FR2919775A1 - METHOD AND DEVICE FOR SYNCHRONIZING A DATA STREAM IN A SINGLE FREQUENCY NETWORK - Google Patents

Abstract

According to a first aspect, the invention relates to a method for adapting a data stream with a view to its isochronous distribution by a network of transmitters operating on a single frequency, comprising: - the division of the data stream into a plurality of mega-frames, and inserting in each mega-frame an initialization packet for use by the transmitters to synchronize the distribution of the data stream, the initialization packet of a mega-frame comprising a field STS intended to indicate the beginning of the transmission of the next mega-frame to the transmitters, - the evaluation, for each mega-frame, of the beginning of the transmission of the next mega-frame with respect to a non-high time reference -resolution having an imprecision, characterized in that, for each mega-frame, a correction is applied to the evaluation of the start of transmission of the next mega-frame to delay said evaluation of the inaccuracy of the temporal reference, and the fields STS and maximum_delay of the mega-frame are informed taking into account the corrected evaluation. The invention also extends to a device comprising means for implementing the method.

Description

The field of the invention is that of communication systems, and more

  precisely that of communication systems for broadcasting multimedia content to fixed or portable receivers via digital radio networks of the single frequency network type (SFN network for Single Frequency Network). The DVB-T, DVB-H, DVB-SH standards are examples of digital terrestrial broadcasting standards for broadcasting content to fixed or portable receivers in which broadcast streams are synchronized for distribution in a network environment. single frequency. In an SFN network, a content source transmits the data to be broadcast to a plurality of transmitters synchronized with each other. Synchronization is indeed necessary so that all the transmitters of the SFN network transmit the same binary information (bits) in the same frequencies and at the same time. In order for all the transmitters to be able to broadcast the transport stream synchronously, the transport stream includes markers that make it possible to define a reference between a position in the bit stream and a time reference.

  In the case of DVB-T and also DVB-H, a technique for synchronizing transmitters in a single frequency network is specified in ETSI TS 101 191 entitled Digital Video Broadcasting (DVD); DVB mega-frame for Single Frequency Network (SFN) Synchronization.

  This specification proposes that an SFN adapter having the common transport stream facilitates the synchronization of the transmitters by transmitting to the transmitters time information which is calculated based on a repetitive time reference and a frequency reference, these references being obtained from a high-resolution time source such as a GPS satellite positioning system. This time reference is broken down into a 10 MHz clock signal giving a

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  precision of 100 ns and in a signal pps (pulse per second) giving with the same precision the division of the time in seconds. The SFN adapter specified in ETSI TS 101 191 is more specifically responsible for forming groups of temporally marked frames (called mega-frame, mega-frame according to the English terminology) and sending these mega-frames on the distribution network to the transmitters of the SFN network, thus allowing the modulators associated with the transmitters to be synchronized accurately and to deliver the same bits on the same COFDM carriers at the same time. All the 1 o signals broadcast by the transmitters are thus identical which allows for a simultaneity of reception of information by all users. A mega-frame consists more precisely of a group of n TS packets or RS packets (i.e. TS packets to which Reed Solomon OFDM coding information has been added), where n is an integer which depends on the number of RS packets per mega-frame OFDM in the DVBT transmission mode used. A mega-frame contains a synchronization marker known as the Mega-frame Initialization Packet (MIP). An MIP is an MPEG-2 packet with a dedicated identifier (PID). The MIP packet of a mega-frame of index M mainly makes it possible to determine the starting point of the next M + 1 index mega-frame and to provide the transmitters with the moment at which they must start the transmission. . The MIP notably carries information intended for transmitters and concerning the position of the first packet of the next mega-frame 25 in the transport stream (expressed in terms of the number of TS MPEG-2 packets), timing information (with a precision 100 ns) indicating to the modulator when modulation of the next mega-frame should be started, as well as configuration values for modulation and transmission parameters. The time information included in the MIP packet of a mega-frame is mainly the STS (Synchronization Time-Stamp) field and the maximum_delay field, as defined in ETSI specification TS 101 191 and illustrated in its appendix B Functional description of SFN synchronization). The STS field of the MIP packet of a mega-frame of index M contains the time difference between the last pulse of the reference 1 pps which precedes the beginning of the mega-frame of index M + 1 and the actual departure of this mega-frame at the SFN adapter to senders. The maximum_delay field contains the time difference between the moment of the synchronous transmission of the start of the megatram M + 1 by the antennas of all the transmitters in the cell of the SFN network, and the departure of the mega-frame. M + 1 at the SFN adapter to the transmitters. The value of the maximum_delay field must be greater than the sum of the longest delay in the distribution network and the delays in modulators, power transmitters, and antenna feeders. The maximum value of the maximum_delay field is one second. A transmitter receiving the start of a mega-frame at Trec (expressed in units of 100 ns relative to the current pulsation of the reference 1 pps) will delay this mega-frame by a duration Tdelay which is equal to STS + maximum_delay - Trec) modulo 10 '. As we have seen, state-of-the-art SFN adapters are provided with a time reference provided by a high-resolution time source (eg via a GPS), and implemented on computer systems. or real-time electronics. However, it would be preferable to perform the SFN adaptation function at a lower cost, for example on non-real-time computer systems with less accurate time reference than GPS. In this respect, it has been proposed by WO 2006/046107 that a non-high-resolution inaccurate time reference be delivered to the SFN adapter. More specifically, this document provides that the adapter

