FR2794268A1 - Coding procedure for binary data prior to transmission over a communications network involves turbo coding of the data and mapping which enables the data to be decoded using a Viterbi algorithm - Google Patents

Abstract

Procedure involves coding a data stream into at least two binary elements using a coder with an interlacer and a recursive systematic conventional coder (RSC). The binary elements are converted into binary words before modulation and transmission. In an intermediate association step each word is associated with a graphical representation point (mapped) with a particular distortion. When the data is received it can be decoded using a Viterbi algorithm or turbo-decoding. Independent claims are made for a transmission device, a receiver device and a receiving procedure.

Description

The present invention relates to a method and a device for transmitting information, a method and a method B> an information receiving device, and <B> to </ B> systems implementing them.

In particular, the methods and devices of the present invention provide for a particular arrangement of the data outputted by a turbo encoder, so as to allow a decoder using the algorithm to <B> to </ B>. of Viterbi to decode these data, whereas according to the prior art, data outputted by a turbo encoder require a turbo decoder to be decoded.

Recall that a conventional turbocoder consists of two recursive systematic convolutional (RSC) convolutional coders and an interleaver, arranged as shown in FIG. 1. The turbo encoder provides at the output three sequences of binary elements (x, yl, <B> y2), where x is the so-called systematic output of the turbocoder, that is to say having undergone no processing with respect to the signal input x, yl is the output coded by the first RSC encoder, and <B> y2 </ B> is the output encoded by the second RSC encoder after passing through the interleaver.

For more details on the turbocodes, we will usefully refer <B> to </ B> the article of <B> C. </ B> BERROU, <B> A. </ B> GLAVIOUS and P. THITIMAJSHIMA titled "Near Shannon limited error-correcting coding and decoding: turbo-codes", ICC '93, Geneva.

FIG. 2 represents an example of a conventional turbodecoder capable of decoding data provided by a turbocoder such as that of FIG. 1. The inputs x, yl, y2 of the turbodecoder are the outputs of the turbo encoder as received by the decoder after passing through the transmission channel, here included as ideal to facilitate the description. The structure of such a turbodecoder is known to those skilled in the art and will not be described in detail here. <B> It </ B> is clear from Figure 2 that a turbodecoder has the disadvantage of having a very complex structure.

<B> It </ B> requires in particular two decoders, denoted by "Decoder <B> 1" </ B> and "Decoder 2" in FIG. 2, for example of the BCJR type, that is to say using the algorithm of Bahl, Cocke, Jelinek and Raviv, or of the SOVA type (in English "Soft <I> Output </ I> ViterbiAlgorithm").

A conventional turbodecoder also requires a loopback of the output of the deinterleaver iz2 on the input of the first decoder, in order to transmit the so-called "extrinsic" information from the second decoder to the first decoder. The use of a transmission chain comprising a conventional turbocharger <B> to </ B> transmission and a conventional turbodecoder <B> to </ B> the reception has another disadvantage. The output bits of the turbo encoder are usually sent one after the other, in series. This generates a significant risk of errors due to confusion between the different outputs of the turbo encoder, and therefore between the different inputs of the turbodecoder.

To solve this problem, it has already been proposed to use a data mapping system ("mapping") and then to modulate the data before transmitting them, for example by means of a quadrature phase modulation of the QAIVI type (in English <I> "Quadrature Amplitude </ I> <I> Modulation") </ I> or QPSK (in English "Quatemary <I> Phase Shift </ I> Keying") .

One technique is to convert the three bit sequences (x, yl, <B> y2) </ B> output by the turbo-coder into a sequence of three-bit binary words, and <B to <B> to <B> to </ B> each of the possible binary words a point of a constellation comprising eight equitably distributed points on the same circle. The notion of constellation is well known to those skilled in the art and denotes a discrete set of points in the Fresnel space. <B> A </ B> Each point is associated with a vector from the origin <B> to </ B> that point. This vector is modulated by the amplitude of the signal and for phase that of the signal <B>; </ B> each of these points represents a phase and an amplitude. If for example the modulation used is an 8-PSK modulation, the constellation has <B> 8 </ B> points. Such a symmetrical classical constellation is shown in the figure <B> M. </ B>

The axis <B> 1 </ B> (for "in-Phase" in English) is the real axis of the complex plane and the axis <B> Q </ B> (for <I> "Quadrature" < / I> in English) is the imaginary axis. The constellation of the figure <B> 3A </ B> is said to be symmetrical in the sense that all the points of the constellation are evenly spaced on the circle which carries them, so that the radius coming from a point of the constellation forms a equal angle <B> to </ B> 7Z / 4 with the radius coming from the next point on the circle. In Figure <B> 3A, </ B> the encoding used to allocate a three-bit binary <B> to </ B> a point in the constellation is a Gray encoding, that is, that two neighboring points on the circle only differ by a single bit.

When seeking to simplify the structure of the decoder by replacing the turbodecoder with a conventional Viterbi decoder, a symmetrical constellation such as that of Figure 3A is not suitable. Indeed, to make a Viterbi decoder compatible with a turbocharger associated with a mapping system as described above, one seeks to recover correctly, on the one hand , the so-called systematic output x of the turbocharger, and on the other hand, another output of the turbo encoder, that is to say either yl or <B> y2. </ B> If for example we choose to correctly recover x and yl, the output <B> y2 </ B> is not used, and so we try to <B> to further protect the bits of the binary words that correspond <B> to </ B> x and yl that the bit of the binary words that matches <B> to y2. </ B>

The object of the present invention is to provide a solution to the problems set out above by proposing a type of constellation said to be distorted, that is to say an invariant constellation by rotation of an angle multiple of 7r, unlike <B> to a classical constellation as described previously, invariant by rotation of an angle multiple of n / 4.

Furthermore, in the case where a QAM or PSK type modulation is not used, but a frequency modulation of the FSK (Frequency <I> Shift </ I> Keyine ') type, the present invention also proposes a distorted graphic representation in the allocated frequency band.

For this purpose, the present invention proposes an information transmission method, according to which <B>: </ B> <B> - </ B> an encoding operation is carried out, using an encoder comprising at least one interleaver and at least one systematic recursive convolutional coder, this coding operation consisting in coding an information data stream in at least two bit sequences <B> - </ B> a conversion operation, consisting of converting these bit sequences to a sequence of binary words, which method is remarkable in that an association operation is performed, consisting of <B> to </ B> associating each binary word obtained previously, by mapping report, <B> to </ B> a point of a graphical representation having a particular distortion, in a specific space <B>; < / B> and <B> - </ B> we perform a send operation, consisting of <B> to </ B> issue these points. During the coding operation, one can for example code the data stream <B> to </ B> using a turbo-coder, so as <B> to </ B> obtain at the output of the turbocharger three bit sequences <B>; </ B> during the conversion operation, all three are converted. sequences of bits obtained at the output of the turbocoder in a sequence of three-bit binary words.

Prior to the transmitting operation, it is possible to perform a transposed band modulation operation, consisting in that each point of the graphical representation to which a binary word is associated modulates a carrier and in that the repetition of this operation provides a modulated symbol sequence <B>; </ B> the transmission operation then consists in sending this sequence of modulated symbols.

In a particular application, the aforementioned specific space is the Fresnel plane, the aforementioned distorted graphic representation is a distorted constellation and the association operation consists of associating each binary word <B> with <B> / B> a point of this distorted constellation. In another particular application, the aforementioned specific space is the frequency space, the aforementioned distorted graphic representation is a distorted frequency representation and the association operation consists of associating each binary word <B> at </ B> a predetermined frequency among a plurality of frequencies, these frequencies not being equidistributed in the allocated frequency band.

Thus, thanks to the use of a constellation which is not symmetrical, but distorted, or the use of a frequency representation as briefly described above, the invention makes it possible to decode with a Viterbi decoder conventional a stream of data that has been turbocharged, while providing greater protection to bits useful for decoding than bits that are not used for decoding. Decoding is simplified while maintaining a satisfactory quality, both for Viterbi decoding and for turbodecoding.

