WO2011026998A1 - Methods for transmitting and receiving a digital signal implementing at least one multi-user relay in a cooperative network, and corresponding computer program and devices - Google Patents

Abstract

The invention relates to a method for transmitting a digital signal in the form of code words, each including information bits and detection or error correction bits, implementing at least two sources transmitting first code words to at least one receiver via a transmission channel, and implementing at least one relay device, characterized in that said device implements the following steps: receiving (21) and decoding (22) at least two of said first code words transmitted by each of said sources, respectively, said first code words being rendered with noise by the first transmission channel, outputting decoded bits; generating an estimation (23) of said first transmitted code words from the decoded bits, outputting intermediate code words; constructing (24) a so-called single code word estimated from all the sources and being representative of an estimation of the code words received from all the sources, by grouping all of said intermediary code words together, the length of which is equal to the sum of the lengths of each intermediary code word; interlacing (31) at least a portion of the bits of said single code word; encoding (25) and compressing (26) said interlaced single code word, outputting a second code word having a number of bits lower than the number of bits of said single code word; and transmitting (27) said second code word to the receiver(s).

Description

 METHODS OF TRANSMITTING AND RECEIVING A DIGITAL SIGNAL IMPLEMENTING AT LEAST ONE MULTI-USER RELAY IN A COOPERATIVE NETWORK,

 COMPUTER PROGRAM AND CORRESPONDING DEVICES

1. Field of the invention

 The field of the invention is that of the transmission of coded data in a multi-user context implementing a system comprising at least two transmitters and at least one receiver. More specifically, the invention relates to improving the quality of the transmission of such data and in particular its reliability in terms of performance of the error correction decoding in a receiver as well as the reduction of the signal processing by the set of the system.

 The invention applies in particular, but not exclusively, to the transmission of data via wireless cooperative networks, the general principle of such a network being based on cooperation established between each node of the network in order to transmit information to the recipient. .

 2. Prior Art

 These wireless or cooperative mobile networks aim to provide significant gains in terms of capacity, reliability, consumption and others. Indeed, the transmission channel of a wireless or mobile network is generally of reduced quality and variable, and leads to a relatively poor transmission reliability. Significant progress has been made in recent years in coding and modulation, especially for consumption and capacity considerations. Indeed, in a wireless network where several transmitters / receivers share the same resources (time, frequency and space) it is necessary to reduce the transmission power as much as possible.

 Since the 1970s, a technique using a relay transmission channel has been used to make the communications reliable. This technique improves the transmission efficiency. The relay can either decode the bitstream and retransmit ("Decode & Forward" in English) or amplify and retransmit the received signal ("Amplify & Forward" in English) or compress and retransmit the received signal.

Mr. Valenti and B. Zhao ("Valenti and B. Zhao, Distributed Turbo Codes: Towards the Capacity of the Relay Channel," Vehicular Technology Conference, Vol 1, pp. 322-326, Oct. 2003.) propose in particular a new coding technique called distributed turbo code ("distributed turbo code"). According to this approach, a single source transmits data to both the relay and the destination terminal. The relay decodes, interleaves and re-codes the message before relaying it to the recipient. In other words, the relay performs one of the turbo-coding steps, generally performed by the transmitter (which justifies the term "distributed turbo-code"). The recipient thus receives two coded versions of the original message and decodes them together using an iterative decoding algorithm. This technique thus achieves an improvement in gain and diversity. Similar approaches are described, for the particular case where the source number is limited to two, by DEL SER J. et al. in the article "On Combining Distributed Joint Source- Channel-Network Coding and Turbo Equalization in Multiple Access Relay", or by Christoph HAUSI et al. in the article "Joint Network-Channel Coding for the Multiple-access Relay Channel".

 More recently, it has been proposed to combine this relay technique with that called "Network Coding". This approach is described, for example, by S. Yang and R. Koetter ("S. Yang and R. Koetter," Network Coding over a Noisy Relay: a Belief Propagation Approach, "in Proc., IEEE ISIT '07, Nice, France, June 2007.). The relay decodes the two received codewords from two sources respectively and then calculates and transmits the likelihood ratio logarithm (LLR) of the modulo two bit-to-bit sum of the two codewords. Thus, the receiver has three observations: the two sources and the LLR. This solution has several faults: it is very sensitive to errors in the relay, and above all it is necessary to transmit the analog value of the LLR with sufficient precision (at least 4 bits) between the relay and the receiver for each bit of the stream emitted by the sources, which is to the detriment of network capacity. A similar approach is proposed by S. Zhang, Y. Zhu, S.-C. Liew, and K. Ben Letaief, ("Joint Design of Network Coding and Channel Decoding for Wireless Networks" in Proc.IEE WCNC '07, pp. 779-784, 1-1-15 March 2007). However, the authors studied the reduction of complexity in the relay without addressing the decoding in the receiver.

 In these different cases, the decoding remains uncomplicated, and there is no simple and effective solution in the relay that simplifies the processing in the receivers. Moreover, these techniques do not make it possible to take into account a multi-source context.

 3. Objectives of the invention

 The invention particularly aims to overcome these disadvantages of the prior art.

 More precisely, an objective of the invention, according to at least one embodiment, is to propose a technique extended to at least two sources.

 Another objective of the invention, according to at least one embodiment, is to implement an inventive processing within the relay that allows reception in a simple and effective processing in a multi-source context.

 In addition, another object of the invention is to allow a flexibility of the output flow of the relay to be able to adapt to the constraints and congestion of the communication network.

 Moreover, another object of the invention is to allow an adaptation of the level of protection against errors at the output of the relay.