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  SFN receives the time reference of a server respecting the Network Time Protocol (NTP). In this way, the STS field of the MIP is determined with respect to the imprecise time reference. In the technique proposed by this document, the transmitters of the single frequency network implement the synchronization recommended in the ETSI specification, which consists for a transmitter to compare the STS field (here inaccurate because established with respect to the imprecise time reference of the server NTP) with the arrival time Trec of the mega-frame via the distribution network (this arrival time Trec being precise since determined with respect to a precise temporal reference delivered to the transmitters by a high-resolution source of the GPS type) . The transmitter then decides to delay the transmission of the mega-frame by a delay Tdelay given by the difference between the maximum delay for joining the transmitter furthest and the difference between the arrival time Trec of the mega-frame and the STS.

  The transmitter thus retards the emission of Tdelay = (STS + maximum_delay -Trec) modulo 10 '. Although the method recommended in this document makes it possible to overcome the use of a high-resolution temporal reference (for example a GPS source) at the level of the SFN adapter, it nevertheless has drawbacks. In particular, when the delay to reach the nearest transmitter via the distribution network is less than the inaccuracy of the non-high-resolution time source delivered to the SFN adapter, it is possible that the synchronization is not correctly performed.

  Consider the following case in which: the imprecise time delivered to the SFN adapter is greater than the absolute time of a quantity A. For example, the SFN adapter thinks that it has sent a mega-frame at pps + 200, whereas the time Absolute sending this mega-frame is actually pps + 100; the delay to reach the nearest transmitter is less than A.

  Suppose that the transmission time on the distribution network to reach the nearest transmitter from the SFN adapter is 50. This transmitter will receive at absolute time (pps + 100) +50, information that is indicates as having been sent to pps + 200. This issuer will therefore deduce that the information is part of the previous pps, and that it therefore took 950 ns to reach him. This transmitter can then delay the transmission only if the maximum_delay field in the MIP packet is greater than 950 and all the repeaters are actually less than 50 of the SFN adapter, which excludes 1 o to use in such a case the satellite or the internet as a distribution network. These media actually have delivery times well above 50ns, which requires the operator to indicate delays of the order of 950ns when in reality these delays are of the order of one hundred ns. On the basis of this observation, the object of the invention is to propose a technique for the synchronization of transmitters in a single frequency network that does not require the use of a high-resolution time reference (of the GPS source type) at the of the SFN adapter while still allowing the implementation of the standard synchronization, in accordance with the ETSI specification, at the level of the transmitters, and which moreover overcomes the disadvantages of the technique proposed in the document WO 2006/046107. . To this end, according to a first aspect, the invention proposes a method for adapting a data stream for isochronous distribution by a network of transmitters operating on a single frequency, comprising: the division of the data stream in a plurality of mega-frames, and inserting in each mega-frame an initialization packet for use by the transmitters to synchronize the distribution of the data stream, the initialization packet of a mega-frame, frame having an STS field for indicating the start of the transmission of the next megatrack to the transmitters,

