DE10345713B4 - ARQ method - Google Patents

Abstract

Method for transmitting digital information between a transmitter (S) and a receiver (E),
(a) where transmitter side
splitting a serial stream (ST) of information bits into a plurality of parallel streams (PS1, PS2, PS3),
the information bits of the parallel streams (PS1, PS2, PS3) are converted by coding into coded bits (KB1, KB2, KB3),
the coded bits (KB1, KB2, KB3) are sent in the form of symbols (SYM) to the receiver (E), wherein in the symbols (SYM) in each case one coded bit (KB1, KB2, KB3) of each parallel stream (PS1 , PS2, PS3),
characterized in that
(b) at the transmitter side, due to at least one error message (NAK) from the receiver (E) concerning received coded bits of a subset of parallel streams of the plurality of parallel streams (PS1, PS2, PS3)
In step (a) already transmitted encoded bits (KB1, KB2, KB3) of the at least one error message (NAK) indexed coded bits and / or ...

Description

The The invention relates to a method for transmitting digital information between a transmitter and a receiver according to the preamble of Claim 1.

Farther The invention relates to a transmitter and a receiver for execution of the procedure.

communications systems serve the transmission information between a sender and a receiver. In Radio communication systems become information (e.g. Language, image information, video information, SMS (Short Message Service) or other data) by means of electromagnetic waves over one Radio interface between transmitter and receiver transmitted. The blasting of the In this case, electromagnetic waves take place with carrier frequencies that are in the for the respective System provided frequency band lie.

News channels, in particular Radio channels, are a variety of disorders exposed. Unavoidable in all systems is the fault due to the noise of the receivers, mostly additives white gaussian Noise. Furthermore, radio channels show many additional disorders, caused by multipath propagation, scattering, fading, total failures, impulse disturbances, Interference from other participants and interference signals.

at the digital transmission of information about a channel will become common Method of channel coding used to provide a reliable, i. largely error-free, transmission to ensure. The term channel coding is a generic term for all Coding method in which the properties of a transmission channel considered be transferred to the redundancy of Data targeted for error detection or error correction he heights. in the In contrast, source coding reduces redundancy. method for channel coding, e.g. the block encoding and the convolutional coding.

Around individual bits during a transmission different degrees of protection, Multi-level coding techniques are used. This is splitting a serial bit stream into a plurality of parallel bitstreams, being for each of the parallel bitstreams a different coding can be used. The different strongly coded bits of the parallel streams then become symbols in which each symbol is exactly one coded bit of a each of the parallel bitstreams received. A set of bits whose number equals the number of parallel ones Bitstreams matches, thus enters a symbol; the symbols are thus dependent on the coded ones Bits which are mapped to the symbols.

• S. Benedetto, D. Divsalar, G. Montorsi, F. Pollara: „Parallel Concatenated Trellis Coded Modulation", IEEE International Conference on Communications, 23–27. Juni 1996, Vol. 2, S. 974–978

beschreibt eine parallele Verknüpfung von Trellis-Kodes mit Multilevel-Amplituden oder -Phasen Modulation.The document

• S. Benedetto, D. Divsalar, G. Montorsi, F. Pollara: "Parallel Concatenated Trellis Coded Modulation", IEEE International Conference on Communications, June 23-27, 1996, Vol. 2, pp. 974-978

describes a parallel linking of trellis codes with multilevel amplitudes or phase modulation.

• Ph. Antoine: „Parallel Concatenated Trellis Coded Modulation with Automatic Repeat Request for ADSL Applications", IEEE International Conference on Communications, 18.–22. Juni 2000, Vol. 2, S. 1075–1079

beschreibt ein ARQ-Verfahren für eine parallele verknüpfte Trellis-Kode-Modulation. Gemäß diesem Verfahren können ganze Blöcke von Symbolen von dem Empfänger als fehlerhaft erkannt und erneut angefordert werden.The document

• Ph. Antoine: "Parallel Concatenated Trellis Coded Modulation with Automatic Repeat Request for ADSL Applications", IEEE International Conference on Communications, 18-22 June 2000, Vol. 2, pp. 1075-1079

describes an ARQ method for parallel linked trellis code modulation. According to this method, entire blocks of symbols can be recognized as erroneous by the receiver and requested again.

