FR2940563A1 - METHODS FOR BROADCAST AND RE-DIFFUSION OF A SIGNAL IN A RADIOPHONE DIFFUSION NETWORK, DIFFUSER AND RE-DIFFUSER, SIGNAL AND CORRESPONDING COMPUTER PROGRAM PRODUCTS - Google Patents

Abstract

The invention relates to a method for broadcasting a digital signal from a main broadcaster (41) to at least one secondary broadcaster (42, 43) in a digital radio broadcast network. According to the invention, the method implements the following steps, at the main broadcaster (41): generation of at least one marking packet corresponding to a stall order, a marking packet comprising: an identifier of stall order; o stall time information; transmission of said at least one marking packet and said digital signal.

Description

Methods of broadcasting and re-broadcasting a signal in a corresponding radio broadcast network, broadcaster and re-broadcaster, signal and computer program products. FIELD OF THE DISCLOSURE The field of the invention is that of the transmission and broadcasting of digital information, particularly radio data. More specifically, the invention relates to the stalling of programs in a radio broadcast network, making it possible to switch from the broadcast of a main program by a main broadcaster of the network to the broadcasting of a secondary program by a secondary broadcaster or diffuser. The invention applies in particular to radio data broadcast according to one of the following or future standards: DAB or DAB + (for Digital Audio Broadcasting or Digital Broadcasting, described in documents ETSI EN 300 401 and ETSI TS 102 563); DMB (for Digital Multimedia Broadcasting, described in ETSI TS 102 428); DRM (for World Digital Radio or World Digital Radio, described in ETSI ES 201 980); etc. 2. Prior Art The problem of stalling is well known in the field of digital terrestrial television broadcasting, also called TNT, implementing, for example, the DVB-T standard (for Digital Video Broadcasting - Terrestrial or Digital Video Broadcasting - Terrestrial). or DVB-H (for Digital Video Broadcasting - Handheld or Digital Video Broadcast - Portable). In digital television, stalling makes it possible to substitute for a main program, such as a television program covered nationally on France 3 (registered trademark), a secondary program, such as a television program with regional coverage on France 3. It thus passes from a broadcast by a national transmitter broadcasting the main program, to a regional transmitter broadcasting the secondary program. FIG. 1 illustrates an example of a television broadcasting network, comprising a main transmitter 11, also called a headend, supplying one or more secondary transmitters or re-transmitters 121, 122, 131, located at distinct geographical sites. In certain geographic areas, these networks are SFN (Single Frequency Network) or isochronous, which means that the different transmitters operate at the same frequency. For example, the secondary emitters 121 and 122 belong to a first SFN plate 12, and the secondary emitter 131 belongs to a second SFN plate 13. This means that the emitters 121 and 122 of the plate 12 operate at the same frequency F1, and the re-transmitter 131 of the plate 13 operates at another frequency F2. The re-transmitters of the same plate must be synchronized in time and frequency. Conventionally, the headend 11 generates a main digital signal, transmitted by a network adapter and conveyed to the secondary transmitters 121, 122, 131, via a distribution network 14, for example a distribution network. satellite. Such a signal is, for example, of the MPEG2-TS (Motion Picture Expert Group 2 - Transport Stream) type. One or more of the secondary transmitters 121, 122 or 131 can then unhook from the main signal by inserting a secondary program in the main signal and then broadcast the thus modified signal to receiving terminals.

Such stalling technique is described in particular in ANSI / SCTE document 35. It relies on the use of MPEG2-TS transport stream for the transport of stall commands. Unfortunately, it is not possible to apply this solution directly to the field of radio broadcasting. Indeed, the proposed technique, which is based on a modification of the MPEG2-TS stream, is not compatible with radio broadcasting standards such as the DAB, DAB +, or DRM standard. In addition, the adaptation of this solution to the radio broadcast domain for the DMB standard requires modifying the PMT (Program Map Table) tables of the MPEG2-TS transport stream to signal flows containing stall commands, and to add PID packet identifiers. However, this modification of the transport stream is not desirable in radio broadcasting. Indeed, it causes a decrease in the rate during the re-broadcast of the flow of secondary transmitters to the receiving terminals, due to the addition of packets or packet identifiers. In addition, the data added to the PMT is not part of the DMB specification. It is therefore not desirable to disseminate them. There is therefore a need for a new stall technique in the field of digital radio broadcasting, not having all of these disadvantages of the prior art. 3. DISCLOSURE OF THE INVENTION The invention proposes a new solution which does not have all of these disadvantages of the prior art, in the form of a method for broadcasting a digital signal of a main diffuser. to at least one secondary broadcaster, also called re-broadcaster, in a digital radio broadcast network. Such a digital signal carries at least one main program. According to the invention, the broadcasting method implements the following steps, at the main broadcaster: generation of at least one marking packet corresponding to a stall order, a tagging packet comprising: an identifier of stall order; o stall time information, defining a time in which the secondary broadcaster can replace the main program with a secondary program in the digital signal; transmission of the marking packet (s) and the digital signal. The invention thus proposes a new and inventive solution of the stall in digital radio, making it possible to manage the stall on all the sites corresponding to the secondary diffusers, or re-diffusers, from the signal or transport stream transmitted by the main broadcaster. . To do this, the invention is based on the use of specific marking packets, corresponding to stall commands, which are transmitted with the digital signal of the main diffuser to the secondary diffuser (s), in the same channel or in a channel. separate. In particular, a marking packet according to the invention carries a stall time information, defining a time during which the secondary broadcaster can insert a secondary program, for example radiophonic, into the digital signal.