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  the evaluation, for each mega-frame, of the beginning of the transmission of the next mega-frame with respect to a non-high-resolution temporal reference having an inaccuracy, characterized in that, for each mega-frame, a correction is applied evaluating the start of transmission of the next mega-frame to decrease said evaluation of the inaccuracy of the time reference, and informing the STS field of the mega-frame taking into account the corrected evaluation. Some preferred, but not limiting, aspects of this method are as follows: the evaluation, for each mega-frame, of the beginning of the transmission of the next mega-frame to the transmitters comprises: the determination, with respect to the non-high-resolution time reference, of the time tMIp to which the insertion of the initialization packet in the mega-frame is supposed to be performed, and o the addition of the time of processing and transmission tp of the data of the mega-frame frame remaining to flow until the start of transmission of the next mega-frame at the time tMIp to which the insertion is to be performed, so that the transmission start of the next mega-burst to the transmitters is evaluated at tmip + tp, and in which the field STS is informed taking into account the corrected evaluation according to STS = tmlp + tp ù dt. the mega-frame initialization packet further comprises a maximum_delay field representing the gap between the beginning of the transmission of a mega-frame to the transmitters and the Ttransmitted start of the synchronous distribution of this mega-frame. frame by the transmitters, wherein the data stream is intended to be transmitted to the transmitters via a distribution network having a maximum propagation delay DMAx, and in which the

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  maximum_delay field of each mega-frame according to maximum_delay = DMAx + 2 * dt. the data stream being transmitted to the transmitters via a distribution network having a minimum propagation delay Dmin and a maximum propagation delay DMAx, a virtual distribution network with a minimum propagation delay of zero and a maximum propagation delay equal to DMAx is considered; - Dmin and informs the STS field of a mega-frame taking into account the corrected evaluation of the start of transmission of the next mega-frame on said virtual distribution network; the evaluation, for each mega-frame, of the beginning of the transmission of the next mega-frame on the virtual distribution network comprises: the determination, relative to the non-high-resolution time reference, of the time tMIp at which the insertion of the initialization packet in the mega-frame is supposed to be performed, and the addition of the time of processing and transmission tp of the data of the mega-frame remaining to flow until the beginning of the transmission of the mega next frame to the transmitters at the instant tMIp to which the insertion is supposed to be performed, and the minimum propagation delay Dmin, so that the transmission start of the next mega-frame on the virtual distribution network is evaluated at tmip + tp + Dmin, and the STS field is populated taking into account the corrected evaluation according to STS = tmip + tp + Dmin û dt. The mega-frame initialization packet further comprising a maximum_delay field representing the gap between the start of transmission of a mega-frame to the transmitters and the Ttransmitted start of the isochronous distribution of this mega-frame; frame by the emitters, the maximum_delay field of the megatrames is given according to maximum_delay = DMAxû Dmin + 2 * dt. 20