A final objective of the invention, according to at least one embodiment, is to provide a technique that is simple to implement, both on transmission and on reception, and which reduces processing times and / or transmission. 4. Presentation of the invention

 The invention proposes a new solution that does not have all the disadvantages of the prior art, in the form of a method for transmitting a digital signal in the form of code words each comprising information bits. and error detection or correction bits, implementing at least two sources transmitting first code words to at least one receiver, via a transmission channel, and implementing at least one relay device, according to the invention, such a method implemented by the relay device, comprises the following steps:

 receiving and decoding at least two of said first codewords transmitted respectively by each of said sources, said first codewords being noisy by the transmission channel, delivering decoded bits;

 generating an estimate of said first transmitted code words from decoded bits outputting intermediate codewords;

 constructing an estimated code word of all the sources, said unique codeword and representative of an estimate of the codewords received from all the sources, by grouping all of said intermediate code words, whose length is equal to the sum of the lengths of each intermediate code word;

 interleaving at least a portion of the bits of said single code word;

 encoding and compressing said interleaved single codeword, providing a second codeword having a number of bits less than the number of bits of said single code word; transmitting to the at least one receiver of said second code word.

 Thus, in the transmission system, a prior transmission step may be implemented via at least two separate transmission channels associated with two separate sources, so as to increase the diversity. These channels may be distinct, for example because the sources are distinct, one of the said at least two sources implements several transmitting antennas, the relay implements several receiving antennas, or the said at least two antennas source and / or the relay comprise means for varying the transmission channel over time (for example means for applying a variable delay). Said at least two separate sources transmit both to said at least one relay device and to said at least one receiver.

 The source transmission and relay transmission stages can implement a time division (TDMA), frequency (FDMA) and / or modulation code (CDMA) multiple access technique, or any other multiple access technique, allowing to separate the different contributions in the receivers.

An essential aspect of the invention is that the relay does not independently process each code word that it receives, to re-transmit a corresponding code word (representative of the received code word, to which decoding, recoding and interleaving could be applied). At On the contrary, the relay builds a unique code word, representative of all the received code words (for example several tens, corresponding to several dozen sources) and applies an interleaving on the bits forming this single code word. This approach provides improved performance by increasing the diversity and efficiency of interleaving.

 The compression and encoding in the relay device (s), which makes it possible to benefit all the scattered sources of the coding gain of a turbo-code resulting from the use of the coder of each source in combination with the encoder of the relay.

 Furthermore, the technique according to the invention allows a flexibility of the system, the relay being able to code second codewords representative of a plurality of sources (the number of which may vary during the communication). Adding a new source to the system does not require any changes to the relay operation. Indeed, the relay realizes the construction of a single code word, whatever the type of code or the length of the source code words.

 In addition, the compression step may make it possible to meet the Shannon criterion which demonstrates that the output of the relay must be less than or equal to the capacity of the transmission channel. Indeed, due to an increase in the number of sources, the application of a compression in the relay makes it possible to respect the Shannon criterion regardless of the number of sources used.

 In addition, the approach of the invention makes it possible to implement, in the receivers, an iterative decoding, without requiring the implementation of turbo-coding in the sources.

 This approach also makes it possible to reduce coding delays, compared with conventional turbo-coding, which would be implemented in each source, and which would be incompatible with real-time applications, while simplifying the processing and the complexity of these applications. sources.

 In other words, the invention is based on a novel approach, proposing a network distribution of error correction coding, or turbo coding.

 According to a particular characteristic of the invention, said coding and compression step implements an adaptation of the output rate of said relay device according to at least one predetermined criterion.

 Said predetermined criterion takes into account at least one of the parameters belonging to the group comprising:

- the number of active sources;

 the available bandwidth;

 the quality of the channel;

 the level of error detection desired upon receipt.

Thus, the invention also makes it possible to adapt the output rate of the relay as a function, for example, of the constraints of the transmission network or of the congestion of the transmission channel used by the relay. Such a rate adaptation also makes it possible to control the level of error protection at the output of the relay in order to satisfy the desired level of error detection on reception.

 According to various embodiments, the step of interleaving at least a portion of the bits of said estimated code word of all the sources may be implemented before and / or after said coding and / or said compression.

 However, interleaving before coding and compression seems to be the most effective approach.

 The introduction of such interleaving makes it possible to improve the reception decoding performance. Indeed, the approach of the invention makes it possible to implement in the receivers an iterative decoding, based on a redundancy generated in the relays, without requiring the implementation of turbo-coding on transmission.

 According to a particular embodiment, said interleaving step implements a pseudo-random interleaving (for example of the S-random type of the English "S-random", or an ARP interleaving with quasi-regular permutation of the English "Almost Regular permutation", or alternatively a "regular dithered relative" interlacing (DRP).

 Many implementation variants can be envisaged, depending on the type of interleaving, the type of coding and compression, the number of sources and relays (which can be cascaded), the concatenation of the codes (parallel, series, or any).

 According to a particular aspect of the invention, said coding of said unique code word implements a convolutional code. In particular, the coding in the relay can use a convolutional and recursive code. Recursion makes it possible to obtain an interlace gain.

 Moreover, the invention can be implemented with many types of codes used by the sources. Said sources may notably implement a linear coding belonging to the group comprising:

 convolutional codes;

 BCH codes;

 RS codes;

 turbo-codes;

 - binary or non-binary LDPC codes;

 bulk codes

 the parity codes.

According to a first embodiment, said compression is performed before said coding. Furthermore, in this case, said compression comprises a grouping of the bits of said estimated code word of the set of sources, if necessary previously interleaved, into groups each comprising a predetermined number of said bits and the allocation to each of said groups of a bit representative of the modulo-2 sum of the bits of said group. Moreover, said predetermined number and / or the number of groups is chosen as a function of said predetermined criterion or criteria. For example, if the capacity of the transmission channel and the channel allows it, one can consider a weak compression, with for example a grouping every two bits, each group being then represented by a bit. Such compression makes it possible to apply a high level of error protection at the output of the relay.