For example, this stall time information comprises at least one element belonging to the group comprising: a stall start time; a moment of end of stall; stall duration; a request to start an immediate stall; a request for an immediate stall end. A marking package therefore carries a kind of time stamp, to indicate to re-broadcasters a time range during which they can pick up and broadcast a program separate from the main program. This time stamp is expressed from a clock of the digital transport signal, which depends on the broadcast standard used. For example, if the broadcasting network broadcast standard is the DMB standard, the stall time information is expressed from the object clock reference (OCR) conveyed in the digital signal. DMB. If the broadcasting network broadcast standard is the DAB, DAB +, or DRM standard, the stall time information is expressed from a time stamp. Other known or future radio broadcast standards may also be used within the scope of the invention.

These elements can be present in the different fields of the marking packet. For example, a marking packet comprises a field named Spl Pos Beg bearing a value representative of a start-of-stall time, a field named Spl Pos End bearing a value representing a stall end instant, a field named Spl Hard bearing a value representative of a stall duration. The marking packet may also include an immediate stall start indicator, which, when read by a secondary broadcaster, forces the stall and broadcast of the secondary program, or an immediate stall indicator, which, when it is read by a secondary broadcaster, forces the return to the main program. The tagging packet also includes a stall command identifier, used by the secondary broadcasters to see whether or not to take into account the stall sequence. According to a particular exemplary embodiment, the marking packet also comprises a field called Flags comprising in particular the following indicators: an indicator of the presence of an element of type instant start of stall, named for example Beg; an indicator of the presence of an element of the instant end-of-stall type, named for example End; an indicator of the presence of a stall duration element, named for example Dur; the request indicator for immediate start of stall, forcing a switch to a secondary program, named for example Fin; the immediate stall end request flag, forcing a return on the main program, named for example Fout; an indicator erasing previously stored stall commands for a given stall command identifier, named for example Rst.

According to a first embodiment, the marking packet or packets are inserted into the digital signal prior to the transmission step. In other words, a stall sequence can be transmitted directly into the digital stream, using the transport layer DCP (for Distribution and Communication Protocol) for example. This transmission is described as in-band or in-band transmission. It makes it possible, in particular, to preserve the existing structure of the digital stream, and to ensure compatibility with the re-diffusers adapted to manage a stall or not. According to a second embodiment, the marking packet or packets are transmitted to the secondary diffusers via a means of transmission distinct from the digital signal. A stall sequence can thus be transmitted via a separate link, using an Internet protocol (IP or Internet Protocol) for example. This transmission is described as out-band or out-of-band transmission.

According to one particular aspect of the invention, the digital signal is transmitted according to the DCP distribution and communication protocol, as defined in ETSI standard TS 102 358 for example. It is noted that such a protocol operates, in a conventional manner, with an EDI-type overlay used for the DMB, DAB or DAB + broadcast standards, or of the Multiplex Distribution Interface (MDI) type as described in FIG. ETSI ETS 300 799) for the DRM broadcast standard. According to a particular characteristic of the invention, the broadcasting method comprises a step of receiving a stall insertion request, prior to the step of generating at least one marking packet.

This insertion request can be triggered by an external event, such as sending a command or filing a file, or triggered automatically, taking into account an external clock for example. In particular, the insertion request may carry a timestamp information, expressed taking into account an external synchronization source. The broadcasting method then comprises a step of converting the timestamp information into a stall time information, expressed taking into account a digital signal clock. In other words, if the instant at which the stall must occur is previously known, but is not expressed in the same time base as that of the digital signal, it is necessary to convert this instant into the time base of the signal. digital signal. It is this new information, expressed taking into account the clock of the digital signal, which will be transmitted to the different broadcasters in the marking packet or packets.