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  the non-high-resolution time reference is provided by a computer system having a clock whose drift is stabilized according to the Network Time Protocol (NTP). According to a second aspect, the invention proposes a device for adapting a data stream with a view to its isochronous distribution by a network of transmitters operating on a single frequency, comprising: means for splitting the data stream into one plurality of mega-frames, adapted to insert in each mega-frame an initialization packet (MIP) for use by the transmitters to synchronize the distribution of the data stream, the mega-frame initialization packet comprising a field (STS) for indicating the beginning of the transmission of the next mega-frame, evaluation means, for each mega-frame, of the beginning of the transmission of the next mega-frame with respect to a non-temporal reference. high-resolution having an imprecision, characterized in that the means for cutting the stream are further adapted to correct said evaluation of the beginning of the transmission of the next mega-frame in the delay t inaccuracy of the time reference and to fill the STS field of a mega-frame taking into account said corrected evaluation. Other aspects, objects and advantages of the present invention will appear better on reading the following detailed description of preferred embodiments thereof, given by way of non-limiting example, and with reference to the appended drawing in which: Figure 1 schematically shows the cutting of the data stream into a plurality of mega-frames. The invention relates to a method for adapting a data stream with a view to its isochronous distribution by a network of transmitters operating on a single frequency, as well as a device capable of implementing this method.

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  The data stream may be of the DVB-H compatible type. It is mentioned here that, without this being for all that limiting, we will take the example of a DVB-H stream in the following description. The data stream can also be a DVB-SH compatible stream.

  We note indeed that in DVB-SH, the isochronie of the transmitters is ensured in the same way as in DVB-H, except that: a mega-frame carries in DVB-SH the name of SH-frame ; that the MIP packet carries the name of SHIP (SH Initialization Packet) in DVB-SH, the SHIP packet including, just like the MIP packet in DVB-H, the STS and maximum_delay fields. The mega-frame expression that will be used subsequently must not be understood in a limiting manner; this expression also having particular vocation to apply to the SH-frame of a DVB-SH compatible stream.

  In the same way, the MIP expression that will be used later must not be understood in a limiting manner; this expression also having particular application to the SHIP packet of a DVB-SH compatible stream. The device can take the form of an SFN adapter typically placed in each cell behind an IP encapsulator or multiplexer. The device can however be integrated directly into the IP encapsulator or into the multiplexer. It will be understood that the method according to the invention can be implemented either in an SFN adapter, in an IP encapsulator or in a multiplexer fulfilling the SFN adaptation functions. However, we will take in the following, without however being limiting, the classic example of a standalone SFN adapter. In the context of the invention, it is proposed that the SFN adapter not benefit from a high resolution time source as recommended by ETSI specification 101 191 (for example a time source delivered by a GPS receiver), but from a non-high resolution time source characterized by an imprecision dt.

  Thus, where classically one determines in a particularly precise manner the moment atm ') at which the insertion of the MIP packet is carried out in a mega-frame (this instant being evaluated with respect to the temporal reference of the GPS), within the framework of the invention can only evaluate this moment with an inaccuracy corresponding to that of the time reference used. The instant at which the insertion of the MIP packet is supposed to be carried out is thus evaluated at tMIp in the context of the invention, with respect to the non-high resolution temporal reference, with atm ') - dt <tMIp <a tMIp. + The invention pays attention to the fact that the STS field of a mega-frame 1 o does not indicate a start of transmission of the next mega-frame (calculated for example from the imprecise time tMIp of insertion of the MIP packet. ) that is greater than the actual transmission start (related to the absolute time atMip) of this next mega-frame. In this respect, the invention proposes to apply, for each mega-frame, a correction to the evaluation of the start of transmission of the next mega-frame to reduce said evaluation of the inaccuracy of the time reference. We then inform the STS field of the mega-frame taking into account the corrected evaluation. FIG. 1 shows the structure of a data stream 20 cut in a plurality of mega-frames, in particular the mega-frames of index M and M + 1. The MIP packet is inserted into the mega-frame of index M, and contains the STS field which represents the time difference between the last pulse of the reference 1 pps which precedes the beginning of the next megatram of index M + 1 and the true start of this mega-frame at the SFN adapter to the transmitters. In the example here selected, the MIP packet is more precisely positioned in the mega-frame of index M so that p packets of this mega-frame are interposed between the MIP packet and the beginning of the next mega-frame of M + 1 index. When the absolute time atm ') at which the insertion of the MIP packet of the mega-frame of index M is performed with respect to the high-resolution time reference type GPS, the field STS can be calculated as being equal to (atm ') + tp) modulo 107, where tp represents the processing and transmission time of the p packets of the mega-frame of index M to be transmitted before the start of the next mega-frame of index M + 1. In the context of the invention, this absolute time atMIP is not known, and only an inaccurate tMIp evaluation of this absolute time is available. However, because of the inaccuracy of this evaluation, it is possible in particular that the evaluation of the transmission start of the next mega-frame is greater than the true transmission date of the next mega-frame (tmip + tp> atmip + tp).