On the transmitter side finds in the coder the conversion of information bits into coded ones Bits and an image of the coded bits in symbols instead, which then over the Channel are transmitted to the receiver. While the transmission As a rule, the symbols are falsified by disturbing influences. The job of the decoder exists on the receiver side now in it to recognize any occurred transmission errors or from the received, falsified Signal to determine the transmitted coded bits.

In the case of ARQ (Automatic Repeat Request) methods, checksums such as CRC (Cyclic Redundancy Check) are added to the bits to be transmitted on the transmitter side, which allow the receiver to determine whether errors occurred during the transmission. This corresponds to a check whether the received match the transmitted bits. If errors are detected, a Negative Acknowledgment (NAK) is sent from the receiver to the transmitter, whereupon the transmitter retransmits the erroneously received bits. Hybrid ARQ methods are understood to be methods in which ARQ mechanisms such as checksum formation, acknowledgment (ACK or NAK) and repeated transmission are combined with an error-correcting coding. The receiver only requests the repeated sending of bits if the error correction of an Ab detected as erroneous cut is not possible. With regard to the subsequent repeated sending of bits, the following possibilities exist: in the case of type 1 methods, the coded data sent in the first transmission is exactly repeated and no combination with the coded data sent during the first transmission takes place, while in type 2 methods, in addition to the coded data the first transmission further redundancy is sent, which was not sent in the first transmission, without the bits of Erstversendung be sent again. The coded bits thus transmitted are not decodable by themselves. They must be combined in the receiver with the data sent during the initial transmission before they can be decoded. In Type 3 methods, in repeated transmission, different versions of the coded bits with different redundancy may be sent in addition to the coded data of the first transmission. In this case, more redundancy can be added step by step per repeated transmission. The repeatedly transmitted data can thus also be decoded alone, without taking into account the data transmitted during the first transmission. However, before decoding, a combination of the repeatedly transmitted data and the data transmitted during the first transmission may also take place in the receiver. Type 2 or 3 hybrid ARQ methods are preferably used for radio transmission.

at the transmitter transmits the described ARQ method with an error message from the recipient entire symbols repeatedly or redundancy regarding the entire faulty symbols. It is possible, however, that transmission errors only a part of a symbol, so that in this case the described ARQ procedure radio resources for the transmission of repetition or use redundancy bits which the receiver for correct decoding not required.

The document US 5,983,384 describes turbo-coding in which code bits are punctured before shipment. If the receiver recognizes received bits as faulty, then the dotted code bits can be sent by the transmitter.

The Document US 2002/0199147 A1 describes the sending of symbols, where a first part is a high reliability and a second part a low reliability exhibit. High priority bits are modulated so that these are on the first part of the symbols are mapped, low priority bits are modulated so that these are mapped to the second part of the symbols.

Of the Invention is based on the object, an efficient ARQ method To demonstrate which supports a sparing use of transmission resources. Farther should be a sender and a receiver to carry out of the method.

These Task is with respect to the method by a method with the features of claim 1 solved.

advantageous Embodiments and developments are the subject of dependent claims.

• – in Schritt (a) bereits gesendete kodierte Bits der in der mindestens einen Fehlermeldung indizierten kodierten Bits und/oder
• – in Schritt (a) nicht gesendete kodierte Bits basierend auf Informationsbits der Teilmenge von parallelen Strömen, auf welchen die in der mindestens einen Fehlermeldung indizierten kodierten Bits basieren

an den Empfänger gesendet.In the method for transmitting digital information between a transmitter and a receiver, at the transmitter end in a method step (a), a serial stream of information bits is split into a plurality of parallel streams. The information bits of the parallel streams are converted into coded bits by encoding. The coded bits are sent in the form of symbols to the receiver, wherein the symbols each receive a coded bit of each parallel stream. The coded bits are sent in the form of symbols to the receiver. According to the invention, at least one error message from the receiver regarding received coded bits of a subset of parallel streams of the plurality of parallel streams is provided on the transmitter side in a method step (b)

• - In step (a) already transmitted encoded bits of the indexed in the at least one error message coded bits and / or
• Coded bits not sent in step (a) based on information bits of the subset of parallel streams on which the coded bits indicated in the at least one error message are based

sent to the recipient.