 In addition, depending on the size of the transmission channel, the relay according to the invention makes it possible, thanks to the compression step, to obtain the best compromise between the level of error protection at the output of the relay and the possible bit rate. vis-à-vis the capacity of the canal with respect to Shannon's criterion.

 According to a second embodiment, said coding is performed before said compression.

In this case, the bits of said estimated code word of the set of sources, if necessary previously interleaved, are coded and then compressed by deleting bits according to a predetermined ratio punching.

 Moreover, said predetermined ratio is chosen as a function of said predetermined criterion or criteria. For example, if the transmission channel of the relay to the destination is congested, the output bit rate of the relay can be adjusted by deleting bits (for example deleting redundancy bits) as a function of this congestion.

 According to a particular embodiment, said compression step delivers at least one of the signaling information belonging to the group comprising:

- information representative of the type of compression performed;

 information representative of the coding performed;

 information representative of the interleaving performed;

 information representative of the order in which the compression and coding were performed;

an information representative of the number and / or the size of the groups used for compression;

 information representative of the position of the punched bits and / or the punching report.

 Thus, according to the invention, it is possible to adapt the flow rate and the level of error protection at the output of the relay. The relay informs in real time via the signaling information the receiver of the type of compression and coding performed, which enables the latter to adapt in real time the decoding according to the constraints of the transmission network.

 According to a first approach, said step of receiving and decoding in the relay implements a hard decision on the value of each of the bits received in the relay to form said intermediate codewords.

This approach is simple and quick to implement. According to a second approach, said step of receiving and decoding in one of said relay devices implements a thresholding sub-step on the value of each of the bits received in said relay device, delivering threshold data, and a sub-step of error correction of said threshold data to form said intermediate codewords.

 According to a third approach, said step of receiving and decoding in one of said relay device comprises a step of soft decoding on the soft value of each of the bits received in said relay, to form said intermediate codewords.

 In this case, said flexible decoding step can in particular implement a step of searching for a code word that minimizes the square error with respect to the soft values received.

 This provides greater efficiency than the first approach because it reduces the number of errors in the relay.

 In at least one embodiment of the invention, the method also comprises a step of assigning, in the relay, at least one of said bits of said second code words, a reliability information item.

 It is thus possible to further improve the quality of the decoding, by introducing a weighting.

 Said reliability information may in particular comprise at least one signaling bit indicating the position of at least one bit of low reliability in said second code word.

 In at least one particular embodiment, at least one first relay device receives at least one intermediate code word transmitted by a second relay device.

 In other words, it is possible to cascade relay devices. More generally, many arrangements, where appropriate variable in time and / or space, are conceivable to combine transmitters and relays so as to improve the quality of the decoding.

 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 transmission described above.

 The invention also relates to a relay device for implementing this method. Such a relay device comprises in particular:

 means for receiving and decoding at least two first code words transmitted respectively by each of said sources, said first codewords being noisy by the transmission channel;

means for generating an estimate of the transmitted code words from said decoded code words delivering intermediate codewords;

means for constructing an estimated codeword of all the sources, said word of a unique code representative of an estimate of the received code words, by grouping together all of said intermediate code words, the length of which is equal to the sum of the lengths of each intermediate code word;

 encoding and compressing means of said estimated code word of the set of sources, delivering a second codeword having a number of bits smaller than the number of bits of said single code word;

 transmission means to the one or more receivers of said second code word.

 An aspect of the invention also relates to a signal comprising signaling information belonging to the group comprising:

 information representative of the type of compression performed;

 information representative of the coding performed;

 information representative of the interleaving performed;

 information representative of the order in which the compression and coding were performed;

 information representative of the number and / or size of the groups used for compression;

 information representative of the position of the punched bits and / or the punching report.

 Such a signal may in particular represent a data stream coded according to the method described above.

 According to another aspect, the invention also relates to a method of receiving a digital signal transmitted by at least two sources to at least one receiver, in a system implementing at least one relay device.

 Such a reception method comprises, in said receiver, a step of receiving and estimating a signal comprising at least two first code words transmitted by said at least two sources, and at least one second code word transmitted by said relay device , and a first iteration implementing the following steps:

 decoding by first decoders the first received and estimated code words, delivering extrinsic information for each of said first codewords;

 constructing global extrinsic information representative of the set of sources by grouping together all of said extrinsic information, the length of which is equal to the sum of the lengths of each extrinsic information obtained by decoding each of said codewords;

 interleaving the bits of said extrinsic information, delivering a first information a priori;

from said first information a priori, decompression and decoding of said at least second code word transmitted by the relay device, by means of a module of decompression and a second decoder, said decompression and decoding steps delivering at least one second information a priori;

 de-interleaving and unbundling said second information a priori, so as to form at least second information a priori to each of said first decoders of said first estimated code words, so that said second prior information is used by said first decoders when said step of decoding said first code words is reiterated

 In addition, such a reception method can implement at least a second iteration of all of said steps to reach a predetermined convergence criterion.

 Thus, the invention implements a turbo-decoding reception, based on the general principle that the first decoders, said source decoders, and the second decoder, said relay decoder, each perform an estimation of the received signals, communicate to each other their results, then perform at least a second estimate based on these results. Thus, there is cooperation between the first decoders and the second decoder for turbo-decoding.

 Moreover, the turbo-decoding implemented by the invention takes into account a decompression step of the signal emitted by the relay.