  The invention then proposes to apply a correction to the evaluation of the start of the transmission of the next mega-frame M + 1, by decreasing the said evaluation by an amount equal to the inaccuracy dt of the non-high time reference. resolution, and to fill in the STS field of the MIP packet of the mega-frame M taking into account said corrected evaluation.

  In particular, according to a first possible embodiment of the invention, and when the insertion time of the MIP packet is evaluated at tMlp, the invention proposes to inform the STS field according to STS = tMIp + tp û dt. Moreover, considering that the distribution network of the data flow destined for the transmitters of the SFN network presents a maximum propagation delay DMAx, one informs the field maximum_delay of each of the mega-frames according to maximum_delay = DMAx + 2 * dt. Thus, each transmitter receiving the mega-frame of index M + 1 to Trec, conventionally delays the broadcast of this mega-frame of Tdelay = {STS + maximum_delay - Trec} modulo 107, that is when the mega start time M + 1 is evaluated with respect to the evaluation of the insertion time of the MIP packet in the mega-frame M, Tdelay = {tMIP + tp + DMAX + dt → Trec} modulo 10 '. It will be noted that the field maximum_delay must be less than 1 second, the implementation of this first mode of the invention requires that the longest path on the distribution network is less than (1 s û 2 * dt).

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  This constraint is, however, quite slight insofar as the inaccuracy values dt commonly obtained with conventional means, such as for example a Unix system having an NTP synchronization, are of the order of ten milliseconds, very weak vis-à-vis the total delay of l s. This constraint can moreover be minimized by a second possible embodiment of the invention. According to this mode, assuming that the distribution network has a propagation delay varying between a minimum propagation delay Dmin and a maximum propagation delay DMAx, we choose to consider a virtual distribution network characterized by a minimum propagation delay of zero and a maximum propagation delay equal to DMAx-Dmin. In other words, it is considered that the SFN adapter is virtually placed at the transmitter closest to the adapter (Drain SFN adapter in the real distribution network) and that other transmitters ( to Di from the SFN adapter in the real distribution network) are brought back to Di-Dmin from the virtual SFN adapter. In the context of this second embodiment, the STS field of a mega-frame is informed by taking into account the corrected evaluation of the start of transmission of the next mega-frame on said virtual distribution network. Considering the case where the evaluation of the transmission start of the next mega-frame is carried out on the basis of the evaluation of the insertion time of the MIP packet at tMIp, the field STS of a mega-frame is informed by taking into account account of the corrected evaluation according to STS = tmip + tp + Dmin ù dt.

  In the context of this second embodiment of the invention, the maximum_delay field of the MIP packet of the mega-frames is advantageously given according to maximum_delay = DMAx ù Dmin + 2 * dt. This is advantageous in that the constraint that the maximum delay of the distribution network must be less than 1 second is reduced. Indeed, this constraint of one second is no longer linked to the path