It this is an ARQ method, in which in step (a) Information bits processed for the first time and in coded form to the recipient be shipped. Upon an error message from the recipient, in step (b) repetition and / or redundancy bits to those in step (a) sent for the first time.

The bits of the parallel streams are processed in parallel in the transmitter and also sent parallel to each other, that is, in the sent symbols are bits of different parallel currents. Thus, there is a correlation between the number of parallel streams and the modulation method used: the more parallel streams are used, the more highly used it is te modulation method.

In front The formation of symbols becomes the information bits of the parallel ones streams subjected to a coding. This may be, for example, a Error detection coding, such as appending checksums act on the information bits, or even error correction encodings, such as convolutional or block encodings. Those bits, which leave the encoder are called coded bits.

In front the receiver sends the error message Method for determining the correctness of received coded Bits through. This means that the receiver checks if transmission errors have occurred or whether the received match the transmitted bits. The error message concerns one or more of the parallel streams. Consequently it is with the method according to the invention possible, in the case of faulty reception instead of repeated transmission of whole symbols the repeated transmission of components of symbols or of individual bits which are in the respective symbols have to be requested. It is thus a bit selective ARQ method, which is an economical use of transmission resources supported.

ever After designing the ARQ method, the transmitter responds differently to the error message of the recipient. So it is possible that he sent with a repeated shipment of previously sent coded bits responds. Furthermore, besides the dispatch of already sent coded bits an additional dispatch of further, previously undelivered, coded bits take place. Here are the ones already sent and the first time after the error message sent coded bits based on the same information bits determined so that the receiver using the new coded bits, a more accurate decoding can make. After all is it possible that the transmitter does not resend the coded bits already sent, but only not yet sent coded bits, which due to the same information bits were calculated. The described make ARQ type 1, 2 and 3.

In Development of the invention takes place in step (a) for the information bits of at least two of the parallel streams are different from each other Encoding. In this case, the transmitter has a multi-level encoder with different coding methods. A different coding for different parallel currents can be realized by different calculation rules the coding method or by the same calculation rules and a different punctuation. A different coding manifests itself usually in a different number of redundancy bits per transmitted information bit. However, it is also possible that for the Information bits of all parallel streams the same coding takes place.

In Embodiment of the invention are prior to sending the encoded Bits in step (b) each of a number of in step (b) transmitted coded bits corresponding to the plurality of parallel streams, Symbols are formed, in which one of the plurality of parallel currents corresponding number of bits. This means that in step (b) sent symbols into which exclusively received coded bits sent due to the error message. Becomes For example, using a trivalent modulation method, so In each case, three of the bits sent in step (b) become one Symbol summarized and sent to the recipient. In this way can all or even part of the in step (b) due to the error message transmitted coded bits are combined to form symbols. are several of the parallel streams affected by an error message, symbols can be formed in which exclusively bits of a single parallel stream sent in step (b) received. In this case, you can the coded bits of the individual sent due to the error message parallel currents e.g. be sent one after the other, so that first all symbols formed from bits of a first parallel stream and then all Symbols formed from bits of a second parallel stream sent become. Furthermore you can alternatively or in addition to these pure symbols mixed symbols are formed, in which coded bits are received by different parallel streams.

In Another embodiment of the invention are prior to shipment the coded bits in step (b) each of a number of in Step (b) of transmitted coded bits, wherein the number of a subset the plurality of parallel streams corresponds to symbols formed in which one of the plurality of parallel Stream corresponding number of bits, the bits of the symbols, which do not correspond to the coded bits sent in step (b), for the different formed symbols are the same. Hereby are thus Symbols formed, in addition to those due to the error message transmitted coded bits and other bits. In these other bits are a particular bit pattern, which for all symbols formed according to this scheme is the same. Due to the determination This bit pattern occurs an effective reduction of the used Modulationalphage, which provides easier decoding in the receiver allows.

In a further embodiment of the inventions In each case, before sending the coded bits in step (b), a plurality of coded bits sent in step (b), the number of a subset of the plurality of parallel streams corresponding to each other, form symbols into which one of the plurality of parallel streams corresponding number of bits, wherein the bits of the symbols which do not correspond to the coded bits transmitted in step (b) consist of coded bits based on information bits of one or more parallel streams with respect to which no coded bits have previously been transmitted. In this case, symbols are thus formed, within which the coded bits sent due to the error message occupy some, but not all, positions. The other positions are occupied by coded bits calculated from information bits for which no coded bits have previously been transmitted. This corresponds to the case where some of the parallel streams continue scheduled bits, while other positions of the transmitted symbols are occupied by repetition bits of step (b).

advantageously, The information between the transmitter and the receiver is transmitted by radio.