According to a particular characteristic, <B> to </ B> the result of the conversion operation, the most significant bit of the binary word represents the systematic output of the turbo encoder, the intermediate weight bit of the binary word represents the output encoded by the first encoder included in the turbo encoder and the least significant bit of the binary word represents the output coded by the second encoder included in the turbo encoder after passing through the interleaver included in the turbo encoder. According to a particular characteristic, during the association operation, a QAM or PSK type quadrature modulation can be used, in the case of the use of a graphical rep resentation consisting of a constellation, or a modulation of frequency of FSK type in the case of the use of a frequency representation.

The present invention is also likely to apply in the case where a D-PSK type modulation is used (in English "Differential <I> Phase </ I> <I> Shift </ I> Keying") According to a particular characteristic , the distorted constellation is constructed <B> to </ B> from a symmetric constellation <B> to </ B> eight points, in which <B> - </ B> we divide all eight points into two groups of four points symmetrical relative to one another in a first axis of symmetry, so that in each of the two groups, the most significant bit of the binary words associated with constellation points in this group be the same <B>; </ B> and divide each group of four points into two subgroups of two symmetrical points one-to-relative <B> to </ B> the other according to a second axis of symmetry, so that in each of the subgroups, the intermediate-weight bit of the binary words associated with the points of the constella located in this subgroup is the same.

Thus, the binary words associated with points in the same subgroup differ only in the least significant bit.

Such a distorted constellation makes it easier to decode, by grouping together in the same area the binary words which correspond to the same value of two outputs of the turbo-coder. In the application to distorted frequency representations, according to a particular characteristic, during the association operation, <B> to </ B> from a set of eight equidistributed frequencies in the allocated frequency band, <B > - </ B> we divide all of these eight frequencies into two bands of four frequencies arranged symmetrically with respect to each other according to the median frequency fo of the band of frequency allocated, so that in each of the two aforementioned bands, the most significant bit of the binary words associated with the frequencies in the band under consideration is the same <B>; </ B> and <B> - </ B > each band of four frequencies is divided into two sub-bands of two frequencies arranged symmetrically with respect to each other according to two symmetrical frequencies fo + fb and <B> fo - < Fb, fb being a predetermined frequency, so that in each of the subbands, the intermediate weight bit of the binary words associated with the frequencies in the sub-band under consideration is the same. Thus, the binary words associated with the points situated in the same subband differ only by the least significant bit.

Such a distorted frequency representation makes it possible to facilitate decoding by grouping in the same area the binary words that correspond to the same value of two outputs of the turbo-coder.

For the same purpose as that indicated above, the present invention also proposes a method of receiving information, which is remarkable in that it comprises in particular: <B> - </ B> a reception operation, consisting of <B receiving symbols from an emitter, this emitter using a turbo encoder and implementing an information issuing method as succinctly set forth above, and <B> - </ B> a decoding operation, either according to the Viterbi algorithm or according to a turbodecoding algorithm.

<B> A </ B> the reception, in the application to the distorted constellations, according to a particular characteristic, a decoding operation is carried out according to the Viterbi algorithm <B>; </ B> the method being remarkable in that that, between the reception and decoding operations <B>: </ B> <B> - </ B>, a distance calculation operation is performed, consisting of <B> calculating the Euclidean distance between each received symbol and the main points of a constellation in which the received symbol is located, the decoding operation being based on the previously calculated Euclidean distances.

The main points of a constellation, of which there are four, are defined as being the points corresponding to the different possible bitwords obtained with the so-called bits of interest, that is to say for example the corresponding bit <B> at the so-called systematic output of the turbo encoder and the corresponding bit at the output of the turbocoder designated by yl in Figure 1. <B> 1. </ B>

As a variant, a decoding operation is carried out according to a turbodecoding algorithm, the method being remarkable in that, between the reception and decoding operations: <B>: </ B> <B> - </ B> for each symbol received, an estimation operation of a first bit element from a first output of the turbocode is carried out, r, <B> to </ B> from the value of the real part of the received symbol, an estimation operation of a second binary element <B> '</ B> from a second output of the turbo encoder, <B> to </ B> from the value of the imaginary part of the received symbol , and an operation of estimating a third bit from a third output of the turbo encoder, from the value of the projection of the received symbol on an axis that separates the two regions of Voronoi. quadrant of a distorted constellation in which the received symbol is located.

It is recalled that the Voronoi regions of a constellation are planes delimited by the symmetry axes of the constellation, and that they define the decision regions for the reception <B>: </ B> we estimate a point received by the point of the closest constellation, for example in the sense of the Euclidean distance, which amounts to estimating by a given point of the constellation all the points received which are in the same region of Voronoi as this point of the constellation.

<B> A </ B> the reception, in the application to the distorted frequency representations, according to a particular characteristic, <B> - </ B> a decoding operation is carried out according to the Viterbi algorithm <B>; < / B> the method being remarkable in that, between the reception and decoding operations <B>: </ B> <B> - </ B> a frequency difference calculation operation is carried out, consisting of <B> calculating the difference between the frequency of each received symbol and the center frequencies of a plurality of specific frequency subbands, the decoding operation being based on the previously calculated frequency differences. As a variant, a decoding operation is carried out according to a turbodecoding algorithm, the method being remarkable in that, between the reception and decoding operations <B>: - <B> - </ B> <B> For each symbol received, an operation is carried out for estimating a first bit from a first output of the turbo encoder, from the difference between the frequency of the symbol received and the median frequency fo of the allocated frequency band, an operation of estimating a second bit from a second output of the turbo encoder, from the difference between the frequency of the symbol received and the center frequency of one of two frequency bands deduced from the operation of estimating the first bit, and an operation of estimating a third bit from a third output of the turbocharger, B> to </ B> from the difference between the frequency of the received symbol and the center frequency of one of four frequency subbands, derived from estimation operations of the first and second bits. If, during the reception operation, transposed band modulated symbols are received from the transmitter, <B> to </ B> is carried out following said reception operation, an operation of demodulation, consisting of demodulating the received modulated symbols.

Thus, the invention makes it possible to use either, during the decoding, either a Viterbi decoder or a turbodecoder, compatibility being ensured in both cases with the turbo encoder included in the transmission system. The present invention further proposes an information transmission device, comprising: a coding module, comprising at least one interleaver and at least one systematic recursive convolutional coder , for encoding an information data stream into at least two bit sequences <B>; </ B> <B> - </ B> a conversion module, for converting these bit sequences to a following binary words <B>; </ B> the device is remarkable in that it also includes <B>: </ B> <B> - </ B> an association module, to associate each word binary provided by the conversion module, by mapping report, <B> to </ B> a point of a graphic representation with a particular distortion, in a specific space <B>; </ B> and <B> 1 </ B> - </ B> a broadcast module, to issue these points.

According to one particular characteristic, the association module merges, according to the enviaged application, either the coordinates of the points of the distorted constellation, or the values of the frequencies of the plurality of non-equidistributed frequencies in the allocated frequency band.

The present invention further provides an information receiving device, remarkable in that it comprises in particular: a receiving module, for receiving symbols from of an emitter, this emitter using a turbo encoder and comprising an information transmission device as succinctly explained above, and a decoding module, either indifferently or a Viterbi decoder. , a turbodecoder.

The present invention also relates to a digital signal processing apparatus, comprising means adapted to implement an information transmission method as succinctly described above.

The present invention also provides a digital signal processing apparatus, comprising means adapted to implement a method of receiving information as succinctly set forth above.

The present invention also relates to a digital signal processing apparatus, comprising an information transmission device as succinctly explained above.

The present invention also relates to a digital signal processing apparatus, comprising an information receiving device as briefly described above. The present invention also relates to a telecommunications network, comprising means adapted to implement an information transmission method as succinctly set forth above. </ B> The present invention also relates to a telecommunications network, comprising means adapted to implement a method of receiving information as succinctly set forth above.