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  the longest to reach a transmitter, but is mainly related to the difference in time between the longest path and the shortest path. This embodiment therefore authorizes the distribution of SFN transport streams on networks having more than one second of delay of propagation, and more particularly the use in such networks of equipment introducing a high latency, insofar as this latency is between a minimum and a maximum. In such cases, only the difference between the maximum and minimum latencies will be taken into account in the allocated budget of 1s. 1 o Furthermore, the validity of the data stream is not impaired insofar as each transmitter receiving the mega-frame index M + 1 to Trec, typically delays the broadcast of this mega-frame Tdelay = {STS + maximum_delay û Trec} modulo 107, that is, Tdelay = {tMIp + tp + Dmin -dt + DMAx -Dmin + 2 * dt û Trec} modulo 10 'or Tdelay = {tMIp + tp + DMax + dt û 15 Trec} as this is the case for the first embodiment of the invention. Returning to the general description of the invention, we consider the case where the MIP packets are always inserted at the same position in the megatrams (so that p packets follow the MIP packet and Pp packets 20 precede the MIP packet), the fields STS (i) and maximum_delay (i) of the MIP packet of the mega-frame of index i can be obtained from the corresponding fields of the MIP packet of the mega-frame of index i-1 according to: STS (i) = STS (i-1) + P * T, where T represents the transmission processing time of a packet of a mega-frame; 25 maximum_delay (i) = maximum_delay (i-1). The non-high resolution temporal reference used in the context of the invention is understood as a reference having the resolution recommended in the ETSI 101 specification 191. This is in particular a reference supplied to the SFN adapter by a system. non real-time computing, for example having a clock whose drift is stabilized in accordance with the protocol NTP (Network Time Protocol). The resolution of the

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  non-high-resolution time reference is for example from 1 ms to several tens of ms (where that of a GPS is 100ns). Here is repeated the example given in the introduction according to which: the imprecise time delivered to the SFN adapter is greater than the absolute time of a quantity A (the inaccuracy dt thus being greater than or equal to A). For example, the SFN adapter thinks that it has sent a mega-frame at pps + 200, whereas the absolute sending time of this mega-frame is actually pps + 100 (here the inaccuracy dt is greater than or equal to 100). the delay to reach the nearest transmitter is less than A. Suppose that the transmission time Dmin on the distribution network to reach the nearest transmitter from the SFN adapter is 50. This transmitter will then receive at an absolute time (pps + 100) +50, information indicated to it, via the STS field of the previous mega-frame 15, as having been sent to: (pps + 200) -dt in the context of the first mode embodiment of the invention, that is to say information that is indicated to him as having been sent at the latest to pps + 100; The receiver will consider in this case that the mega-frame has taken 50 ns to reach him, which corresponds to the actual delay on the network; (pps + 200) -dt + Dmin in the context of the second possible embodiment of the invention, that is to say a piece of information that is indicated as having at the latest been sent to pps + 150. The receiver will consider in this case that the mega-frame has sent Oms to him. It can be seen that in both cases the transmitter will be able to apply standard SFN mechanisms to calculate the delay to be made to the transmission of the mega-frame, and to ensure the isochronous operation of the network. Note also that the disadvantage reported in the example presented in introduction (950ms delay and sending assumed the previous pps) is this time avoided.

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  As already explained above, the invention is not limited to a method but also extends to a device for adapting a data stream with a view to its synchronous distribution by a network of transmitters operating on a single frequency , comprising means configured to implement the method, and in particular: evaluation means, for each mega-frame, of the beginning of the transmission of the next mega-frame with respect to a non-high-resolution time reference presenting an inaccuracy, means for dividing the data stream into a plurality of mega-frames, adapted to insert in each mega-frame an initialization packet (MIP), adapted to correct said evaluation of the beginning of the transmission of the mega-frame; next frame by delaying the inaccuracy of the time reference and to fill the STS field of the MIP packet taking into account said corrected evaluation.