 According to a particular aspect of the invention, said decompression step implements a preliminary step of determining a first level of compression using signaling information included in said signal.

 Many variants of implementation at the reception can also be envisaged, depending on the type of compression (for example unbundling or punching) used in the coding in the relay device.

 The invention also relates to a reception device for implementing the reception method. Such a device comprises:

 means for receiving and estimating a signal comprising at least two first code words transmitted by said at least two sources, and at least one second code word transmitted by said relay device;

 first decoders of said first estimated code words delivering extrinsic information for each of said first codewords;

 means for constructing global extrinsic information representative of the set of sources by grouping together all of said extrinsic information, the length of which is equal to the sum of the lengths of each extrinsic information obtained by decoding each of said code words ;

means for interleaving the bits of said extrinsic information, delivering a first information a priori;

a decompression module and a second decoder, said decompression steps and decoding device delivering at least a second information a priori from said first information a priori;

 means for deinterleaving and unbundling said second information a priori so as to form at least second information a priori to each of said first decoders of said first estimated code words, so that said second information a priori is used by said first decoders.

 5. List of figures

 Other characteristics and advantages of the invention will emerge more clearly on reading the following description of particular embodiments, given as simple illustrative and non-limiting examples, and the appended drawings, among which:

 Figure 1 is a first example of a transmission system implementing the method of the invention;

 Figure 2 is a simplified flowchart of the method implemented in the system of Figure 1;

FIGS. 3A and 3B reciprocally describe an embodiment of a transmission method and of a reception method according to the invention;

 FIGS. 4A and 4B illustrate another embodiment of a transmission method and a reception method according to the invention;

 FIG. 5 describes the means present in a relay device according to the invention;

FIG. 6 represents the signal emitted by the relay according to one embodiment of the invention;

 FIG. 7 illustrates an example of performances obtained with the system according to the invention;

 FIG. 8 illustrates the frame error rate (FER), and the gain obtained by means of optimized punching.

 6. Description of particular embodiments

 6.1 General

 The invention therefore proposes a new approach to the use of relay devices (or relays), to improve the quality of the transmission, while allowing a simple and efficient decoding in the receivers.

 For this, the relay or relays receive the code words (or at least some of them) produced by the sources (or at least some of them), and produce at least one additional code word according to the different received code words. These additional code words are transmitted to the receiver (or receivers), which processes all the received codewords, transmitters and relay (s) as a whole, according to iterative decoding.

The relay is therefore not limited to re-transmitting the code words that it has received, but builds a specific code word, corresponding to a grouping, in particular a concatenation, code words he received, and decoded. It therefore emits, at a given instant, a single code word, formed from the bits of the set of decoded code words, and processed globally, as regards the coding, the interleaving and / or the punching.

 In the present description, the term "code word" is a set of bits (or of real values, if it is a codeword received in a form modified by a transmission channel), comprising bits. information and error detection or correction bits.

 Furthermore, one of the features of the invention is, according to at least one embodiment, its ability to compress the additional codewords generated by the relay. This compression allows the relay to adapt naturally to any multi-source context. Indeed, thanks to the compression step, the relay is flexible and can manage an additional source in the system without any significant change in the coding mode. The compression step implemented within the relay makes it possible to respect the Shannon criterion and to control the output of the relay so that it is less than or equal to the capacity of the transmission channel used by the relay. .

 Furthermore, this transmission step may allow the relay to control the output rate depending on the constraints of the network or a possible congestion of the transmission channel. Thus, independently of a context implementing a flexible number of sources, the relay can also be able to adapt in real time to the constraints of the network.

 In addition, the invention, according to at least one embodiment, also makes it possible, thanks to the compression step, to control the level of error protection at the output of the relay.

 According to different embodiments, there may be only two or more transmitters, with one or more transmit antennas. In most cases, the relay (s) (and the receiver (s)) can therefore receive code words transmitted via separate transmission channels.

 Each relay device therefore provides redundancy code words, which make it possible to improve the decoding. These redundancy code words are formed by optionally applying interleaving to the bits of the received and decoded code words, and coding of the interleaved bits.

 According to this approach, it is realized, given the receiver, a concatenation series of codes.

 According to another embodiment, one can also implement a concatenation of parallel codes or any other. We can consider in particular the case where the relay directly decodes the information and not the coded information, then we realize, given the receiver, a parallel concatenation. It is also possible to apply any interleaving, for example pseudo-random, and if necessary variable in time (a signaling must then be provided to inform the receiver of the interleaving implemented).

The bits received are decoded (before or after interleaving) by thresholding or "hard" or "soft" way, before undergoing a new coding. Soft decoding can by example implement a search of the code word that minimizes the squared error with respect to the values received. In this case, it is possible to associate with the coded data information of confidence, or reliability. In particular, it may be a signaling bit indicating the position of at least one bit of low reliability in one of the second codewords.

In the case of a multi-source transmission system illustrated in Figure 1, implementing q sources (Si, SS _q ) with q≥2, a relay R and a receiver BS (in the implementation example , a base station). The relay receives q first code words q sources and delivers a code word to the receiver BS.

For each source S, with (i = 1, q), the information U _h of length K _t bits is encoded by a rate encoder R _t in code words x, of length N _l = K _i IR _t .

 According to the embodiments, it is of course possible to provide that the sources send several code words simultaneously, if necessary at different R rates and / or in a manner that varies over time.

 Again, in this case, adapted signaling is preferably implemented. Moreover, the code lengths may be, according to the embodiments, equal or different, just as each code word may have undergone the same coding or a different coding on transmission. This possibility implemented by the invention allows great flexibility of the entire system.

 In addition, the q sources also send q codewords to the receiver BS. The base station therefore has q + 1 codewords, which it can decode according to an iterative decoding method.