The present invention also relates to a telecommunications network, comprising an information transmission device as succinctly set forth above.

The present invention also relates to a telecommunications network, comprising an information receiving device as briefly described above.

The present invention also relates to a mobile station in a telecommunications network, comprising means adapted to implement an information transmission method as briefly described above. The present invention also relates to a mobile station in a telecommunications network, comprising means adapted to implement a method of receiving information as succinctly set forth above.

The present invention also relates to a mobile station in a telecommunications network, comprising an information transmission device as succinctly described above.

The present invention also relates to a mobile station in a telecommunications network, comprising an information receiving device as briefly described above.

The invention also aims at: computer-readable information storage means or a microprocessor holding instructions of a computer program, enabling the implementation of the method of the invention as succinctly set forth above, and <B> - </ B> removable, partially <B> or <B> or </ B> fully removable information storage means readable by a computer or microprocessor retaining instructions from a computer program, allowing the implementation of the method of the invention as succinctly set forth above.

Other particular features and advantages of the reception method, the transmitting device, the receiving device, the various digital signal processing apparatus, the different telecommunications networks, the different mobile stations and the information storage means being the same as those of the emission process according to the invention, these particular characteristics and advantages are not recalled here. Other aspects and advantages of the invention will appear on reading the following detailed description of particular embodiments given as non-limiting examples. The description refers to the accompanying drawings, in which <B>: </ B> <B> - </ B> Figure <B> 1, already </ B> described, schematically represents the structure of A conventional turbocharger <B>; </ B> <B> - </ B> Figure 2, <B> already </ B> described, schematically represents the structure of a conventional turbodecoder <B>; <B> - </ B> Figure <B> 3A, already </ B> described, represents a classical symmetrical <B> 8-point </ B> constellation used in the context of a modulation. PSK <B>; </ B> <B> - </ B> Figure 3B is a graphical representation of a conventional frequency band used as part of an FSK <B> type modulation; </ B> <B> - </ B> Figure 4A is a flow chart showing successive steps of the information transmission method of the invention <B>; </ B> - </ B> - Figure 4B is a flowchart representing successive steps of the information transmission method of the invention, in a particular embodiment of where the information data <B> is coded using a turbo encoder and a transposed band modulation operation is performed prior to the <B> transmission <B> , <B> - </ B> Figure <B> 5 </ B> is a flowchart showing successive steps of the information receiving method of the invention, in a first particular embodiment where the aforesaid graphic representation is a distorted constellation and where it is decided to decode the received data by means of a decoder using the Viterbi algorithm; <B> - </ B> the figure <B> 6 </ B> is a flow chart showing successive steps of the receiving method of the invention, in a second particular embodiment where it is chosen to decode the received data by means of a turbo-decoder; <B> - </ B> Figure <B> 7A </ B> represents a distorted constellation <B> at 8 </ B> points used by the method and device of the invention, as part of a 8-PSK modulation; <B> - </ B> Figure <B> 7B </ B> is a distorted graphic representation of a frequency band used by the method and device of the invention, in the context of a modulation of FSK type; <B> - </ B> Figure <B> 8 </ B> is a schematic representation of an information transmission device according to the invention, in a particular embodiment <B>; </ B> <B> - </ B> Figure <B> 9 </ B> is a schematic representation of an information receiving device according to the invention, in a first particular embodiment where the graphic representation mentioned above is a distorted constellation and where the decoder chosen is a Viterbi decoder <B>; </ B> <-> </ B> <B> 10 </ B> is a schematic representation. of an information receiving device according to the invention, in a second particular embodiment where the chosen decoder is a turbo-decoder, <B> - </ B> the figure <B> 11 </ B> is a view simplified schematic of a telecommunication network without <B> wire, </ B> for example of the type compliant <B> to </ B> the DECT standard (enhanced digital wireless communications, in English <I> "Digital < / I> Enhanced Cordless Head <I> communications "), </ I> capable of implementing the invention <B>; </ B> <B> - </ B> - Figure 12 is a schematic representation of a peripheral station of a network such as that of the figure <B> 11, </ B> used for the transmission and capable of implementing the invention <B>; </ B> and the figure < B> 13 </ B> is a schematic representation of a peripheral station of a network such as the one of the figure <B> 11, </ B> used for reception and capable of implementing the invention . FIG. 4A illustrates the succession of the main steps of the information transmission method of the invention. First of all, during a step <B> 10, </ B>, we proceed to code the flow of information data <B> to </ B> transmit, so <B> to </ B> > obtain at the output of the encoder used at least two sequences of binary elements. Any suitable coding technique involving at least one interleaver and at least one systematic recursive convolutional coder may be employed here. 4B, a particular embodiment where the coding technique employed is turbo-coding, a turbo-coder outputting three sequences of bits. Then, during a step 12, the resultant bit sequences <B> are converted to the result of the encoding operation into a single sequence of binary words, each binary word consisting of as many bits as were obtained from bit sequences <B> to </ B> step <B> 10. </ B> It is described later, <B> to </ B> using Figure 4B, the way we proceed <B> to </ B> this conversion when each binary word consists of three bits. <B> A </ B> the next step 14, we proceed <B> to </ B> an operation of association, also called mapping operation (in English "mapping"), that is to say say that we associate each binary word obtained previously <B> to </ B> a point of a graphical representation having a particular distortion, in a specific space. In a first particular embodiment, this specific space is the complex plane or Fresnel plane, and the distorted graphic representation in question is a distorted constellation used in the context of a QAM or PSK type modulation, described in detail below. <B> to </ B> using the figure <B> 7A, </ B> in the case of a PSK <B> to </ B> eight states. In a second particular embodiment, it is possible to use a frequency modulation of the FSK type. In this case, the specific space is the frequency space, in which the different frequencies to which the binary words are associated are not equidistributed in the allocated frequency band, but grouped in a particular way, whence the aforementioned distortion, such as it is described in detail later <B> to </ B> using the figure <B> 7B, </ B> in the case of an FSK <B> modulation at </ b> eight frequencies. Finally, <B> at </ B> the step <B> 18, <B> is <B> </ B> the transmission, on a transmission channel, points obtained in the specific space supra. In a transmission device 220 such as that illustrated in FIG. 12, described in detail below, steps 12, 14 and <B> 18 </ B> consist, for a unit <B> 1 </ B> of calculation <B> 260, to </ B> read <B> 280 </ B> input data <I> "data </ I> 1-in" which <B> y </ B > have been loaded <B> to </ B> from a data source 200, <B> to </ b> treat them according to <B> to </ B> the corresponding sequence of instructions contained in a program <B> - </ B> "Pe" stored in a read-only memory <B> 300, </ B> and <B> to </ b> store the data obtained "datal-out" in the RAM <B> 280. </ B> FIG. 4B illustrates the succession of the main steps of the information transmission method of the invention, in a particular embodiment in which, on the one hand, the information data flow is coded. <B> to </ B> using a turbo encoder and where, on the other hand, previously <B> to </ B> the issuing operation, one proceeds <B> to </ B> a modulation in ba According to a first variant, it is possible to encode the data stream <B> using a turbo encoder, without however performing a transposed band modulation operation. According to a second variant, it would be possible to perform a transposed band modulation operation, without however having coded the data stream <B> to </ B> using a turbo-coder. As shown in FIG. 4B, during step <B> 10, </ B> is coded for the data <B> to be transmitted, <B> to </ B> using the a conventional turbocharger, yielding <B> 1/3, </ B> as described above <B> to </ B> using Figure <B> 1. </ b> The turbocharger provides output three bit sequences (x, yl, <B> y2), where x is the systematic output of the turbo encoder, where y1 is the output of the turbo encoder from the first RSC encoder, and <b> y2 </ B> being the output of the turbocoder from the second RSC encoder after passing through the interleaver. In the transmission device 220 of FIG. 12, the three bit sequences (x, yl, <B> y2) </ B> are temporarily stored in the RAM <B> 280. </ B>

Then <B> to </ B> step 12, converting the three bit sequences (x, yl, <B> y2) </ B> obtained at the output of the turbo encoder into a sequence of binary words of three bits, in which the MSB (Most Significant <I> Bit) </ I> represents x, the intermediate weight bit (the middle bit of the binary word) represents yl and the bit Least Significant Weight (LSB) </ I> stands for <B> y2. </ B>

<B> A </ B> the following step 14, we proceed <B> to </ B> the mapping report operation, that is to say we associate each binary word obtained previously, < B> at </ B> a point in a distorted constellation used as part of a QAM or PSK type of modulation, ie <B> at </ B> a frequency of a distorted frequency band used in the frame frequency modulation type FSK, depending on the intended application.