In another aspect, the same tagging packet is transmitted periodically. In this way, the non-stall problems that may occur during the loss of a marking packet are avoided. This periodic transmission is interrupted once the stall time has passed.

The invention also relates to a computer program product downloadable from a communication network and / or recorded on a computer readable medium and / or executable by a processor, comprising program code instructions for implementing the method of broadcast as described above.

In another embodiment, the invention relates to a main broadcaster broadcasting a digital signal to at least one secondary broadcaster, in a digital radio broadcast network, said digital signal carrying at least one main program. According to the invention, the main diffuser comprises: means for generating at least one marking packet as defined above; means for transmitting the marking packet or packets and the digital signal. Such a main diffuser is particularly adapted to implement the diffusion method described above. This is for example a device for encoding and multiplexing radio data. Another aspect of the invention relates to a signal broadcast by a main broadcaster to at least one secondary broadcaster, or re-broadcaster, in a digital radio broadcast network, carrying at least one marking packet as defined above. Such a signal is for example broadcast by a main diffuser as described above. It may of course include the various characteristics relating to the diffusion method according to the invention. Thus, in the context of an out-band transmission, this signal carries only stall commands, in the form of marking packets. In the context of in-band transmission, this signal carries at least one main radio program in addition to one or more tagging packets. The invention also relates to a method for re-broadcasting a modified signal, in a digital radio broadcast network comprising a main diffuser supplying at least one secondary diffuser, or re-diffuser. According to the invention, such a method implements the following steps, at at least one of the secondary diffusers: reception of a digital signal carrying at least one main program, and at least one marking packet as defined previously; reading the marking package; checking the stall order identifier, and according to the result: determining a stall start time, from the stall timing information; o replacement of the main program by the secondary program in the digital signal received, from the start of stalling, delivering a modified signal; o broadcast of the modified signal.

The reading of the marking packet thus enables a re-diffuser to determine whether to perform the stall, taking into account the stall order identifier, and when it must perform this stall, taking into account the stall stall time information. The stalling order can therefore be previously received by the repeater, but the stall is performed only when the clock of the received digital signal actually reaches the stall time. Thus, the step of determining a stall start time implements a comparison between the stall time information and a clock of said received digital signal.

As indicated above, according to a first embodiment, the marking packet or packets are inserted into the digital signal prior to transmission. The digital signal received then carries at least one main program and at least one marking packet as defined above. According to a second embodiment, the marking packet or packets are transmitted to the secondary diffusers via a means of transmission distinct from the digital signal. The reception step thus makes it possible to receive a first digital signal carrying at least one main program and a second signal carrying at least one marking packet. According to another aspect of the invention, the re-broadcasting method comprises a preliminary step of receiving the secondary program and storing in a memory. The secondary program can notably be received in real time and stored in a buffer memory. The invention also relates to a computer program product downloadable from a communication network and / or recorded on a computer readable medium and / or executable by a processor, comprising program code instructions for the implementation of the method previously described. Another embodiment of the invention relates to a secondary diffuser of a modified signal, in a digital radio broadcasting network comprising a main diffuser supplying at least one secondary diffuser, comprising: means for receiving a digital signal carrying at least one least one main program and at least one marking packet as previously described: means for reading the marking packet; means for verifying the stall order identifier; means for determining a stall start time, from the stall time information; Means for replacing the main program by the secondary program in the digital signal received, from the stall start time, delivering a modified signal; means for broadcasting the modified signal. Such a secondary diffuser is particularly adapted to implement the re-diffusion method described above. This is for example a local encoder or relay, allowing local stalls. 4. List of Figures Other features and advantages of the invention will emerge more clearly on reading the following description of a particular embodiment, given by way of a simple illustrative and nonlimiting example, and the appended drawings. among which: FIG. 1 illustrates an example of a television broadcasting network according to the prior art; FIG. 2 shows the main steps of the diffusion method according to one embodiment of the invention; FIG. 3 presents the main steps of the re-diffusion method according to one embodiment of the invention; FIG. 4 illustrates an exemplary radio broadcast network according to one embodiment of the invention; - Figure 5 shows the structure of a main diffuser according to one embodiment of the invention; - Figure 6 shows the structure of a secondary diffuser according to one embodiment of the invention; FIGS. 7A to 7D illustrate an exemplary structure of a marking packet according to different broadcasting standards. 5. DESCRIPTION OF AN EMBODIMENT OF THE INVENTION 5.1 GENERAL PRINCIPLE The general principle of the invention is based on the transmission of specific packets, called marking packets, from a main diffuser to at least one secondary diffuser, also called re-broadcaster, in a digital radio broadcast network, to indicate to the secondary broadcaster a time range during which he can drop a main program and broadcast a secondary program, such as a local radio program. In this way, it is possible to manage the stall on different secondary diffusers of the broadcast network from the digital signal broadcast by the main broadcaster, carrying at least one main program. In addition, the stall configuration of the different secondary diffusers is independent. Each secondary diffuser can thus insert into the broadcast signal a program of its own, in the time range thus identified.