 The method implemented is illustrated in a simplified manner in FIG.

The relay receives 21 q code words corresponding to transmitted code words x, 200 previously by the q separate sources (Si, S _q ), these code words are noisy code words x _l during their transmission in the channel of transmission.

 Each of these noisy code words is decoded 22, delivering q decoded codewords, then these decoded codewords are estimated 23 delivering q intermediate codewords. This decoding can implement, according to the applications:

 a decision lasts on the value of each of the received bits to form said intermediate codewords;

 a thresholding on the value of each of the received bits, delivering thresholded data, and an error correction of said thresholded data, to form said intermediate codewords;

soft decoding on the value of each of the received bits, to form said intermediate codewords. The relay according to the invention then implements the construction 24 of a single code word estimated from the set of intermediate codewords. According to a particular embodiment, said construction can implement a parallel-serial transformation or serial concatenation delivering an estimated code word length L _n = ^ N _l .

 i = l

 This estimated code word is then coded 25 then compressed 26 or compressed 26 then coded

Delivering a second code word.

 This second codeword is finally transmitted 27 by the relay device to the recipient. Among all the possible embodiments, two particular embodiments of the corresponding transmission and reception method are presented.

 6.2 First embodiment

 6.2.1 Principle of the transmission process in the relay device

 A first embodiment of the transmission method in the relay is described in connection with FIG. Figure 2 depicted the steps of receiving and decoding messages received from each source. These steps are not shown in Figure 3A.

 From the decoded code words, an estimate 23 of the transmitted code words is generated.

(That is, an estimate is made of the codewords transmitted from the decoded code words) to form so-called intermediate codewords. These intermediate codewords are then grouped together to form a single estimated code word from all sources.

The bits of the estimated code word are then interleaved 31 delivering an interlace codeword of length L _n containing in particular redundancy in order to optimize the level of error protection of said code word.

The interlace codeword is then compressed 32, so as to reduce the number of bits that compose it. This compression can in particular result from a coding provided for this purpose and / or punching. In the embodiment represented in FIG. 3A, the compression implements a distribution of the bits of the estimated code word, in groups each comprising a predetermined number of bits J and assigns each group a bit representative of the sum modulo-2 of the J bits that constitutes it. We obtain then a compressed code word of length L _c such that:

Optionally, this compression step can implement, or take into account, a preliminary evaluation step 34 of the transmission channel, for example in terms of capacity and space. This evaluation step can thus make it possible to adapt in real time the level of compression J applied to the estimated code word.

Optionally, the compression step 32 also delivers signaling information I _s , such information making it possible, for example, to specify:

that the compression 32 is carried out before the coding 33, that it is a compression by grouping, and

 the value of J

 etc.

 This signaling information may be according to an embodiment coded and sent at the same time as said second code word.

 The compressed code word is then coded 33 and then sent to the recipient 27 according to a transmission step already described in relation to FIG. 2.

 The coding step preferably implements a convolutional and recursive code (of ratio 1, for example).

As a result, on reception, the actual flow rate related to a user i can be represented by the following equation: R _{eff i} = K _t I (N _t + L _r I q) with:

 q the number of sources used,

 Ki length of the information of the source S, (i = 1, q),

 Neither length of the code word of the source S, (i = 1, q),

L _r length of the code word at the output of the relay.

 6.2.2 Principle of turbo-decoding at the reception

 A first embodiment of the reception method corresponding to the transmission method implemented in the relay according to FIG. 3A is described with reference to FIG. 3B.

 In reception, the reception method implements two types of decoders. First decoders deliver the first q code words sent by the q sources and a second decoder delivers the information bits of the second code word transmitted by the relay (ie the bits corresponding to the concatenation of the words intermediate code, generated by the relay). These two types of decoders cooperate, that is to say that the two types of decoders communicate with each other in order to perform turbo-decoding.

 The turbo-codes, presented by C. Berrou and A. Glavieux in particular in the document

"Near Shannon limited error-correcting coding and decoding: Turbo-codes (1)," IEEE Int. Conf. on Comm. ICC 93, pp. 1064-1071, vol 2/3, May 1993, rely on the implementation of two concatenated recursive systematic convolutional codes in parallel, through non-uniform interleaving. Decoding is for example an iterative decoding with flexible inputs and soft outputs (SISO soft input soft output), using extrinsic information.

Thus, according to an embodiment shown in FIG. 3B, the first iteration of the decoding algorithm implemented by the invention is described below. Each of the noisy code words x _l corresponding to each source is decoded by one of the first decoders D _si , ... , D _sq delivering q extrinsic information.

Each of the bits of these noisy code words x ₁ is represented by a value L representing a possible transition or transformation in the transmission channel. These values can in particular correspond to the logarithm of the likelihood ratio of each bit of said noisy code words in the channel.

 Then, from said extrinsic information, an extrinsic global information representative of the set of sources is constructed by grouping together all of said extrinsic information.

 Optionally, said global extrinsic information is interleaved 38 and delivers first information a priori.

 Then, said a priori information is compressed by a compression module 39 (and / or decompression according to the required input / output direction) and delivers a second extrinsic information whose length is shorter compared to the length of said information a priori.

 The second decoder 312 then uses this global extrinsic information to decode the code word transmitted by the relay. It delivers bits corresponding to the information bits of the second codeword sent by the relay (and therefore to an estimate of all the first codewords, as determined by the relay).

 This decoding step performed by the second decoder can in particular implement a step of decoding the signaling information that has possibly been coded within the relay. Thanks to this signaling information, the second decoder can in particular determine in real time the level of compression J applied within the relay or the level of coded error protection.