In the embodiment of FIG. 4B, <B> at </ B> step <B> 16, </ B>, a transposed band modulation is furthermore carried out. that is, each point of the distorted graphical representation obtained at step 14 modulates a carrier according to a predetermined transposed band modulation, the repetition of this operation providing a modulated symbol sequence. This step <B> 16 </ B> is optional.

Finally, <B> at </ B> step <B> 18, </ B> you emit the modulated symbols.

We now describe <B> to </ B> using Figure <B> 7A </ B> how to obtain a distorted constellation used <B> at </ B> step 14 of the process which has just been described, <B> to </ B> from a symmetrical classical constellation of the type described above <B> to </ B> using the figure <B> M. </ B> In the non-limiting example described, the considered constellations have <B> 8 </ B> points. We start by dividing all of these <B> 8 </ B> points into two groups of 4 points arranged symmetrically with respect to <B> to </ B> the other along the imaginary axis < B> Q </ B> of the complex plane.

Within each of these two groups, the most significant bit x is the same, ie, for example, a logical 'T' in the half-plane located <B> to the left </ B> of the axis. <B> Q, </ B> and a logical <B> "0" </ B> in the half plane <B> to </ B> right of the <B> Q. </ B> axis The angle <B> 0 </ B> is defined as the angle between the neighboring rays located on either side of the axis <B> Q. </ B> The distortion or distortion of the constellation consisting of <B> to </ B> increase the value of the angle <B> 0 </ B> to lower the bit error rate (BER, in English <I> "Bit </ I> Error <I > Rate ") </ I> on the recognition of the most significant bit x when receiving. However, if we limit ourselves to this single distortion, the reduction of BER on x would be to the detriment of the reception quality of the other two bits. This is why we proceed <B> to </ B> another deformation. We divide each group of 4 points into two subgroups of 2 points arranged symmetrically with respect to each other along the real axis of <B> 1, </ B> of so that within each of the subgroups the intermediate weight bit y1 is the same, i.e., for example, a logical <B> 'T' </ B> in the half plane above the <B> 1 </ B> axis and a logical <B> 'V' </ B> in the half-plane below the <B> 1 axis. </ B> The angle # is defined as the angle between the neighboring rays located on either side of the axis <B> 1. </ B> The deformation consisting of <B> to </ B> increases the value of the angle dc makes it possible to improve the reception quality of the yl bit by lowering the corresponding BER. The angle (p) is defined in the same way as the angle between two neighboring radii in the same quadrant, in which the -binary words differ only in the least significant bit.The distorted constellation thus obtained presents Voronoi regions of unequal surfaces, <B> to </ B> the difference of the classical symmetrical constellations where they are of identical surface.This distorted constellation makes it possible to confer a better protection to the first two bits x and yl, and thus, d obtain better detection of these bits during reception.

We now describe <B> to </ B> using the <B> 7B </ B> scheme for obtaining a distorted representation of the allocated frequency band used <B> to </ B> step 14 of the method described above, from a representation of the conventional frequency band of the type of that of Figure 3B. In the nonlimiting example described, we use <B> 8 </ B> frequencies in the band. In the conventional representation of FIG. 3B, the horizontal axis represents the frequencies. All frequencies <B> fi, f8 </ B> are regularly spaced along the axis, so that <B> f2 - fi = </ B> f3 <B> - f2 = </ B> f4 <B> - </ B> f3 <B≥ </ B> f5 <B> - </ B> f4 <B≥ f6 - </ B> f5 <B≥ </ B> f7-- <B> f6 </ B > <B> f8 - </ B> f7 <B≥ </ B> Af. The frequency fo designates the median frequency.

In Figure 3B, the coding used to allocate a three-bit binary word to a frequency of the band is a Gray coding.

To obtain from this classical representation a distorted representation as used in the present invention, one begins by dividing all the <B> 8 </ B> frequencies <B> fi,. .., f8 </ B> in two bands of 4 frequencies arranged symmetrically one pa ratio <B> to </ B> the other according to the median frequency fo.

Within each of these two bands, the most significant bit x is the same, ie, for example, a logical <B> "V '</ B> in the band <B> to </ B> left of the median frequency, and a logical <B> 'V' </ B> in the right <B> to </ B> band of the median frequency.The difference in frequency AfI is defined as the difference between the neighboring frequencies located on either side of the median frequency.The distortion or distortion of the frequency space consisting of <B> to </ B> increase the value of the difference AfI makes it possible to lower the error rate binary on the recognition of the most significant bit x when receiving.

In the same way as in the application to distorted constellations, we do not limit ourselves to this single modification. We proceed <B> to </ B> another distortion. Each band of 4 frequencies is divided into two sub-bands of 2 frequencies arranged symmetrically with respect to each other according to the two symmetrical frequencies fo <B> + fi, </ B > and fo <B> - </ B> fb, fb being a predetermined frequency, so that within each of the subbands the intermediate weight bit y1 is the same, i.e., for example, a logical <B> I "</ B> for frequencies close to the median frequency fo and a logical <B> 'V' </ B> for outward frequencies. difference in frequency Af2 as being the difference between the neighboring frequencies situated on either side of the frequencies fo <B> + </ B> fb and fo <B> - </ B> fb. </ B> increasing the value of the difference Af2 makes it possible to improve the reception quality of the yl bit by lowering the corresponding BER It is likewise defined the difference in frequency Af3 as being the difference between the frequencies within the same sub-band, within which the associated binary words differ only in the least significant bit. So, we have <B>: </ B> f2 <B> - fi = </ B> f4 <B> - fi =% - </ B> 4 <B≥ f8 - </ B> f7 <B≥ </ B> Af3 f3 <B> - </ B> f2 <B≥ </ B> f7 <B> - f6 = </ B> Af2 f5 <B> - </ B> f4 <B≥ </ B > Af <B> 1 </ B> and Af3 <B> </ B> Af2 <B> </ B> AfI. It is ascertained beforehand that the choice of the frequencies <B> fi, .... f8 </ B> does not result in <B> at </ B> a set of frequencies presenting between them relations of multiplicity.

FIG. <B> 5 </ B> illustrates the main steps of the reception method of the invention, in a first particular embodiment where it is chosen to decode the received data <B> to </ B> using a simple Viterbi decoder.

<B> A </ B> In step 20, the symbols possibly modulated in transposed band transmitted by the transmitter are received. If a transposed band modulation has been performed during transmission <B> to </ B>, then a step 22 consists of demodulating the received symbols.

In the particular application to distorted constellations, the next step 24 is to compute the Euclidean distance between each received symbol and the main points of the constellation, four in number for the constellation considered <B> at 8 </ B> points, which corresponds to <B> at </ B> a classical <B> at 4 points (QPSK) constellation, where two adjacent rays that carry these points have an angle of n / 2. This makes it possible to take into account only the two bits of interest x and yl of the binary words.