The The above object with respect to the transmitter is by a device for sending information with the features of the claim 7 solved.

A advantageous embodiment is the subject of a subclaim.

• – zuvor bereits gesendeten kodierten Bits der in der mindestens einen Fehlermeldung indizierten kodierten Bits, und/oder
• – zuvor nicht gesendeten kodierten Bits basierend auf Informationsbits der Teilmenge von parallelen Strömen, auf welchen die in der mindestens einen Fehlermeldung indizierten kodierten Bits basieren,

aufgrund der mindestens einen Fehlermeldung an den Empfänger.The inventive apparatus for sending information to a receiver comprises means for dividing a serial stream of information bits into a plurality of parallel streams, further means for converting the information bits of the parallel streams to coded bits by coding, and means for forming symbols from the encoded bits, so that in each case a coded bit of each parallel stream is received in the symbols. Furthermore, the device according to the invention comprises means for sending the coded bits in the form of symbols to the receiver, means for receiving and evaluating at least one error message from the receiver concerning received coded bits of a subset of parallel streams of the plurality of parallel streams, and means for sending from

• Previously encoded bits of the coded bits indicated in the at least one error message, and / or
• Previously untransmitted coded bits based on information bits of the subset of parallel streams on which the coded bits indexed in the at least one error message are based,

due to the at least one error message to the receiver.

In Embodiment of the invention comprises the device according to the invention for sending information further means for forming symbols, in which in each case at least one due to the at least one error message sent coded bits received.

The The above object with respect to a receiver is achieved by a device for receiving information from a sender having the features of claim 9 solved.

• – zuvor bereits empfangenen kodierten Bits der in der mindestens einen Fehlermeldung indizierten kodierten Bits, und/oder
• – zuvor nicht empfangenen kodierten Bits basierend auf Informationsbits der Teilmenge von parallelen Strömen, auf welchen die in der mindestens einen Fehlermeldung indizierten Bits basieren,

von dem Sender.The information receiving device according to the present invention comprises means for receiving symbols from the transmitter, each having a coded bit of each of a plurality of parallel streams of information bits at the transmitter end, and means for determining the correctness of the received coded bits, and means for generating and sending at least one error message regarding received coded bits of a subset of parallel streams of the plurality of parallel streams to the sender. Finally, the device according to the invention comprises means for receiving

• Previously encoded bits of the coded bits indicated in the at least one error message, and / or
• Previously unreceived coded bits based on information bits of the subset of parallel streams upon which the bits indicated in the at least one error message are based,

from the transmitter.

The inventive device for sending information to a receiver and the device according to the invention in particular, for receiving information from a transmitter to carry out of the method according to the invention, this also applies to the subclaims. For this purpose, the Each device may comprise further suitable means.

in the Following, the invention will be explained in more detail with reference to an embodiment. there demonstrate

1 schematically the processing of data in the transmitter and the receiver,

2 : the transmission of repetition bits in the context of an ARQ method according to the invention,

3 : an arrangement of symbols in the complex plane.

In the digital transmission of information over a transmission channel, modulation techniques are used wherein multiple bits are combined into one symbol and transmitted using modulation types such as ASK (Amplitude Shift Keying), PSK (Phase Shift Keying) or QAM (Quadrature Amplitude Modulation) , Particularly in the case of higher-order types of modulation, the individual bits of a symbol to be transmitted are subject to different susceptibility to error. At the example 16QAM shows 3 an assignment of four bits each to a symbol. Here all possible symbols are shown in the complex plane. The axes correspond to the real and the imaginary part of a received or transmitted signal. The position of a symbol detected by the receiver, which was transmitted via a disturbed channel, is identified by a cross. The probability that the first bit of the transmitted signal is a zero is significantly higher than the probability that the last bit of the transmitted signal is a zero, since the first bit for all possible symbols within the right upper quadrant is one Zero acts.

at usual ARQ method transmits the transmitter the recipient after notifying that he was unable to decode the symbol correctly, again the entire symbol or redundancy information regarding the entire symbol. In the present case, this does not correspond to efficient utilization the transmission resources, because the receiver the first bit of the erroneous symbol with a higher probability can correctly decode as the rest Bits. In the following the process of the invention will be described, which this problem bypasses.