 Thus the invention allows a flexible decoding according to the constraints of the transmission network, including its size.

 The second decoder 312 delivers a second information a priori. The decompression module (and / or decompression according to the required input / output direction) 39 again uses the second information a priori and the first information a priori and generates as output a third information a priori.

 Said third information a priori is then, if necessary, de-interleaved 310 then unbundled 311, that is to say divided into portions of third information a priori corresponding to each source. Said third information portions a priori are then communicated to each corresponding first decoder.

 The reception method, according to the embodiment presented in connection with FIG.

3B, then performs at least a second iteration until reaching a convergence criterion.

 6.3 Second embodiment

 6.3.1 Principle of the transmission process in the relay device

A second embodiment of the transmission method in the relay is described in connection with FIG. Figure 2 depicted the steps of receiving and decoding messages received from each source. These steps are not shown in Figure 4A. The decoded codewords are then estimated 23 and grouped together to form a single estimated codeword from all sources.

The bits of the estimated code word are then interleaved 41 delivering an interlace codeword of length L _e containing in particular redundancy in order to optimize the level of error protection of said code word.

The interleaved code word is then coded 42 in a code word y of length N _r The coding step preferably implements a convolutional and recursive code (of ratio 1, for example).

Then, in the embodiment shown in FIG. 4A, the compression 43 implements a bit deletion of the code word y according to a predetermined ratio punch P. This then gives a compressed code word of length L _p such that L _p <L _n .

 Optionally, this compression step can implement a preliminary evaluation step 44 of the transmission channel, for example in terms of capacity and space. This evaluation step can thus make it possible to adapt in real time the level of punching P applied to the estimated code word.

Optionally, the compression step 32 also delivers signaling information I _s , such information making it possible, for example, to specify:

 that the compression 32 is carried out before the coding 33,

 that it is a compression by punching, and

 the value of P,

the position of deleted bits I _pos

 etc.

 This signaling information may be according to an embodiment coded and sent at the same time as said second code word.

 The compressed code word is then sent to the recipient 27 according to a transmission step already described in relation to FIG. 2.

 6.3.2 Principle of turbo-decoding at reception

 A second embodiment of the reception method corresponding to the transmission method implemented in the relay according to FIG. 4A is described with reference to FIG. 4B.

 With respect to the first embodiment, in reception, the reception method also implements two types of decoders which perform turbo-decoding.

According to an embodiment shown in FIG. 4B, the first iteration of the decoding algorithm implemented by the invention is described below. Each of the noisy code words corresponding to each source is decoded by a decoder D _if , D _sq delivering q extrinsic information. Each of the bits of these noisy code words x _i is represented by a value L representing a possible transition or transformation in the transmission channel. These values may in particular correspond to the logarithm of the likelihood ratio of each bit of said noisy code words in the channel.

 Then, from said extrinsic information, an extrinsic global information representative of the set of sources is constructed by grouping all of said extrinsic information.

 Optionally, said global extrinsic information is interleaved 48 and provides first information a priori.

 Then, a second decoder performs a decoding 410, using said first information a priori, of the second code word transmitted by the relay previously unpitched 49.

 This decoding step performed by the second decoder can in particular implement a step of decoding the signaling information that has possibly been coded within the relay. Thanks to this signaling information, the second decoder can in particular determine in real time the punching level P applied within the relay or the position of the bits deleted during encoding in the relay.

 Thus the invention allows a flexible decoding according to the constraints of the transmission network, including its size.

 The second decoder delivers a second information a priori.

 Said second information a priori is then, if necessary, de-interleaved 310 then unbundled 311, that is to say divided into portions of second information a priori corresponding to each source. Said a priori second information portions are then communicated to each corresponding first decoder.

 The reception method, according to the embodiment presented with reference to FIG. 4B, then implements at least a second iteration until a convergence criterion is reached.

 6.4 Optimization of punching in the relay

 According to certain techniques of the documents mentioned in the preamble, punching is provided in the relay. However, this punching is applied to each code word received and processed, and not to a single code word, of great length, formed from the set of code words received.

In addition, this interleaving is regular and fixed, the relay consequently transmitting permanently the same number of bits. On the other hand, according to a particular embodiment of the invention, the relay implements non-regular punching, adapted to minimize the error rate, and the number of bits transmitted by the relay can be adjusted continuously, in particular depending on the number of sources, a requirement in terms of error rate, the desired overall rate, the optimal time allocation and / or power constraints. Thus, if we consider a number q of users and a total system throughput (that is to say the total amount of information that can be transmitted) R _eff , it is possible to optimize the temporal allocation sources and relay (s) (that is to say the amount of information transmitted by the sources and the relay) so as to obtain, in the receiver or receivers, the best efficiency.

 For this, we optimize a permeability ratio p, 0 p p \, representing the fraction of bits retained after punching (called the highest level of punching P). With the help of an "EXIT chart analysis" for example, it is possible to determine the optimal parameter that minimizes the convergence threshold.

 A similar optimization can be implemented by acting on the parameter J (embodiment of § 6.2).

If we consider, as an example, a case where all the sources emit with the same rate R _t = R _{s so} we search the couple (R _s , p) minimizing the convergence threshold. To simplify this search, we consider that R _s is selected from the set {0.5, 0.55,. . . , 0.95}. R _s is then determined by randomly punching the output of the convolutional encoder, looking for the value minimizing the convergence threshold (for values of R _s and R _e / f data, p is fixed).

 As can be seen in the example of FIG. 11, illustrating the Frame Error Rate (FER) in a system implementing the second embodiment (§ 6.3) respectively for FIG. = 20 and 100 sources (emitters) emitting in a fast fading Rayleigh channel, a significant gain is obtained by optimizing the punching according to the approach proposed above.