Finally, the next step <B> 26 </ B> consists of <B> to </ B> perform a conventional decoding according to the Viterbi algorithm, known to those skilled in the art and therefore not detailed here. This decoding is based on the calculated Euclidean distances <B> to </ B> in step 24 to estimate the sequence actually transmitted. In the particular application to distorted frequency representations, in the case of the use of an FSK-type frequency modulation, step 24 consists of calculating the differences between the frequencies of the received symbols. B> at </ B> step 20 - and the center frequencies of the 4 frequency sub-bands in which the value of the two most significant bits remains constant. Finally, in this application, the following step <B> 26 </ B> consists of <B> to </ B> perform a conventional decoding according to the Viterbi algorithm, known to those skilled in the art and therefore not detailed. right here. This decoding is based on the frequency differences calculated in step 24 to estimate the sequence actually transmitted.

In a receiving device <B> 700 </ B> such as that illustrated in FIG. 13, described in detail later, steps 20, 22, 24 and <B> 26 </ B> > consist, for the calculation unit <B> 260, to </ b> read in the RAM <B> 280 </ B> the data "data2 <I> in" </ I> received from the transmitter after passing through a transmission channel, <B> to </ B> process these data according to <B> to </ B> the corresponding instruction sequence contained in a program "PrV" memorized in the read-only memory <B > 300, </ B> and <B> to </ B> store the data obtained "data2 <I> out" </ I> in RAM <B> 280. </ B>

FIG. 6 illustrates a second particular embodiment of the succession of steps of the reception method of the invention, in the case where one chooses to decode the data by means of a turbodecoder. This situation can occur, for example, in a non-<B> wire </ B> type telecommunications network using the DECT standard, in cases where the distance between the transmitter and the receiver is relatively large, for example if a server is remote from a personal computer (PC, Personai Computee), in which case the use of turbocodes <B> at </ B> is justified. , the personal printer is usually located near the PC, in which case the extra cost of the turbodecoder is prohibitive compared to its efficiency.

As shown in Figure 6, when using a turbo-coder to receive data, the symbols are first received (step <B> 28). , </ B> then demodulated (step <B> 30) </ B> if, at the time of transmission, a transposed band modulation was performed.

Each received symbol that is represented by a point of the complex plane in the particular application to the distorted constellations serves to estimate the transmitted bits. Bits are considered by the receiver as <B> -1 </ B> or <B> +1 </ B> instead of <B> 0 </ B> and <B> 1, </ B> respectively .

<B> A </ B> step <B> 32, </ B> it is estimated the systematic output x thanks to <B> to </ B> the real part of the point representing the received symbol.

<B> A </ B> step 34, we are, ime the output of the first coder yl thanks to <B> to </ B> the imaginary part of the point representing the received symbol.

<B> A </ B> step <B> 36, </ B> we estimate the output of the second encoder <B> y2 </ B> using the quadrant delimited during steps <B> 32 </ B > and 34, projecting the point representing the symbol received on the axis that separates the two regions of Voronoi from the quadrant considered.

In the receiving device <B> 700 </ B> of Figure <B> 13, </ B> the estimates of the outputs x, yl, <B> y2 </ B> are temporarily stored in the RAM < B> 280. </ B>

Each of the previous estimates is further weighted by a normalization coefficient taking into account the point of the initially transmitted constellation. For example, if one chooses the following values for the angles of distortion defined above <B>: 0 = </ B> n / 2, <B> a = </ B> n / 4, (p 7z / 8, then the binary word <B> "011 </ B> is represented by the point cos (a / 2) <B> + j </ B> sin x / 2) cos (n / 8) <B> + j < / B> sin (7r / 8).

In this case, the systematic output x is estimated as being the real part of the corresponding point, weighted by the coefficient -1 / cos (7z [8]. The negative sign makes it possible to recover the coherence between the sign of the real part and the value of the bit before processing (a positive real part must correspond to an equal bit <B> to 0 </ B> and a negative real part, <B> to </ B> an equal bit <B> to 1). </ B>

Similarly, the output of the first RSC encoder y1 is estimated to be the imaginary part of the corresponding point, weighted by the coefficient 1 / sin (7r / 8). This time, the weighting coefficient is positive (a positive imaginary part must match <B> to </ B> an equal bit <B> to 1 </ B> and a negative imaginary part must match <B> to </ B > an equal bit <B> to 0). </ B>

The output of the second RSC encoder <B> y2 </ B> is estimated as the projection of the corresponding point on the bisector of the rays which carry the two points differing only by the least significant bit, that is to say here we say the bisector of the rays bearing the points "Ollu and <B>" M ". </ B> This estimate is weighted by the coefficient 1 / cos (n / 16), where n / 16 is the value of the angle between the radius bearing the point <B> "0 11" </ B> and the bisector that has just been described The above normalization coefficients are the same for the points representing the binary words <B> "000 "," M "</ B> and <B> 10l". </ B> On the other hand, for the other points, including the one associated with the word "M", these coefficients are different, since the value of the angle between the radius bearing the point representing each of these other words and the axes <B> 1 </ B> and <B> Q </ B> is different from the value of this angle for the binary words <B> "011 "," 000 "," 110 "</ B> and" 10l ". At the x and yl outputs, these coefficients are equal and are equal to 1 / cos (n / 4) <B≥ </ B> 1 / sin (7r / 4). The coefficient weighting the output <B> y2 </ B> is equal <B> to 1 </ B> / cos (7r / l <B> 6). </ B>

The final step <B> 38 </ B> of the process in this particular embodiment consists of presenting the three estimates previously obtained to the input of a turbodecoder , for decoding the received sequence.

In the receiving device of Figure <B> 13, </ B> steps <B> 28, 30, <B> 32, </ B> 34, <B> 36 </ B> and <B> 38 </ B> consist, for the computing unit <B> 260, to </ b> read in the RAM <B> 280 </ B> the data "data2 <I> in" </ I> received from the transmitter after passing through a transmission channel, <B> to </ B> process these data according to <B> to </ B> the corresponding instruction sequence contained in a program "Prf memorized in the read-only memory <B> 300, </ B> and <B> to </ B> store the data obtained "data2 out'in the RAM <B> 280. </ B> In the case of the modulation of type FSK, in the application to the distorted frequency representations, the steps <B> 28 </ B> and <B> 30 </ B> respectively consist of <B> to </ B> receive and, in case the transmission, we proceeded <B> to </ B> a transposed band modulation, <B> to </ B> demodulate the modulated symbols received. <B> A </ B> step <B> 32, </ B> we estimate the systematic output x thanks <B> to </ B> the difference between the frequency of the symbol obtained <B> to </ B> step <B> 30 </ B> and the median frequency <B> fo </ B> of the allocated frequency band.

<B> A </ B> step 34, it is estimated the output of the first coder yl thanks to <B> to </ B> the difference between the frequency of the symbol obtained <B> to </ B> the step < B> 30 </ B> and <B> there - </ B> central frequency fo <B> + fi, </ B> or fo <B> - </ B> fb, respectively, of one of the two bands of four frequencies arranged symmetrically with respect to <B> to </ B> the other according to the median frequency <B> fo, </ B> the choice between these two bands resulting from the previous step <B > 32. </ B>

<B> A </ B> step <B> 36, </ B> we estimate the output of the second encoder <B> y2 </ B> by <B> to </ B> the difference between the frequency of the symbol obtained <B> at </ B> step <B> 30 </ B> and the center frequency of one of the four sub-bands of two frequencies arranged symmetrically with respect to <B> to < / B> the other following the frequencies fo <B> + fi, </ B> and <B> fo - </ B> fb, the choice between these four sub-bands resulting from the previous steps <B> 32 </ B> and 34.

As shown in FIG. 8, an information transmission device 220 conforming to the invention is connected to the outputs of an encoder which comprises at least one interleaver and at least one systematic recursive convolutional coder. In the particular embodiment illustrated by FIG. 8, the outputs of the encoder are the three outputs x, yl, y2 of a turbo encoder 40.

The information transmission device comprises a mapping carry unit 42, a modulator 44 (optionally) and a transmitter 46 (not shown).