In other words, the secondary program replacing the main program during the stall can be a video, a BIFS scene, an audio program, a radio program, etc. The term "unhooking" here refers to the detachment of one or more broadcasters from the broadcasting network to enable the broadcast of local programming. For example, the main program corresponds to the national information, and the program secondary to the regional information, specific to a specific geographical area. Note that the invention can be applied regardless of the radio broadcast standard used, such as DAB, DAB +, DRM, or DMB, or an upcoming standard. FIG. 2 illustrates more precisely the main steps implemented at the main diffuser, for the transmission of a digital signal from the main diffuser to the secondary diffuser or diffusers, according to one embodiment of the invention. During a first step 21, the main diffuser generates at least one marking packet corresponding to a stall order. Such a marking packet comprises at least: a stall order identifier; stall time information, defining a time at which a secondary broadcaster can insert a secondary program, for example a radio program, into the main digital signal. In a next step 22, the main broadcaster transmits the marking packet (s) and the digital signal including at least one main program to the secondary broadcaster (s). This or these packets may be inserted into the digital signal or transmitted via another transmission means. The main steps implemented by a secondary diffuser are illustrated in FIG. 3. During a first step 31, the digital signal and one or more marking packets as defined above are received by a secondary diffuser. The secondary diffuser then reads a marking packet in a second step 32, and checks the stall order identifier during a third step 33.

If the identifier is valid, the secondary broadcaster determines (34) a stall start time, from the stall time information, and replaces (35) the main program with a secondary program, in the digital signal, at the moment of start of stall, delivering a modified signal.

For example, this secondary program is a regional program, replacing a national program transmitted in the digital signal. Finally, the signal thus modified is broadcast (35) to digital receivers, such as mobile phones, car radios, personal digital assistants, set top boxes, etc. 5.2 Description of an Embodiment A) Equipment of the Broadcast Network The following is an example of implementation of the invention in a digital radio broadcasting network comprising a main diffuser and two secondary diffusers or re-diffusers. As illustrated in FIG. 4. According to this example, the main broadcaster 41 comprises a specific module 411, making it possible to generate and send outgoing orders or requests (in English splice) to at least two secondary diffusers 42 and 43.

This stall command generation module 411 takes into account the digital signal, comprising at least one main program, intended to be broadcast by the main broadcaster. This transport signal is still called DMB stream, DAB stream, DRM stream, etc., depending on the broadcast standard used. It is considered hereinafter that this digital signal is transmitted using the DCP transport layer, and this signal signal DCP or DCP flux is recorded, regardless of the broadcast standard used. Of course, this notation is not limiting, and the digital signal can be transported according to other protocols. The stall command generation module 411 makes it possible to construct a stalling order by generating a marking packet comprising at least: a stall command identifier; - Stall time information, to define the stall position in the DCP signal received by a re-diffuser. In other words, a stall sequence contains sufficient data to allow a secondary broadcaster to determine a stalling point or moment in the digital signal broadcast by the main broadcaster. This stall command generating module 411, or the main broadcaster 41 to which it belongs, can then send the stall commands to the secondary broadcasters.

According to an advantageous embodiment, this transmission is an in-band transmission (in the band), illustrated by the arrow 44 in full line. This transmission relies on the insertion of the marking packets directly into the DCP signal, before the DCP is broadcast by the main broadcaster. According to one variant, the transmission is an out-band transmission, illustrated by the arrow 45 in full dashed line. This transmission is based on the sending of the marking packets in a signal distinct from the DCP signal broadcast by the main broadcaster. The secondary diffusers 42, 43 thus receive the DCP signal and the marking packet or packets transmitted in the same channel or in separate channels.

According to the example described, the secondary diffuser 42 (respectively 43) comprises a stall module 421 (respectively 431), capable of receiving and executing received stall commands. This stall module 421 makes it possible to replace a main program of the DCP signal with a secondary program, in order to deliver an off-hook program.