1 shows a present in the transmitter S for the receiver E bitstream ST. This is divided into three parallel bit streams PS1, PS2 and PS3. However, the inventive method is not limited to using three parallel bit streams, but any number of parallel bit streams greater than or equal to two may be used. The parallel bit streams PS1, PS2 and PS3 correspond to three branches, which are processed in parallel in the transmitter S and sent in parallel to the receiver. Various algorithms can be used for the division of the bits of the serial bit stream into the parallel bit streams. In the simplest case, the bits are cyclically split into the parallel bit streams so that every third bit gets into each of the parallel bit streams PS1, PS2 and PS3.

The Bits of the three parallel bit streams PS1, PS2 and PS3 are in the three encoders ENCODER1, ENCODER2 and ENCODER3 each coded differently. As encoding rule can e.g. a convolutional coding or a serial concatenation of Folding codes are used. In the folding coding is it is an image of x incoming bits outgoing on y, channel coded bits, i. each incoming x bits are coded y Bits output. The ratio x / y is called Koderate. Technically, a convolutional encoder realized by a digital circuit of shift registers whose Content in y different ways along with the currently incoming one Data bits are linked by addition and modulo-2 operations.

To The convolutional coding may be the result of this convolutional coding to be punctured. This is a certain number of bits the result of the convolutional coding and thus the Reduced number of redundancy bits. A different coding Thus, the three encoders ENCODER1, ENCODER2 and ENCODER3 can thereby be achieved by each of the three encoders ENCODER1, ENCODER2 and ENCODER3 use the same calculation rule for convolutional coding but in combination with different punctuation.

at the bits representing the three encoders ENCODER1, ENCODER2 and ENCODER3 leave, it is the coded bits KB1, KB2 and KB3 the three branches. The coded bits KB1, KB2 and KB3 are grouped into packets, so every packet containing one of the three encoders ENCODER1, ENCODER2 and ENCODER3 leaves, includes an equal number of coded bits.

One another coding step, which in each case in the three encoders ENCODER1, ENCODER2 and ENCODER3 is the calculation of a checksum such as. CRC (Cyclic Redundancy Check) into which all bits of the each package received. This checksum is part of the packages and thus also the coded bits KB1, KB2 and KB3. Based on this Error detection coding allows the receiver to decide if the respective one Transfer the package correctly i.e., whether the bits of the received packet match those of the sent one Package match.

In the left part of the 2 schematically the quantitative distribution of coded bits KB1, KB2 and KB3 is shown in a set of information bits i and redundancy bits r, wherein the amount of information bits i the uncoded bits of the parallel streams PS1, PS2 and PS3 corresponds and the amount the redundancy bits r those bits which were additionally added due to the coding. The nature of the representation does not imply that the set of information bits i and redundancy bits r are necessarily separate from each other following each other in the packets. Rather, the division of the packets into the set of information bits i and redundancy bits r indicates how many of the uncoded bits of the parallel streams PS1, PS2 and PS3 per packet were processed by encoders ENCODER1, ENCODER2 and ENCODER3. The lower index on the information bits i and the redundancy bits r stands for the packet number and the upper parenthesized index stands for the respective branch. i ₁ ⁽¹⁾ thus stands for the amount of information bits of the first Pa ketes the topmost branch. The uppermost branch has in the left illustration the 2 the greatest amount r of redundancy bits, so that the coding by the encoder ENCODER1 in the topmost branch is stronger than by the encoders ENCODER2 and ENCODER3 of the other branches.

After encoding, the coded bits KB1, KB2 and KB3 are written in 1 combined in a symbol formation device MAPPER to symbols SYM. Since three branches are used, a modulation alphabet with 2 ³ = 8 symbols is used. A symbol corresponds to a binary vector with three entries, the first entry corresponding to the MSB (Most Significant Bit) and the third entry to the LSB (Least Significant Bit). In the following, the entries of the vectors are referred to positions within a symbol. The coded bits KB1 of the first branch occupy the uppermost position within a symbol, the coded bits KB2 of the second branch the middle and the coded bits KB3 of the third branch the lowest. The receiver E is aware of the composition of the symbols or the assignment of positions within the symbols to coding specifications of the encoders ENCODER1, ENCODER2 and ENCODER3.