The mapping carry unit 42 includes a conversion module for converting the three bit sequences (x, yl, <B> y2) </ B> from the turbo encoder 40 into a sequence of three-bit binary words. where the MSB is x, the intermediate weight bit is yl and the LSB is <B> y2. </ B>

The mapping report unit 42 also comprises an association module, for associating each binary word provided by the conversion module, that is to say, a point of a distorted constellation as described above for reference. <B> to </ B> 7A, <B> to </ B> a point in a distorted frequency representation as previously described with reference <B> to </ B> Figure <B> 7B. </ B> Figure <B> 9 </ B> illustrates the overall structure of an information receiving device <B> 700 </ B> according to the invention, in a first Particular embodiment where the decoder uses the Viterbi algorithm, We have chosen to illustrate in detail the device in the particular application to the distorted constellations. The device of Figure <B> 9 </ B> comprises <B>, </ B> a receiver (not shown), for receiving symbols from a transmitter using a turbo encoder, possibly a demodulator 48, for to demodulate these symbols in the case where they have been modulated into a transposed band before transmission, a distance calculation module <B> 50 </ B> to calculate the Euclidean distance between each received symbol and the main points of a constellation in which This received symbol is located (that is, the <B> y2 </ B> bit is not used in this case <B>; only x and yl) are used, and Viterbi decoder <B> 52 </ B> of conventional type.

In the application to the distorted frequency representations, the module <B> 50 </ B> would be constituted by a frequency difference calculation module, to calculate the difference between the frequency of each received symbol and the central frequencies of a plurality specific frequency sub-bands, as described above in the context of the reception process.

Figure <B> 10 </ B> illustrates the overall structure of an information receiving device <B> 700 </ B> according to the invention, in a second particular embodiment of the invention. embodiment where the decoder is a turbodecoder.

The device of Figure <B> 10 </ B> comprises, as well as-the device of Figure <B> 9, </ B> a receiver (not shown) and (possibly) a demodulator 54. <B> It also includes three estimation modules <B> 56, 58, 60, </ B> respectively to estimate, for each received symbol, the three bits x, yl, <B> y2 </ B> respectively from the three outputs of the turbocharger.

In the application to distorted constellations, the estimation module <B> 56 </ B> estimates the output x <B> at </ B> from the value of the real part of the received symbol. The estimation module <B> 58 </ B> estimates the output yl <B> to </ B> from the value of the imaginary part of the received symbol. The estimation module <B> 60 </ B> estimates the output <B> y2 to </ B> from the value of the projection of the received symbol on an axis that separates the two regions of Voronoi from the quadrant of a distorted constellation in which this received symbol is located.

In the <U> application to </ U> distorted frequency representations, the estimation module <B> 56 </ B> estimates the output x <B> to </ B> from the difference between the frequency of the received symbols and the median frequency <B> fo </ B> of the allocated frequency band. The estimation module <B> 58 </ B> estimates the output yl <B> to </ B> from the difference between the frequency of the received symbol and the center frequency of one of the two frequency bands deduced from the estimate provided by module <B> 56, </ B> as described above in the context of the reception process. The estimation module <B> 60 </ B> estimates the output <B> y2 to </ B> from the difference between the frequency of the received symbol and the center frequency of one of the four frequency sub-bands deduced the estimates provided by modules <B> 56 </ B> and <B> 58, </ B> as described above in the context of the reception process.

In both of the above applications, the outputs of the three estimation modules <B> 56, 58, 60 </ B> are connected to the inputs of a turbodecoder <B> 62. </ B> As shown in Figure <B> 11, </ B> a network according to the invention consists of a station called base station SB designated by the reference 64, and several peripheral stations SPi, i <B≥ 1,. ... N, N </ B> being an integer greater than or equal to <B> to 1, respectively denoted by references <B> 661, 662, ..., 66N. </ B> devices <B> 661, 662, </ B> .., <B> 66N </ B> are remote from the base station SB, each connected by a radio link with the base station SB and able to move by report <B> to </ B> the latter. The block diagram of FIG. 12 represents a more detailed view of a peripheral station SPi, i <B≥ 1, .... N </ B> according to the invention which comprises a data source 200 and a device of FIG. issue 220.

The peripheral station SPi comprises for example a digital camera, a computer, a printer, a server, a fax machine, a scanner or a digital camera. The transmission device 220 comprises a data processing unit 240 comprising a CPU calculation unit (in English <I> "Central </ I> Processing <I> Unit") </ I> <B> 260, </ B> temporary data storage means <B> '280 </ B> (RAM memory), data storage means <B> 300 </ B> (ROM memory), character input means <B > 320, </ B> such as a keyboard for example, image restoration means 340 such as a screen for example, and input / output means <B> 360 .- </ B> RAM <B> 280 </ B> contains, in different registers <B> - </ B> "datal-in" input data, from data source 200 <B>; </ B> <B > - </ B> "datal-out" output data, obtained <B> at </ B> the outcome of the emission process of the invention <B>; </ B> and <B > - </ B> the current elements of the sequences of bits x, yl, <B> y2 </ B> coming from the turbocoder. The peripheral station SPi also comprises a transmission block <B> 380 </ B> and a radio module 400 comprising a known transmitter with one or more modulators, filters and a radio antenna (not shown).

The transmission device 220, thanks to the "Pe" program, stored in ROM <B> 300 </ B> and whose instruction sequence corresponds to the steps of the transmission method of the invention, is suitable <B> to execute the steps of the transmission method illustrated in FIG. 4A.

The peripheral station SPi according to the invention furthermore comprises, as shown in FIG. 13, a reception device <B> 700 </ B> which consists of a corresponding data processing unit. <B> to </ B> the data processing unit 240 <B> already </ B> described with reference <B> to </ B> in FIG. 12, of a reception block <B> 720 < / B> and radio module-400 with its antenna as shown in Figure 12. In the receiving device <B> 700, </ B> RAM <B> 280 </ B> contains, in different registers <B >: </ B> <B> - </ B> input data "data2 <I> in", </ I> from the transmitter, after passing through a transmission channel <B>; </ B> <B> - </ B> output data "data2 <I> out ', </ I> obtained <B> at </ B> the outcome of the <B> - </ B> process flow in any of its embodiments, the estimates i, # 1, # 2 corresponding to the current elements of the suites of bits x, yl, <b> y2 </ b> which come from the turbo encoder used by the transmitter.

The receiving device <B> 700, </ B> thanks to the programs "PrV '<I> and </ I>" Prt', stored in ROM <B> 300 </ B> and whose sequences of instructions correspond respectively to the steps of the reception methods of the invention with Viterbi decoding (for "PrV") and with turbodecoding (for "Prt"), is able <B> to </ B> execute indifferently, either the steps of the method of Receipt with Viterbi decoding shown in Figure <B> 5, </ B> are the steps of the turbo-decoded reception method illustrated in Figure <B> 6. </ B>

The invention as described above may as well be implemented on so-called base stations, in a network <B> to </ B> centralized architecture, as on stations in a network <B> to </ B> distributed architecture.