For example, the stall module 421 implements the following steps: reception of the stall commands (in-band or out-band); verification and filtering of stall orders; interpretation of stall orders; management of the sources used to perform the content modification; - DCP flow analysis; stalling. It is noted that the methods according to the invention can be implemented in various ways, in particular in hard-wired form or in software form. These different devices communicate in particular by using the IP protocol. B) Operation of the stall command generation module Hereinafter described in greater detail, in connection with FIG. 5, an example of operation of the main diffuser 41. According to this example, the main diffuser 41 receives as input to encode 51 (digital radio program, audio, video, multimedia file, etc.), which are encoded by a coder 412. The main broadcaster 41 also receives as input stall command insertion requests 52, and optionally synchronization information 53, from an external synchronization source (for example from NTP, for Network Time Protocol or network time protocol). The main diffuser 41 outputs a digital signal formatted in a DCP encapsulator 413, also called DCP stream, as well as marking packets, including stall commands. The stall commands can be inserted into the DCP stream 44 or sent by an ancillary channel 45 (using an internet protocol on an IP channel for example). More specifically, the generation of an off-hook command is implemented in the stall command generation module 411, upon receipt of a stall command insertion request 52. This request may be caused by a stall command. external intervention, such as sending an order via IP, filing a file in FTP (File Transport Protocol or File Transfer Protocol), etc., or triggered automatically, taking into account for example a clock. In the latter case, the stall command insertion request 52 must be time stamped. The stall command generation module 411 uses one or more synchronization sources to determine the stall position in the DCP stream, i.e., to determine the stall timing information defining a time in which a secondary broadcaster can insert a secondary program into the DCP stream. More precisely, the stall command generating module 411 takes as input synchronization information 54 with respect to the digital signal generated by the encoder 52, determined taking into account the clock of the transport signal. The stall timing information transmitted to a broadcaster in a marking packet is therefore determined taking into account the time base of the transport signal. For example, it is an OCR value indicating the start time and the end time of the stall for a broadcast according to the DMB standard, or an EDI time stamp value for a broadcast according to the DAB or DAB + standards, and MDI for distribution according to the DRM standard. The stall command generation module 411 can also take into account synchronization information 53 from an external source (NTP for example). This synchronization information 53 is used by the module 411 to synchronize the stall command insertion request 52, when it is time stamped. In this case, the stalling orders are dated, that is to say the determination of the stall time information, by comparing the synchronization information 54 from the digital signal and the synchronization information 53 from the digital signal. an external source. This comparison makes it possible to convert the time stamp of the stall command insertion request 52 to the time base used in the DAB, DAB +, DRM or DMB transport signal.

The stall command generation module 411 thus makes it possible to generate one or more marking packs 55, each packet corresponding to a stall order to be transmitted to the secondary broadcasters. According to this exemplary embodiment, a marking packet comprises at least: a field carrying a unique stall command identifier, named Spl Ord ID for example, allowing the stall module 421 to know if the stalling command is at to take into account or not. The value of this field is configurable; at least one field carrying stall time information, to identify the position of the stall point, or splice point, in the DCP signal (OCR value for the DMB standard or a time stamp for the standard DAB for example). For example, this time information specifies the start date (value of the OCR equal to Vl) and the end date (value of the OCR equal to V2) of the stall. Optionally, the marking packet also includes a field carrying a stall duration. This field defines a duration before returning to the main program, that is to say a duration during which the secondary broadcaster can broadcast a secondary program before returning to the broadcast of the main program. The structure of the marking packs according to this embodiment of the invention will be described in more detail below, in connection with FIGS. 7A to 7D. In order to prevent losses of stalling during transport between the main diffuser 41 and the secondary diffusers 42 or 43, a marking packet corresponding to a stall sequence may be repeated several times before the stall point. According to a variant embodiment, once the stall start date has passed, the main broadcaster 41 may periodically send commands to the secondary diffusers 42 or 43 to force the stall. For example, according to the DMB standard, if the time information associated with a stall order specifies a stall start date corresponding to an OCR value equal to V1, the marking packet can be transmitted more than once until the OCR value of the transport signal is lower (earlier) than V l. Once this value has passed, the main broadcaster can send, possibly periodically, an order to force the stall, for example by assigning a specific value (1) to an immediate stall start request indicator (End). C) Transport of the stall sequence As indicated above, the transport of the marking pack (s) to the secondary diffusers performing the stall (splicer in English) can be done in-band, that is to say in the digital signal, using the DCP transport layer, for example, and / or out-band, by sending the marking packet (s) on a separate link, via an IP type link for example. For an in-band transmission, as illustrated by the solid line arrow 44 in FIG. 4, the stall sequence may be conveyed by a proprietary DCP tag or tag packet. This can be inserted into the DCP stream according to the broadcast standard. The use of the DCP transport layer for the transport of the stall commands avoids modifying the structure of the digital stream that will be transmitted. In addition, the use of this mode of transport makes it possible to maintain the compatibility with the equipment not managing the stall commands, since the marking packets or DCP tag not recognized by a device are automatically ignored.