The Symbols SYM are sent by the sender S and sent via the transmission channel CHANNEL transmit the receiver. In the transmission channel In the present exemplary embodiment, this is a radio channel. However, the described method can also be applied to other types of transmission channels particular to such transmission channels which have no static behavior, but especially short-term temporal changes subject.

often are subject to the transfer various disorders, so that is from the receiver E received symbols SYM 'of can distinguish the transmitted symbols SYM. Using the Decoder DECODER, which is due to the nature of the transmitter side Encoding around a multi-stage decoder the recipient E checks first using the checksums, whether the transfer on the individual branches is flawed. If an error is detected, it may be due to the error-correcting properties of the convolutional codes the transmitted symbols SYM from the received symbols SYM 'to determine. Furthermore, the receiver E reliability values for sections determine the received parallel bitstreams. The reliability values can then be used as a measure in which cases Repeat bits are requested for correct decoding of the symbols. Succeed the receiver E a correct decoding for all symbols of a package, this confirms the correct receipt of the packet by an ACK (acknowledgment). In the following, the case is considered that the receiver E is not is able to get a correct decode result for a package to obtain.

Under Use of a return channel FEEDBACK CHANNEL the receiver E then informs the transmitter S below Use of a NAK (Negative Acknowledgment) about that uncorrectable transmission errors occurred in the package concerned. The return channel FEEDBACK CHANNEL is used for each branch of each received Packet to signal whether the decoding was successful or Not. The following assumes that there is an uncorrectable transmission error occurred in the middle branch. Depending on the receiver E used Decoding method includes the error message NAK only the Specification of the branch or the position within the symbols, which contains erroneous bits, or in addition a delimitation of bits of the respective packet, which by the transmission falsified were. From the recipient will thus be repeat bits, giving it better error correction to enable the decoding of the data, packet by packet or for symbol sequences requested within a package.

The sender S can respond to the error message NAK by sending variously configured information. In 2 For example, the bits which the transmitter S sends to the receiver due to the error message NAK are denoted by ⁺ r ₁ ⁽²⁾ . Concerning the specific configuration of the bits ⁺ r ₁ ⁽²⁾ , it is possible that these match the previously transmitted encoded bits KB2 or i ₁ ⁽²⁾ and r ₁ ⁽²⁾ , so that the transmitter S only the already sent repeated unchanged. Furthermore, the transmitter S can send the coded bits KB2 and additionally previously transmitted coded bits calculated from the same uncoded bits as the coded bits KB2. This can be realized, for example, by the fact that the transmitter S is a part of the before the first transmission ment punctured bits in the coded bits KB2 inserts and thus increases the proportion of redundancy bits or the Koderate lowered. Thus, the code rate can be gradually reduced until at most all previously punctured bits are inserted. In this case, the number of bits ⁺ r ₁ ⁽²⁾ exceeds the number of previously transmitted coded bits KB2. It is also possible to send coded bits not previously transmitted together with a subset of the previously transmitted coded bits KB2, so that the number of bits ⁺ r ₁ ^{(2) can be} greater or smaller than the number of previously transmitted coded bits KB2. Finally, it is also possible to transmit coded bits which were not previously transmitted and which were calculated from the same uncoded bits as the coded bits KB2. For example, the sender S can send the previously punctured bits without re-transmitting the coded bits KB2. In this case, the number of bits ⁺ r ₁ ^{(2) is} less than the number of previously transmitted coded bits KB2.