Claims (1)

<B> <U> CLAIMS </ U> </ B> <B> 1. </ B> A process for transmitting information, according to which a <B> (10) </ B> operation is performed encoding, using an encoder including at least one interleaver and at least one systematic recursive convolutional encoder, said coding operation consisting in encoding an information data stream in at least two bit sequences on performs (12) a conversion operation, consisting of converting said at least two bit sequences into a sequence of binary words, said method being characterized in that <B> - </ B> one performs (14) an association operation, consisting of <B> to </ B> associating each binary word obtained previously, by mapping report, <B> to </ B> a point of a graphical representation having a particular distortion , in a specific space <B>; </ B> - </ B>, <B> (18) </ B> is carried out as a sending operation, consisting of <B> to </ B> said points . 2. A method of transmitting information according to claim 1, characterized in that, during said coding operation, said data stream <B> is coded to </ b>. using a turbo-coder, to obtain at the output of said turbo-coder three bit sequences (x, yl, <b> y2), and that, in the course of said converting operation, converting said three sequences of bits (x, yl, <b> y2) </ b> obtained at the output of the turbo encoder into a sequence of three-bit binary words. <B> 3. </ B> The information transmission method according to claim 1, wherein said transmission operation is prior to <B> <B> a transposed band modulation operation is performed, whereby each point of said graphical representation with which a binary word is associated modulates a carrier and in that the repetition of this operation provides a a sequence of modulated symbols, and in that said transmission operation consists in transmitting said sequence of modulated symbols. An information transmitting method according to claim 1, wherein said specific space is the Fresnel plane, said distorted graphical representation is a distorted constellation and this association operation is to associate each binary word <B> with a point of said distorted constellation. <B> 5. </ B> Information transmission method according to claim 1, 2 or 3, characterized in that said specific space is the space frequency, said distorted graphical representation is a distorted frequency representation and said association operation consists in associating each binary word <B> with a predetermined frequency among a plurality of frequencies, the frequencies of said plurality of frequencies not being evenly distributed in the allocated frequency band. <B> 6. </ B> Information transmission method according to any one of claims 2 <B> to 5, </ B> characterized in that, <B> to </ B> the issue of said conversion operation, the most significant bit of said binary word represents the systematic output (x) of the turbo encoder, the intermediate weight bit of said binary word represents the output (yl) encoded by the first encoder included in the turbo encoder and the least significant bit of said binary word represents the output <B> (y2) </ B> encoded by the second encoder included in the turbo encoder after passing through the interleaver included in the turbo encoder. <B> 7. </ B> Information transmission method according to any one of claims <B> 1 to </ B> 4 and <B> 6, </ B> characterized in that, during of said association operation, quadrature modulation of QAM or PSK type is used. <B> 8. </ B> A method according to any one of claims <B> 1 to 3, 5 </ B> and <B> 6, </ B> characterized in that, during said operation of The association uses FSK type frequency modulation. <B> 9. </ B> Information transmission method according to claim 4 or <B> 7, </ B> characterized in that said distorted constellation is constructed <B> to </ B> from a symmetrical constellation <B> to </ B> eight points, in which <B> - </ B> we divide all of the said eight points into two groups of four symmetrical points, one with respect to <B> to </ B> the other following a first axis of symmetry, so that in each of said two groups, the most significant bit of the binary words associated with the points of the constellation located in said group is the same <B>; </ B> and <B> - </ B> we divide each group of four points into two subgroups of two symmetrical points, one with respect to <B> one </ B> the other along a second axis of symmetry, so that in each of said subgroups, the intermediate weight bit of the binary words associated with the points of the constellation located in said subgroup is the same. <B> - 10. </ B> Information transmission method according to claim <B> 5 </ B> or <B> 8, </ B> characterized in that, during said operation of association, <B> to </ B> from a set of eight frequencies equidistributed in the allocated frequency band, <B> - </ B> all of said eight frequencies are divided into two bands of four frequencies arranged symmetrically with respect to the median frequency fo of the allocated frequency band, so that in each of said two bands, the most significant bit of the associated bit words at the frequencies in this band the same <B>; </ B> and <B> - </ B> each band of four frequencies is divided into two sub-bands of two frequencies arranged symmetrically with respect to each other. <B> to </ B> the other following two symmetrical frequencies <B> fo </ B> + fb and <B> fo - </ B> fb, fb being a predetermined frequency, so that in each of In said sub-bands, the intermediate bit of the binary words associated with the frequencies in this sub-band is the same. <B> 11. </ B> A method for receiving information, characterized in that it comprises in particular <B>: </ B> <B> - </ B> a receiving operation (20 <B> 28), wherein <B> to receive symbols from a transmitter, said transmitter using a turbo encoder and implementing an information transmission method according to any one of claims <B> 1 to 10, </ B> and <B> - </ B> a decoding operation <B> (26; 38), </ B> indifferently according to the Viterbi algorithm or according to an algorithm of Turbo decoding. The information receiving method according to claim 11, wherein said transmitter implementing an information transmitting method according to any one of claims 1 to 4. > 4, <B> 6, 7 </ B> and <B> 9, </ B> where <B>: - </ B> <B> - </ B> is performed <B> (26) </ B> a decoding operation according to the Viterbi algorithm <B>; </ B> said method being characterized in that between said reception and decoding operations <B> - </ B> is performed ) a distance calculation operation, consisting of calculating the Euclidean distance between each received symbol and the main points of a constellation in which said received symbol is located, said decoding operation being based on said distances Euclidean previously calculated. <B> 13. </ B> The information receiving method according to claim 11, wherein said transmitter implementing an information transmitting method according to any one of claims <B> > 1 to </ B> 4, <B> 6, 7 </ B> and <B> 9, </ B> depending on which <B>: </ B> - </ B> << B> (38) </ B> a decoding operation according to a turbodecoding algorithm <B>; </ B> said method being characterized in that, between said reception and decoding operations <B>: </ B> <B> - </ B> for each symbol received, an estimation operation <B> (32) </ B> of a first bit (x) -issue of a first output of said turbo encoder is performed, <B> to </ B> from the value of the real part of said received symbol, an estimation operation (34) of a second binary element (y1) coming from a second output of said turbo encoder, <B> to </ B> from the value of the imaginary part of said received symbol, and an estimation operation <B> (36) </ B> of a third element binary ent <B> (y2) </ B> from a third output of said turbo encoder, <B> to </ B> from the value of -the projection of said received symbol on an axis that separates the two regions of Voronoi quadrant of a distorted constellation in which said received symbol is located. The information receiving method according to claim 11, wherein said transmitter implementing an information transmission method according to any one of claims 1 to 3, 5, 6, 8 </ B> and <B> 10, </ B> where <B>: </ B> <B> <B> (26) </ B> an operation of decoding according to the Viterbi algorithm; said method being characterized in that, between said receive and decode <B> <U> </ U> </ B> operands <B> : </ B> <B> - </ B> A frequency difference calculation operation is performed, consisting of <B> to calculate the difference between the frequency of each received symbol and the center frequencies of a frequency difference. plurality of sub-bands of specific frequencies, said operation of. decoding based on previously calculated differences. <B> 15. </ B> The information receiving method according to claim 11, wherein said transmitting transmitter is an information transmitting method according to any of claims <B> > 1 to 3, 5, 6, 8 </ B> and <B> 10, </ B> depending on which <B>: </ B> <B> - </ B> is performed <B> (38) </ B> a decoding operation according to a turbodecoding algorithm <B>; </ B> said method being characterized in that, between said reception and decoding operations <B>: </ B> <B> - < / B> for each symbol received, an estimation operation <B> (32) </ B> of a first binary element (x) is carried out from a first output of said turbo encoder, <B> to </ B> from the difference between the frequency of the received symbol and the median frequency fo of the allocated frequency band, an estimation operation (34) of a second binary element (y1) coming from a second output of said turbo encoder, B> to </ B> from the difference between the frequency of the symbol received and the frequency center of one of two frequency bands, deduced from the estimation operation of said first bit, and an estimation operation <B> (36) </ B> of a third bit <B> ( y2) from a third output of said turbo encoder, from the difference between the frequency of the received symbol and the center frequency of one of four frequency sub-bands, derived from operations for estimating said first and second bits. <B> 16. </ B> The method of receiving information according to any one of claims 11 to 15, characterized in that, during said reception operation, reception is received from of said transmitter of the