 The curves formed of solid markers correspond to an optimal punching and the curves formed of empty markers correspond to a fixed punching.

 These curves were obtained with:

R _eff = ql2 (l + q)

k _t = k = 96 bits

 15 iterations.

 6.5 Structure of a relay device according to the invention

 The structure of an embodiment of such a relay is illustrated in FIG. 5. It comprises means 51 for receiving the code words transmitted by the sources, and means 52 for decoding these code words, for restoring data. decoded bits. The decoding means comprise hard decision means 521, by thresholding, and possibly flexible decision means 522, associating a confidence value with the hard decision.

An intermediate approach may consist in performing an error correction on hard-coded data in the relay, to form said intermediate codewords. If the relay coding is done over the physical layer, there is no soft decision, but it is possible to improve the performance with respect to thresholding. performing a hard decoding.

 The decoded bits are then estimated by estimation means 53, and a construction module 54 makes it possible to construct from the set of q intermediate code words an estimated codeword.

 This estimated codeword is subsequently interleaved, coded and compressed according to a coding and compression module 55 comprising interleaving means 551, coding means 552 and compression means 553.

 The second code word thus obtained is then transmitted by transmission means 56 to the receiver.

 6.6 Structure of a signal according to the invention

The structure of the signal emitted by the relay according to one embodiment of the invention is presented in relation with FIG. Thus, for each second code word transmitted by the relay, the signal also comprises signaling information I _s comprising:

I _comp information representative of the type of compression performed;

- information I representative of the _cod coding performed;

information I _e representative of the interleaving performed;

information I ₀ representative of the order in which the compression and coding were performed;

 information J representative of the number and / or size of the groups used for compression;

an information I _pos representative of the position of the punched bits and / or the P punching ratio.

 6.7 Performance achieved

 Figure 7 shows an example of simulation results obtained for four particular configurations.

Here we consider that each source uses the same encoder, namely a 4-rate debit encoder 1/2 and a non-systematic convolutional code using a generator polynomial (1 + D ² , 1 + D + D ² ) with D an elementary delay. , for the two embodiments described above.

 Furthermore, within the relay if the first embodiment described above (FIG. 3A and FIG. 3B) is used, the coding uses a 4-speed rate coder 1 using a convolutional code.

 1 + D

and recursive of generator polynomial τ-. Moreover, if we use the second mode of

1 + D + D ²

embodiment described above (FIG. 4A and FIG. 4B) the coding uses a 4-speed rate coder 1

1 + D ²

using a convolutional and recursive polynomial generator code.

1 + D + D ²

For the sake of simplicity, we will call strategy A technique according to the invention implemented in the first embodiment, implementing a compression grouping (FIGS. 3A and 3B), and strategy B, the technique according to the invention implemented in the first embodiment, implementing punching compression (FIGS. 4A and 4B).

 Thus, for the strategy A, the parameter J which defines the number of bits per group of bits is chosen, such that J is equal to q the number of sources used.

Thus the length of the second code word transmitted by the relay is 2K _; . In the same way, the P ratio is chosen so that the second code word delivered by the relay is of length 2K _; .

 Thus we can express for these two strategies the flow per source output relay relay

In relation with FIG. 1, the system according to the invention implements three distinct types of connection:

 the source-recipient link;

 the source-relay link;

 the relay-recipient link.

 These different channels are assumed orthogonal, the orthogonality being obtained by means of a modulation implementing a time division multiple access (TDMA).

 Said source transmission and relay transmission stages can also implement a multiple access technique according to an interleaved distribution (IDMA), frequency (FDMA) and / or by modulation codes (CDMA), or any other multiple access technique, allowing to separate the different contributions in the receivers.

 FIG. 7 represents the results obtained for a system implementing a fast fading channel according to strategy A. We consider in particular the case where each source uses the same code on information formed of K = 96 bits, and the receiver sets implemented 15 decoding iterations.

 The curves represented and captioned represent, for a number of sources q such that q = 2, 4, 8, 16, 20, 30, 50, 100, the error rate per frame (of the English "Frame Error Rate" FER) according to the signal-to-noise ratio.

 In addition, the solid line curve entitled "no co-op. 1.5P "represents the result associated with the simulation of a system that does not implement relays, this curve being standardized in order to make it comparable to the other results.

 In addition, the results obtained according to strategy B (not shown) are very close to those obtained with Strategy A previously shown.

Claims

 A method of transmitting a digital signal in the form of code words each comprising information bits and error detection or correction bits,

implementing at least two sources transmitting first code words to at least one receiver, via a transmission channel, and implementing at least one relay device, characterized in that said relay device implements the following steps:

 receiving (21) and decoding (22) at least two of said first codewords transmitted respectively by each of said sources, said first codewords being noisy by the transmission channel, delivering decoded bits;

generating an estimate (23) of said first transmitted code words from the decoded bits, delivering intermediate codewords;

 constructing (24) an estimated codeword from the set of sources, said unique codeword and representative of an estimate of the codewords received from all the sources, by grouping together all of said words of intermediate code, the length of which is equal to the sum of the lengths of each intermediate code word;

 interleaving (31) at least a portion of the bits of said single code word;

 encoding (25) and compressing (26) said interleaved single codeword, providing a second codeword having a number of bits less than the number of bits of said single code word;

transmitting (27) to the at least one receiver of said second code word.

 2. Transmission method according to claim 1, characterized in that said coding and compression step implements an adaptation of the output rate of said relay device according to at least one predetermined criterion.

 3. Transmission method according to claim 2, characterized in that said predetermined criterion takes into account at least one of the parameters belonging to the group comprising: the number of active sources;

 the available bandwidth;

 the quality of the channel;

 the level of error detection desired upon receipt.