Claims (9)

  A method of adapting a data stream for isochronous distribution by a network of transmitters operating on a single frequency, comprising: splitting the data stream into a plurality of mega-frames, and inserting in each mega-frame of an initialization packet for use by the transmitters to synchronize the distribution of the data stream, the mega-frame initialization packet having a 1 o STS field to indicate the start transmitting the next mega-frame to the transmitters, evaluating, for each mega-frame, the beginning of the transmission of the next mega-frame with respect to a non-high-resolution temporal reference having an inaccuracy, characterized in that, for each mega-frame, a correction is applied to the evaluation of the start of the transmission of the next mega-frame to decrease said evaluation of the inaccuracy of the reference tempore lle, and we inform the STS field of the mega-frame taking into account the corrected evaluation. 20   The method of claim 1, wherein the evaluation, for each mega-frame, of the start of transmission of the next mega-frame to the transmitters comprises: determining, with respect to the non-high time reference 25 resolution, of the time (tMIp) at which the insertion of the initialization packet (MIP) is supposed to be carried out in the mega-frame, and the addition of the processing and transmission time (tp) of the mega data. -frame remaining to flow until the beginning of transmission of the next mega-frame at said instant (tM, p) which is supposed to be carried out insertion, so that the transmission start of the next mega-frame destination transmitters is evaluated at tmip + tp, and in which the STS field is populated taking into account the corrected evaluation according to STS = tM, p + tp ù dt.   3. Method according to one of claims 1 to 2, wherein the initialization packet of a mega-frame further comprises a maximum_delay field representing the difference between the start of the transmission of a mega-frame to destination. transmitters and the start (Ttransmitted) of the isochronous distribution of this mega-frame by the transmitters, wherein the data stream is intended to be transmitted to the transmitters via a distribution network having a maximum propagation delay DMAx, and wherein one informs the field maximum_delay of each mega-frames according to maximum_delay = DMAx + 2 * dt.   The method according to claim 1, wherein the data stream is transmitted to the transmitters via a distribution network having a minimum propagation delay Dmin and a maximum propagation delay DMax, in which a virtual delay distribution network is considered. zero minimum propagation and a maximum propagation delay equal to DMAx-Dmin and in which the STS field of a mega-frame is informed by taking into account the corrected evaluation of the start of transmission of the next mega-frame on said network virtual distribution.   The method of claim 4, wherein the evaluation, for each mega-frame, of the start of transmission of the next mega-frame on the virtual distribution network comprises: determining, with respect to the non-temporal reference high resolution, of the moment (tMIp) at which the insertion of the initialization packet (MIP) is supposed to be carried out in the mega-frame, and the addition o of the processing and transmission time (tp) of the data of the mega-frame remaining to flow until the beginning of transmission of the next mega-frame to the transmitters at the instant (tM, p) at which the insertion is supposed to be performed, and the minimum propagation delay Dmin, so that the transmission start of the next mega-burst on the virtual distribution network is evaluated at tmip + tp + Dmin, and in which the field STS is filled taking into account the corrected evaluation according to STS = tmip + tp + Dmin ù dt.   The method of claim 5, wherein the mega-frame initialization packet further comprises a maximum_delay field representing the gap between the start of transmission of a mega-frame to the transmitters and the beginning. (Ttransmitted) of the isochronous distribution of this mega-frame by the emitters, and in which one informs the field maximum_delay of the mega-frames according to maximum_delay = DMax ù Dmin + 2 * dt.   7. Method according to one of the preceding claims, wherein the non-high-resolution time reference is provided by a computer system having a clock whose drift is stabilized in accordance with the NTP protocol (Network Time Protocol).   A device for adapting a data stream for isochronous distribution by a network of transmitters operating on a single frequency, comprising: means for splitting the data stream into a plurality of mega-frames adapted for inserting in each mega-frame an initialization packet (MIP) for use by the transmitters to synchronize the distribution of the data stream, the initialization packet of a mega-frame including a field (STS) for indicating the beginning of the transmission of the next mega-frame, means of evaluation, for each mega-frame, of the beginning of the transmission of the next mega-frame with respect to a non-high-resolution time reference having an inaccuracy, characterized in that the flux cutting means are further adapted to correct said evaluation of the start of the transmission of the next mega-frame by delaying the inaccuracy of the reference tem. and to fill the STS field of a mega-frame taking into account said corrected evaluation.   9. Device according to the preceding claim, incorporating a clock providing said non-high resolution time reference.