For an out-band transmission, as illustrated by the dashed line arrow 45 in FIG. 4, the stall sequence may be carried out outside the DCP stream and may be transported over an IP link using the UDP protocol (User Datagram Protocol or TCP (Transport Control Protocol) for example. In order to homogenize the formats of the stall orders, the out-band transmitted marking packets advantageously have the same structure as the in-band conveyed marking packets. According to a particular embodiment of the invention, which makes it possible to ensure considerable flexibility of stalling, the in-band or out-band conveyed marking packets 30 comprise only: a stall command identifier, which can be used by the secondary diffuser to decide whether to take into account the stall sequence; an identification in the flow of the stall time range, in the form of a stall time information. Advantageously, the very configuration of the stalls, that is to say the choice of streams to pick up (audio, video, BIFS ...), can be parametered separately on each secondary diffuser that achieves the stall. Thus, the different secondary diffusers 42 and 43 can achieve a stall of different type on receipt of the same stall order. D) Operation of the equipment performing the stall A description of the operation of the secondary diffuser 42 or 43 is described below in greater detail with reference to FIG. 6. Such a secondary diffuser receives as input the DCP flux, as well as one or more marking packages. These marking packets may be received in the DCP stream 44 (in-band transmission) or in a separate stream 45 (out-band transmission). The equipment performing the stall includes several modules. A stall command extraction module 61 receives the DCP stream 44 as input. It extracts from this stream the marking packets corresponding to the stall commands, in the case of an in-band transmission. The tagging packets thus extracted are transmitted to a stall command management module 62. The stall command management module 62 may receive stall commands from the stall command retrieval module 61, in the case of an in-band transmission, or receive stall commands directly, on a stall. IP 45 connection for example, in the case of an out-band transmission. The stall command management module 62 then checks whether the stall must be taken into account, by checking the stall order identifier. If the order is valid, the module 62 searches for the local stall configuration associated with it (audio, video, BIFS, etc.), by consulting a stall configuration base 63. If the stall order received does not match is not valid, it is ignored. Here is meant by valid order (or identifier) an order which has for identifier an identifier present in the base of stall configuration 63 of the secondary diffuser. The stall command management module 62 then transmits to the stall module 64 the commands and the configuration of the valid stall commands. These commands make it possible to indicate to the stall module 64 the stalling moment, in the form of the identifier of the corresponding packet (PID to be picked up, identified from the value V1 of the OCR for example, for the DMB). the source to use for stall, etc. This known information, the module 64 derailment scans the DCP stream in search of a stall point to take into account. When the module 64 detects a stall point, it performs the stall in accordance with the configuration associated with it, replacing a main program of the DCP stream with a secondary program, and broadcasting the stream thus modified 67, according to the DCP protocol. for example. The secondary source (s) providing secondary content used for the stall can be of different natures. For example, a source can provide a real-time secondary program to broadcast. This program comes for example from a secondary stream, transmitted according to the DCP protocol for example. According to one variant, this program comes from an analog source and is encoded in an encoder 65. In these two cases, the stall module comprises a buffer memory 641 in which the secondary program is stored until it receives the stall point. . The use of this buffer 641 makes it possible to re-synchronize the beginning of the secondary program with the insertion point in the main stream. Other contents such as pre-recorded contents and stored in a memory 66, in the form of files for example, can also be used as a secondary source.

E) Structure of the marking packets With reference to FIGS. 7A to 7D, the structure of the marking packs according to a particular embodiment of the invention will now be described. As already indicated, a marking packet corresponds to a stall order, and includes sufficient data to allow the secondary diffuser to identify the stall point in the DCP stream. Fig. 7A illustrates an exemplary structure of a tagging packet according to this embodiment. According to this example, the marking packet comprises: a 32-bit field, named Tag name 71, derived from the DCP standard, and making it possible to identify the marking packet; a 32-bit field, named Tag length 72, derived from the DCP standard, and giving the length of the bit marking packet; a 32-bit field, named Spl ord ID 73, containing the unique stall order identifier on the network; an 8-bit field, named Flags 74, comprising eight indicators; an N-bit field (N integer), named Spl Pos Beg 75, containing the information needed to identify the stall start point in the DCP stream. The format of this field is related to the content to be dropped according to the broadcast standard used (for example DMB, DAB, DAB + or DRM); an N-bit field (N integer), named Spl Pos End 76, containing the information needed to identify the end-of-stall point in the DCP stream. The format of this field will be related to the content to be picked up according to the broadcast standard used (eg DMB, DAB, DAB + or DRM); an optional field of M bits (M integer), named Spl Hard 77, containing the duration of the stall. The format of this field will be related to the content to be picked up according to the broadcast standard used (eg DMB, DAB, DAB + or DRM).