For a division of the bits ⁺ r ₁ ⁽²⁾ on the three branches and thus on the positions within the symbols to be transmitted are in 2 on the right side three possibilities are shown. In the top illustration, the bits ⁺ r ₁ ^{(2) have been} split into the three branches and sent at the beginning of the next packet. In this case, symbols were formed from the bits ⁺ r ₁ ⁽²⁾ , the symbols consisting exclusively of the bits ⁺ r ₁ ⁽²⁾ . For symbol formation concerning the bits ⁺ r ₁ ⁽²⁾ , the device for symbol formation MAPPER is used on the transmitter side. Following bits ⁺ r ₁ ⁽²⁾ , in the uppermost branch, the set of information bits i ₂ ⁽¹⁾ and the amount of redundancy bits r ₂ ⁽¹⁾ , in the middle branch, the set of information bits i ₂ ⁽²⁾ and the set the redundancy bits r ₂ ⁽²⁾ , and in the lower branch, the amount of information bits i ₂ ⁽³⁾ and the amount of redundancy bits r ₂ ⁽³⁾ sent. In order not to reduce the payload data rate by the transmission of bits ⁺ r ₁ ⁽²⁾ , for the considered one in the upper part of the right-hand illustration of FIG 2 shown package for each branch a higher punctuation than usual, eg in the first package in the left representation of 2 used to be selected. However, it is also possible that the encodings of the three encoders ENCODER1, ENCODER2 and ENCODER3 are not changed over a normal data transmission, so that the proportion of information bits i ₂ ⁽¹⁾ , i ₂ ⁽²⁾ and i ₂ ^{(3) of} the second Packet is reduced in the total number of bits of the second packet compared to the proportion of the information bits i ₁ ⁽¹⁾ , i ₁ ⁽²⁾ and i ₁ ^{(3) of} the first packet in the total number of bits of the first packet.

If, in addition to the bits ⁺ r ₁ ^(2), repetition bits for a further branch are to be sent, these can be transmitted after the bits ⁺ r ₁ ⁽²⁾ , for example. In this case, the symbols in which only the bits ⁺ r ₁ ^{(2) of} the second branch have been received are symbols which have been formed exclusively from repetition bits of another branch. Alternatively, it is also possible to form symbols into which both one or more of the bits ⁺ r ₁ ⁽²⁾ and one or more repetition bits of another branch are received.

The middle representation of the right side of the 2 shows another way to distribute the bits ⁺ r ₁ ⁽²⁾ to the positions of the symbols of the second packet. In this case, the bits ⁺ r ₁ ^{(2) are sent} on the third branch. On the other two branches there is no transmission of information bits, but these are occupied by the receiver known symbols. This corresponds to a reduction of the modulation alphabet to two symbols. This dramatically simplifies decoding for the receiver. The distribution of the bits ⁺ r ₁ ⁽²⁾ to the positions within the symbols can then be made dependent, for example, on a reliability determined by the receiver. The repetition bits are preferably transmitted on as reliable a branch as possible, which is a branch which, depending on the partitioning, has a higher Euclidean distance than the branch used in the first transmission. In the example of 3 For example, the branch could be used for the repeat bits from which the first bit of the symbols originated. If, in addition to the bits ⁺ r ₁ ^(2), retry bits for another branch are requested, then the described procedure reduces the modulation alphabet to four symbols, in which case as reliable as possible branches for the retransmissions should be selected.

Another possibility of sending the bits ⁺ r ₁ ⁽²⁾ shows the lowest representation of the right side of the 2 , Here, the second branch, ie the branch on which the errored coded bits KB2 were originally transmitted, is used to send the bits ⁺ r ₁ ⁽²⁾ . On the first branch, the set of information bits i ₂ ⁽¹⁾ and the set of redundancy bits r ₂ ⁽¹⁾ and on the third branch the set of information bits i ₂ ⁽³⁾ and the set of redundancy bits r ₂ ^{(3) are} transmitted , This procedure can be applied analogously to the cases in which repetition bits for several branches are requested.

While the case that the bits of the parallel bit streams PS1, PS2 and PS3 have undergone both error detection coding and error correction coding before the first transmission in the encoders ENCODER1, ENCODER2 and ENCODER3 has been described so far, the method can be applied to the cases as well in which no error correction coding takes place before the first transmission. In the case of an error message NAK, then, alternatively, a mere repetition of the dispatch that has already taken place can take place, or a Transmission with increased redundancy in the form of error correction coding.

Furthermore, the encodings applied by the encoders ENCODER1, ENCODER2 and ENCODER3 need not be different. In this case, the ratio of the amount of information bits i to redundancy bits r would be, for example, the left part of 2 same for all three branches.

