Figure J.2: Scattered pilot pattern PP2 (SISO) ETSI 157 ETSI EN 302 755 V1.1.1 (2009-09) Figure J.3: Scattered pilot pattern PP3 (SISO) Figure J.4: Scattered pilot pattern PP4 (SISO) Figure J.5: Scattered pilot pattern PP5 (SISO) ETSI 158 ETSI EN 302 755 V1.1.1 (2009-09) Figure J.6: Scattered pilot pattern PP6 (SISO) Figure J.7: Scattered pilot pattern PP7 (SISO) Figure J.8: Scattered pilot pattern PP8 (SISO) ETSI 159 ETSI EN 302 755 V1.1.1 (2009-09) Figure J.9: Scattered pilot pattern PP1 (MISO) Figure J.10: Scattered pilot pattern PP2 (MISO) Figure J.11: Scattered pilot pattern PP3 (MISO) ETSI 160 ETSI EN 302 755 V1.1.1 (2009-09) Figure J.12: Scattered pilot pattern PP4 (MISO) Figure J.13: Scattered pilot pattern PP5 (MISO) Figure J.14: Scattered pilot pattern PP6 (MISO) ETSI 161 ETSI EN 302 755 V1.1.1 (2009-09) Figure J.15: Scattered pilot pattern PP7 (MISO) Figure J.16: Scattered pilot pattern PP8 (MISO) ETSI 162 ETSI EN 302 755 V1.1.1 (2009-09) k’ (physical carrier) –3456 –3408 (a) Extended carrier mode 48(=Kext) 0 k (logical carrier) symbol 0 P2 1 2 3 4 5 6 7 w0 w48 w1 Symbol-level PRBS value w49 –3456 (b) Normal carrier mode k’ (physical carrier) –3408 0 k (logical carrier) symbol 0 P2 1 2 3 4 5 6 7 w48 Symbol-level PRBS value w49 Frequency P2 Pilot Edge Pilot: always k=0 and k=Kmax Scattered Pilot: same k’ values in given symbol (data symbols only) Figure J.17: Example of pilot and TR cells at the edge of the spectrum in extended and normal carrier mode (8K PP7) ETSI 163 ETSI EN 302 755 V1.1.1 (2009-09) k’ (physical carrier) –2811 –2760 645 (a) Extended carrier mode 696 k (logical carrier) symbol 658 0 P2 1 2 3 4 5 6 7 w645 w696 w646 Symbol-level PRBS value w697 (b) Normal carrier mode k’ (physical carrier) –2811 –2760 648 658 k (logical carrier) 597 symbol 0 1 P2 2 3 4 5 6 7 w645 Symbol-level PRBS value w696 w646 w697 Frequency P2 Pilot Edge Pilot: always k=0 and k=Kmax Tone Reservation cell Continual Pilot Scattered Pilot Figure J.18: Example of pilot and TR cells in extended and normal carrier mode (8K PP7) ETSI 164 ETSI EN 302 755 V1.1.1 (2009-09) Annex K (informative): Allowable sub-slicing values Table K.1 shows the allowed value for the total number of sub-slices Nsubslices_total = NRF ×Nsubslices (see clauses 6.5.4 and 8.3.6.3.2) at the output of each time interleaver block of each PLP. Since the same value must be used for all PLPs, the value selected from the table must be available for all modulation types and FEC block sizes currently in use. The safest possible options are those from the table of short FEC block sizes with a 'Y' in all four columns, since this will always be suitable for all PLPs. These are listed in the table K.2. If only long FEC blocks are used, values from table K.3 can be used. Table K.1: List of available number of sub-slices for different constellations and FEC block sizes Long Short LDPC Constellation LDPC Constellation blocks blocks 64K QPSK 16-QAM 64-QAM 256-QAM 16K QPSK 16-QAM 64-QAM 256-QAM 1 Y Y Y Y 1 Y Y Y Y 2 Y Y Y Y 2 Y Y Y 3 Y Y Y Y 3 Y Y Y Y 4 Y Y Y Y 4 Y Y 5 Y Y Y Y 5 Y Y Y Y 6 Y Y Y Y 6 Y Y Y 8 Y Y Y 9 Y Y Y Y 9 Y Y Y Y 10 Y Y Y 10 Y Y Y Y 12 Y Y 12 Y Y Y Y 15 Y Y Y Y 15 Y Y Y Y 18 Y Y Y 16 Y Y 20 Y Y 18 Y Y Y Y 27 Y Y Y Y 20 Y Y Y Y 30 Y Y Y 24 Y Y Y 36 Y Y 27 Y Y Y Y 45 Y Y Y Y 30 Y Y Y Y 54 Y Y Y 36 Y Y Y Y 60 Y Y 40 Y Y Y 81 Y Y Y 45 Y Y Y Y 90 Y Y Y 48 Y Y 108 Y Y 54 Y Y Y Y 135 Y Y Y Y 60 Y Y Y Y 162 Y Y 72 Y Y Y 180 Y Y 80 Y Y 270 Y Y Y 81 Y Y Y 324 Y 90 Y Y Y Y 405 Y Y Y 108 Y Y Y Y 540 Y Y 120 Y Y Y 810 Y Y 135 Y Y Y Y 1 620 Y 144 Y Y 162 Y Y Y 180 Y Y Y Y 216 Y Y Y 240 Y Y 270 Y Y Y Y 324 Y Y Y 360 Y Y Y 405 Y Y Y 432 Y Y 540 Y Y Y Y 648 Y Y 720 Y Y 810 Y Y Y 1 080 Y Y Y 1 296 Y 1 620 Y Y Y 2 160 Y Y 3 240 Y Y 6 480 Y ETSI 165 ETSI EN 302 755 V1.1.1 (2009-09) Table K.2: List of values for number of sub-slices which may be used with any combination of PLPs (short or long FEC blocks) 1 3 5 9 15 27 45 135 Table K.3: List of values for number of sub-slices which may be used with any combination of PLPs (long FEC blocks only) 1 2 3 4 5 6 9 10 12 15 18 20 27 30 36 45 54 60 90 108 135 180 270 540 ETSI 166 ETSI EN 302 755 V1.1.1 (2009-09) Annex L (informative): Bibliography • ETSI TS 102 005: "Digital Video Broadcasting (DVB); Specification for the use of video and audio coding in DVB services delivered directly over IP". • U. Reimers, A. Morello: "DVB-S2, the second generation standard for satellite broadcasting and unicasting", submitted to International Journal on Satellite Communication Networks, 2004; 22. • M. Eroz, F.-W. Sun and L.-N. Lee: "DVB-S2 Low Density Parity Check Codes with near Shannon Limit Performance", submitted to International Journal on Satellite Communication Networks, 2004; 22. • V. Mignone, A. Morello, "CD3-OFDM: a novel demodulation scheme for fixed and mobile receivers", IEEE Transaction on Communications, vol. 44, n. 9, September 1996. • CENELEC EN 50083-9: "Cable networks for television signals, sound signals and interactive services - Part 9: Interfaces for CATV/SMATV headends and similar professional equipment for DVB/MPEG-2 transport streams". • S.M. Alamouti, "A Simple Transmit Diversity Technique for Wireless Communications", IEEE Journal on Select Areas in Communications, vol 16, no. 8, October 1998. ETSI 167 ETSI EN 302 755 V1.1.1 (2009-09) History Document history V1.1.1 October 2008 Public Enquiry PE 20090227: 2008-10-30 to 2009-02-27 V1.1.1 July 2009 Vote V 20090907: 2009-07-09 to 2009-09-07 V1.1.1 September 2009 Publication ETSI