The eight bits of the flags field 74 include: an indicator named Beg 741 which, if it is at 1, signals a stall start order. The stall start position is then in the Spl pos Beg field. The Spl pos Beg field must be present if this flag is used; an indicator named End 742 which, if it is at 1, indicates the end-of-stall order. The position of the end of stall is then in the field Spl pos End. The Spl pos End field must be present if this flag is used; an indicator named Dur 743 which, if it is at 1 indicates the presence of the hard field Spl used to give the duration of the stall order identified by the identifier Spl ord ID; an immediate stall start request flag named End 744 which, if set to 1, forces the switch to the secondary program; an Immediate Dropout Request Indicator named Fout 745 which, if set to 1, forces the return to the main program; an Rst flag 746 which, if it is at 1, erases all previously stored stall commands for the identifier Spl ord ID; two bits named Rfu 747, 748 not used. FIG. 7B illustrates an exemplary terrestrial DMB (or T-DMB) broadcast tag package. According to this example: the field Tag name 71 can take the value ADMB, or any other value making it possible to identify this marking packet; the Tag length 72 field can be 40, 80,120, or 160; the Spl Pos Beg 75 field is used to indicate the position of the stall start point in the DCP stream. It comprises for example 40 bits (N = 40). The 40 bits use the same time base as the DCR of the DCP stream. The 7 most significant bits therefore represent the number of complete cycles of OCR needed before the time stamp (or time stamp) of the 33 low-order bits can be taken into account to find the start point of the stall; the Spl Pos End 76 field is used to indicate the position of the stall end point in the DCP stream. It also includes 40 bits (N = 40). The 40 bits use the same time base as the DCR of the DCP stream. The 7 most significant bits therefore represent the number of complete cycles of OCR needed before the time stamp of the 33 low-order bits can be taken into account to find the end-of-stall point; the Hard Spl 77 field contains the duration of the stall before returning to the DCP stream. It comprises for example 40 bits (M = 40). The duration is therefore coded on 40 bits and uses the same time base as the OCR of the DCP stream. Thus, for diffusion according to the T-DMB standard, the identification of the stall point can be performed by comparing the OCR value of the DCP stream with the value of the Spl Pos Beg field of the marking packet.

Figure 7C illustrates an example of a broadcast tagged package according to the DRM standard. According to this example: the field Tag name 71 can take the value ADRM, or any other value making it possible to identify this marking packet; the Tag length 72 field can be 40, 96, 128 or 152; the field Spl Pos Beg 75 comprises for example 56 bits (N = 56). The 50 least significant bits are used to carry the time stamp used in the tist tag of the MDI interface to carry the DCP stream in DRM. This marker is well known to those skilled in the art, and in particular described in the document ETSI TS 102 820 supra. The value carried by this field corresponds to the stall start point; the Spl Pos End 76 field also includes 56 bits. The 50 least significant bits are used to carry the time stamp used in the MDI tilt marker to carry the DCP stream in DRM. The value carried by this field corresponds to the end of stall point; the hard Spl field 77 comprises for example 32 bits (M = 32). It gives the stall duration in milliseconds since the start of the stall. FIG. 7D finally illustrates an exemplary broadcast tag broadcast according to the DAB or DAB + standard. According to this example: the field Tag name 71 can take the value ADAB, or any other value making it possible to identify this marking packet; the Tag length 72 field can take the values 40, 104, 136, 168; the field Spl Pos Beg 75 comprises for example 64 bits (N = 64). It carries a time stamp to identify the position of the start point of stall in the DCP stream. The time stamp format is that of the EDI protocol used for transporting DAB, DAB + or DMB over IP using the DCP standard. According to this protocol, the field Spl Pos Beg 75 is decomposed of the two fields named seconds and TIST. The two fields are concatenated as follows: o the second field, on the 32 most significant bits, gives the number of seconds elapsed since January 2000 at 00:00:00; o The TIST field, on the 32 low-order bits, gives the reference in the second. The format of this field is defined in Annex B of ETSI EN 300 797; the Spl Pos End 76 field also includes 64 bits (N = 64). It contains a time stamp to identify the position of the stall end point in the DCP stream. The format of the time stamp is that of the EDI protocol, as described above; the hard Spl field 77 comprises for example 32 bits (M = 32). It gives the stall duration in milliseconds since the start of the stall.