4. Transmission method according to any one of claims 1 to 3, characterized in that said coding of said single code word implements a convolutional code.

 5. Transmission method according to any one of claims 1 to 4, characterized in that said compression (32) is performed before said coding (33).

Transmission method according to claim 5, characterized in that said compression (32) comprises a grouping of the bits of said single code word, if necessary previously interleaved, in groups each comprising a predetermined number of said bits and the assignment to each of said groups of a bit representative of the modulo-2 sum of the bits of said group.

7. Transmission method according to any one of claims 1 to 6, characterized in that said coding (42) is performed before said compression (43).

 8. Transmission method according to claim 7, characterized in that the bits of said estimated code word of the set of sources, where appropriate previously interleaved, are encoded (42) and then compressed (43) by deleting bits according to a predetermined report punching.

9. Transmission method according to any one of claims 1 to 8, characterized in that said compression step delivers at least one of the signaling information (I _s ) belonging to the group comprising:

information (I _comp ) representative of the type of compression performed;

an information (I _cod ) representative of the coding performed;

information ( _Ie ) representative of the interleaving performed;

information (I ₀ ) representative of the order in which the compression and coding were performed;

 information (J) representative of the number and / or size of the groups used for compression;

an information _item (I _pos ) representative of the position of the punched bits and / or the punching ratio P.

 10. Method according to any one of claims 1 to 9, characterized in that said decoding step implements at least one of the techniques belonging to the group comprising:

a decision lasts on the value of each of the bits received to form said intermediate codewords;

 a thresholding on the value of each of the received bits, delivering thresholded data, and an error correction of said thresholded data, to form said intermediate codewords;

a flexible decoding on the value of each of the received bits, to form said intermediate codewords.

 11. Method according to any one of claims 1 to 10, characterized in that it comprises a step of assigning, to at least one bit of said second code words, a reliability information, said reliability information comprising at least one signaling bit indicating the position of at least one reliability bit in said second code word.

 12. Method according to any one of claims 1 to 1 1, characterized in that at least a second relay device receives at least one compressed code word transmitted by a first relay device.

13. 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 transmission method according to at least one of claims 1 to 12.

Relay device intended to be implemented in a network implementing at least two sources transmitting first code words to at least one receiver, via a transmission channel, and implementing at least one relay device, said code words each comprising information bits and error detection or correction bits,

characterized in that it comprises:

 means for receiving (51) and decoding (52) at least two first codewords respectively transmitted by each of said sources, said first codewords being noisy by the transmission channel;

 means for generating an estimate (53) of the transmitted code words from said decoded code words, delivering intermediate codewords;

 means for constructing (54) an estimated code word of the set of sources, said unique code word and representative of an estimate of the received codewords, by grouping together all of said intermediate code words, whose length is equal to the sum of the lengths of each intermediate code word;

encoding and compression means (55) of said estimated code word of all the sources, delivering a second codeword having a number of bits smaller than the number of bits of said single code word;

 transmitting means (56) to the at least one receiver of said second code word.

15. Signal comprising signaling information (I _s ) belonging to group e comprising:

information (I _comp ) representative of the type of compression performed;

information (I _cod ) representative of the coding performed;

information ( _Ie ) representative of the interleaving performed;

information (I ₀ ) representative of the order in which the compression and coding were performed;

 information (J) representative of the number and / or size of the groups used for compression;

an information _item (I _pos ) representative of the position of the punched bits and / or the punching ratio P.

16. A method for receiving a digital signal transmitted by at least two sources to at least one receiver, in a system implementing at least one relay device,

characterized in that it comprises, in said receiver, a step of receiving and estimating a signal comprising at least two first codewords transmitted by said at least two sources, and at least one second code word transmitted by said device relay,

and a first iteration implementing the following steps:

decoding by first decoders the first received and estimated code words, delivering extrinsic information for each of said first codewords; constructing (37) global extrinsic information representative of the set of sources by grouping all of said extrinsic information, the length of which is equal to the sum of the lengths of each extrinsic information obtained by decoding each of said codewords ;

interleaving (38) bits of said extrinsic information, delivering first information a priori;

 from said first information a priori, decompression and decoding of said at least second code word transmitted by the relay device, by means of a decompression module (39) and a second decoder (312), said decompression steps and decoding delivering at least a second information a priori;

 de-interleaving (310) and unbundling (311) said second information a priori, so as to form at least second information a priori to each of said first decoders of said first estimated codewords, so that said second prior information is used by said first decoders when said step of decoding said first codewords is reiterated;

and in that at least a second iteration of all of said steps is implemented, until a predetermined convergence criterion is reached.

 17. The reception method as claimed in claim 16, characterized in that said decompression step implements a preliminary step of determining a first level of compression using signaling information included in said signal.

 18. Device for receiving a digital signal transmitted by at least two sources to at least one receiver, in a system implementing at least one relay device,

characterized in that it comprises:

 means for receiving and estimating a signal comprising at least two first code words transmitted by said at least two sources, and at least one second code word transmitted by said relay device;

 first decoders of the first code words received and estimated, delivering extrinsic information for each of said first words;

 means for constructing global extrinsic information representative of the set of sources by grouping together all of said extrinsic information, the length of which is equal to the sum of the lengths of each extrinsic information obtained by decoding each of said code words ;

 means for interleaving the bits of said extrinsic information, delivering a first information a priori;

a decompression module and a second decoder, said decompression and decoding steps delivering at least one second information a priori from said first information a priori; deinterleaving and ungrouping means of said second information a priori so as to form at least second information a priori to each of said first decoders of said first estimated code words, so that said second information a priori is used by said first decoders.