transposed band modulated symbols and, <B> to </ B> following said receiving operation, performing (22 <B>; 30) </ B> a demodulation operation, consisting of <B>; </ B> demodulate the received modulated symbols. <B> 17. </ B> Information transmission device, comprising <B> - </ B> coding means (40), comprising at least one interleaver and at least one systematic recursive convolutional coder, for coding a stream of information data in at least two sequences of <B> 1 </ B> bits <B>; </ B> <B> - </ B> means (42) of conversion, to convert said at least two sequences of bits in a sequence of binary words said device being characterized in that it further comprises means for associating each provided binary word (42) by said conversion means, by mapping report, <B> to </ B> a point of a graphical representation having a particular distortion, in a specific space <B>; </ B> and <B> - </ B> transmission means (46) for transmitting said points. <B> 18. </ B> Information transmission device according to claim 17, characterized in that said coding means (40) comprise a turbo encoder which outputs three sequences of data. binary elements (x, yl, y2) and said conversion means converting said three bit sequences to a sequence of three-bit binary words. <B> 19. </ B> Information transmission device according to claim <B> 17 </ B> or <B> 18, </ B> characterized in that it further comprises means (44 ) of transposed band modulation, so that each point of said graphic representation with which a binary word is associated modulates a carrier, the repetition of this operation providing a sequence of modulated symbols. An information transmitting device according to claim 17, wherein said specific space is the plane of Fresnel, said distorted graphical representation is a distorted constellation, and said association means associates each binary word <B> with a point of said distorted constellation. 21. An information transmitting device according to claim 17, 18, 19 or 19, characterized in that said specific space is the frequency space, said distorted graphical representation is a distorted frequency representation, and said association means associates each binary word <B> with a predetermined frequency among a plurality of frequencies, the frequencies of said plurality of frequencies n ' being not equidistributed in the allocated frequency band. 22. An information transmission device according to any one of claims 18 to 21, characterized in that, at the output of said conversion means (42), the most significant bit of said binary word represents the systematic output (x) of the turbo encoder, the intermediate weight bit of said binary word represents the output (yl) encoded by the first encoder included in the turbo encoder and the least significant bit of said binary word represents the output < B> (y2) </ B> encoded by the second encoder included in the turbo encoder after passing through the interleaver included in the turbo encoder. <B> 23. </ B> Information transmission device according to any one of claims <B> 17 to </ B> 20 and 22, characterized in that said means (42) of association memorize the coordinates of the points of said distorted constellation. 24. An information transmission device according to any one of claims 17 to 19, 21 and 22, characterized in that said association means (42) memorize the frequency values of said plurality of non-equal frequencies in the allocated frequency band. <B> 25. </ B> Information receiving device, characterized in that it comprises in particular <B> - </ B> receiving means, for receiving symbols from a transmitter, said transmitter using a turbo encoder and having an information transmitting device according to any one of claims 17 to 24, and <B> - </ B> means (52 <B>; < / B> 62), either indifferently, either a Viterbi decoder <B> (52), </ B> or a turbo decoder <B> (62). </ B> <B> 26. </ B> An information receiving apparatus according to claim 25, said emitter using a turbo encoder and having a transmitting device according to any one of claims 17 to 20, 22 and 20; <B> 23, </ B> said information receiving device comprising: decoding means comprising a Viterbi decoder <B> (52), < / B> said information receiving device being characterized in that it comprises In addition <B>: <B> - <B> <B> (50) </ B> distance calculation means, to calculate the Euclidean distance between each received symbol and the main points of a constellation in which said received symbol is located. <B> - 27. </ B> The information receiving device according to claim 25, wherein said transmitter using a turbo encoder and having a transmitting device according to any one of claims <B> 17 to </ B> 20, 22 and <B> 23, </ B> said information receiving device comprising <B>: </ B> <B> - </ B> decoding means comprising a turbodecoder <B> (62), </ B> said information receiving device being characterized in that it further comprises <B>: </ B> <B> - </ B> first means <B> (56) </ B> estimate, for estimating, for each symbol received, a first bit (x) from a first output of said turbo encoder, <B> to </ B> from the value of the part of said received symbol, <B> - </ B> of the second estimating means (B) (58) </ B> for estimating, for each received symbol, a second binary element (y1) from a second output of said turbo encoder, <B> to </ B> from the value of the imaginary portion of said received symbol, and <B> - </ B> of the third estimation means <B> (60) </ B> to estimate, for each received symbol, a third binary element <B> (y2) </ B> derived from a third output of said turbo encoder, from the projection value of said received symbol on an axis that separates the two Voronoi regions from the quadrant of a distorted constellation in which said received symbol is located. <B> 28. </ B> The information receiving device according to claim 25, wherein said transmitter using a turbo encoder and having a transmitting device according to any one of the claims <B> 17 to 19, 21, 22 and 24, said information receiving device comprising: decoding means comprising a decoder Viferbi <B> - </ B> - </ B> > (52), </ B> said information receiving device being characterized in that it further comprises <B>: </ B> frequency difference calculation means, for calculating the difference between the frequency of each received symbol and the center frequencies of a plurality of specific frequency subbands. <B> 29. </ B> The information receiving device according to claim 25, wherein said transmitter using a turbo encoder and having a transmitting device according to any of the claims. at 19, 21, 22 and 24, said information receiving device comprising: decoding means comprising a turbodecoder <B> (62) , </ B> said information receiving device being characterized in that it further comprises <B>: </ B> <B> - </ B> of the first means <B> (56) </ B> estimating, for estimating, for each received symbol, a first binary element (x) resulting from a first output of the turbo encoder, from the difference between the frequency of the received symbol and the frequency median <B> fo </ B> of the allocated frequency band, <B> - - </ B> of the second estimation means <B> (58) </ B>, to estimate, for each symbol received, a second bit (yl) from a second output of the turbo encoder, <B> to </ b> p to calculate the difference between the frequency of the received symbol and the center frequency of one of two frequency bands, deduced from the estimate of said first bit, and <B> -_ </ B> of the third means <B> ( 60) </ B> to estimate, for each symbol received, a third binary element <B> (y2) </ B> from a third output of the turbo encoder, <B> to </ B> from the difference between the frequency of the received symbol and the center frequency of one of four frequency subbands deduced from the estimate of said first and second bits. <B> 30. </ B> Information receiving device according to any one of claims <B> 25 to 29, characterized in that said receiving means receive from said transmitter symbols modulated by transposed band, and in that it further comprises demodulation means (48 <B>; </ B> 54) for demodulating said received modulated symbols. <B> 31. </ B> Digital signal processing apparatus, characterized in that it comprises means adapted <B> to </ B> implement an information transmission method according to one any of the claims <B> 1 to 10. </ B> <B> 32. </ B> Apparatus for processing digital signals, characterized in that it comprises means adapted <B> to </ B> set implement an information receiving method according to any one of claims <B> 11 to 16. </ B> <B> 33. </ B> Digital signal processing apparatus, characterized in that it comprises a information transmitting device according to any one of claims <B> 17 to </ B> 24. 34. Digital signal processing apparatus, characterized in that it comprises an information receiving device according to the present invention. any of the claims <B> 25 to 30. </ B> <B> 35. </ B> Telecommunication network, characterized in that it comprises means adapted <B> to </ B> implement a information transmission method according to any one of claims 1 to 10. <b> 36. </ B> Telecommunications network, characterized in that it comprises adapted means <B to implement an information receiving method according to any one of claims 11 to 16. <BR> <BR> <BR> 37 </ B>. it comprises an information transmission device according to any one of the claims <B> 17 to </ B> 24. <B> 38. </ B> Telecommunication network, characterized in that it comprises an information receiving device according to any one of claims 25 to 30. A mobile station in a telecommunications network, characterized in that it comprises adapted means <B> to </ B> implement an information transmission method according to any one of claims <B> 1 to </ B> <B> 10. </ B> 40. Mobile station in a telecom network unications, characterized in that it comprises means adapted <B> to </ B> implement a method of receiving information according to any one of claims <B> 11 to 16. </ B> 41. Mobile station in a telecommunications network, characterized in that it comprises an information transmission device according to any one of claims 17 to 24. 42. Mobile station in a telecommunications network , characterized in that it comprises an information receiving device according to any one of claims <B> 25 to 30. </ B>