Claims (18)

REVENDICATIONS1. A method of broadcasting a digital signal from a main broadcaster (41) to at least one secondary broadcaster (42), or re-broadcaster, in a digital radio broadcast network, said digital signal carrying at least one program main method, characterized in that said method implements the following steps, at said main diffuser (41): generating (21) at least one marking packet corresponding to a stall order, a marking packet comprising: a stall order identifier; o stall time information, defining a time during which said secondary diffuser can replace said main program by a secondary program in said digital signal; transmission (22) of said at least one marking packet and said digital signal. 2. Broadcast method according to claim 1, characterized in that said stall time information comprises at least one element belonging to the group comprising: a stall start time; a moment of end of stall; stall duration; a request to start an immediate stall; a request for an immediate stall end. 3. Broadcasting method according to claim 2, characterized in that said instants of start and / or end of stall are expressed from a clock of said digital signal. 4. Broadcasting method according to any one of claims 1 to 3, characterized in that said at least one marking packet is inserted in said digital signal prior to said transmission step. 5. Broadcasting method according to any one of claims 1 to 4, characterized in that said at least one marking packet is transmitted to said secondary diffusers via a transmission means separate from said digital signal. 6. Broadcasting method according to any one of claims 1 to 5, characterized in that said digital signal is transmitted according to the distribution protocol and DCP communication. 7. Broadcasting method according to any one of claims 1 to 6, characterized in that it comprises a step of receiving a stall order insertion request, prior to said generation step of at least a marking package. 8. Broadcasting method according to claim 7, characterized in that said insertion request carries a time stamping information, expressed taking into account an external synchronization source, and in that said method comprises a step of converting said timestamp information, in said stall time information, expressed taking into account a clock of said digital signal. 9. Broadcasting method according to any one of claims 1 to 8, characterized in that said marking packet comprises the following indicators: an indicator of presence of an element of instant start-stall type; an indicator of the presence of an element of the instant end-of-stall type; an indicator of the presence of a stall duration element; a request indicator of immediate start of stall; an immediate stall request indicator, forcing a return to the main program; an indicator erasing previously stored stall commands for a given stall command identifier. 10. Broadcasting method according to any one of claims 1 to 9, characterized in that said marking packet is transmitted periodically. 11. Computer program product downloadable from a communication network and / or recorded on a computer readable medium and / or executable by a processor, characterized in that it comprises program code instructions for the implementation of the diffusion process according to at least one of claims 1 to 10. 12. Main broadcaster (41) broadcasting a digital signal to at least one secondary broadcaster (42, 43), in a digital radio broadcast network, said digital signal carrying at least one main program, characterized in that said broadcaster main method (41) comprises: generation means (411) of at least one marking packet corresponding to a stall order, a marking packet comprising: o a stall command identifier; o stall time information, defining a time during which said secondary diffuser can replace said main program by a secondary program in said digital signal; means for transmitting said at least one marking packet and said digital signal. 13. Signal broadcast by a main broadcaster (41) to at least one secondary broadcaster (42, 43), or re-broadcaster, in a digital radio broadcasting network, characterized in that it carries at least one packet marking marking corresponding to a stall order, a marking packet comprising: o a stall order identifier; o stall time information, defining a time in which said secondary diffuser can replace a main program with a secondary program in a digital signal. 14. A method for re-broadcasting a modified signal in a digital radio broadcasting network comprising a main diffuser (42) supplying at least one secondary diffuser (43), or re-diffuser, characterized in that it sets implementing the following steps, at at least one of said secondary diffusers: reception (31) of a digital signal, carrying at least one main program, and at least one marking packet, said corresponding marking packet a stall instruction and comprising: o a stall command identifier; o stall time information, defining a time during which said secondary diffuser can replace said main program by a secondary program in said digital signal; reading (32) said marking packet; checking (33) said stall command identifier, and according to the result: o determining (34) a stall start time, from said stall time information; o replacing (35) said main program by said secondary program in said received digital signal, from said stall start time, delivering a modified signal; o broadcasting said modified signal. 25 15. Re-broadcasting method according to claim 14, characterized in that said step of determining a stall start time implements a comparison between said stall time information and a clock of said received digital signal. 16. Re-diffusion method according to any one of claims 14 and 15, characterized in that it comprises a prior step of receiving said secondary program and storage in a memory. 17. Computer program product downloadable from a communication network and / or recorded on a computer readable medium and / or executable by a processor, characterized in that it comprises program code instructions for the implementation of the re-diffusion method according to at least one of claims 14 to 16. 18. Secondary diffuser (42, 43) of a modified signal, in a digital radio broadcasting network comprising a main diffuser (41) supplying at least one secondary diffuser, characterized in that it comprises: reception means of a digital signal carrying at least one main program and at least one marking packet, said marking packet corresponding to a stall order and comprising: o a stall command identifier; o stall time information, defining a time during which said secondary diffuser can replace said main program by a secondary program in said digital signal; reading means of said marking packet; means for verifying said stall command identifier; means for determining a stall start time, from said stall time information; means for replacing said main program by said secondary program in said received digital signal, from said start-off time, delivering a modified signal; means for broadcasting said modified signal.