Claims (9)

Method for transmitting digital information between a transmitter (S) and a receiver (E), (a) on the transmitter side, dividing a serial stream (ST) of information bits into a plurality of parallel streams (PS1, PS2, PS3), the information bits of the parallel streams (PS1, PS2, PS3) are converted by coding into coded bits (KB1, KB2, KB3), the coded bits (KB1, KB2, KB3) are sent in the form of symbols (SYM) to the receiver (E) , wherein in the symbols (SYM) in each case an encoded bit (KB1, KB2, KB3) of each parallel stream (PS1, PS2, PS3) is received, characterized in that (b) transmitter side due to at least one error message (NAK) from the receiver (E) concerning received coded bits of a subset of parallel streams of the plurality of parallel streams (PS1, PS2, PS3) - coded bits (KB1, KB2, KB3) already sent in step (a) in the at least one error message (NAK) indexed coded bits and / or unsent in step (a) encoded bits are sent based on information bits of the subset of parallel streams, on which are based in the at least one error message (NAK) indexed coded bits to the receiver (E). Method according to claim 1, characterized in that that in step (a) for the information bits of at least two of the parallel streams (PS1, PS2, PS3) a different coding takes place. Method according to claim 1 or 2, characterized in that, prior to the transmission of the coded bits ( ⁺ r ₁ ⁽²⁾ ) in step (b), in each case one of the plurality of parallel streams (PS1, PS2, PS3) corresponds in number to (b) sent coded bits ( ⁺ r ₁ ⁽²⁾ ) symbols (SYM) are formed, in which one of the plurality of parallel streams (PS1, PS2, PS3) corresponding number of bits received. Method according to one of claims 1 to 3, characterized in that prior to the transmission of the coded bits ( ⁺ r ₁ ⁽²⁾ ) in step (b) respectively from a subset of the plurality of parallel streams (PS1, PS2, PS3) corresponding Number of coded bits sent in step (b) ( ⁺ r ₁ ⁽²⁾ ) symbols (SYM) into which one of the plurality of parallel streams (PS1, PS2, PS3) corresponding number of bits are received, the bits of the Symbols (SYM) which do not correspond to the coded bits ( ⁺ r ₁ ⁽²⁾ ) sent in step (b) are the same for the various symbols formed (SYM). Method according to one of claims 1 to 4, characterized in that prior to the transmission of the coded bits ( ⁺ r ₁ ⁽²⁾ ) in step (b) respectively from a subset of the plurality of parallel streams (PS1, PS2, PS3) corresponding Number of coded bits sent in step (b) ( ⁺ r ₁ ⁽²⁾ ) symbols (SYM) into which one of the plurality of parallel streams (PS1, PS2, PS3) corresponding number of bits are received, the bits of the Symbols (SYM), which do not correspond to the coded bits ( ⁺ r ₁ ⁽²⁾ ) sent in step (b), of coded bits (KB1, KB2, KB3) based on information bits of one or more parallel streams (PS1, PS2, PS3 ) with respect to which no coded bits (KB1, KB2, KB3) were previously sent. Method according to one of claims 1 to 5, characterized that the information between the transmitter (S) and the receiver (E) transmitted by radio become. Apparatus (S) for sending information to a receiver (E) comprising means for dividing a serial stream (ST) of information bits into a plurality of parallel streams (PS1, PS2, PS3), means (ENCODER1, ENCODER2, ENCODER3) for converting the information bits of the parallel streams (PS1, PS2, PS3) into coded bits (KB1, KB2, KB3) by coding, means (MAPPER) for forming symbols (SYM) from the coded bits (KB1, KB2, KB3) such that an encoded bit (KB1, KB2, KB3) of each parallel stream (PS1, PS2, PS3) is received in the symbols (SYM), means for sending the coded bits (KB1, KB2, KB3) in the form of symbols (SYM) to the receiver (E), means for receiving and evaluating at least one error message (NAK) from the receiver (E) concerning received coded bits of a subset of parallel streams of the plurality of parallel streams (PS1, PS2, PS3), and means for Sending - previously encoded bits (KB1, KB 2, KB3) in the at least one error message (NAK) indexed coded bits, and / or previously not sent coded bits based on information bits of the subset of parallel streams on which the coded bits indexed in the at least one error message (NAK) are based, due to the at least one error message (NAK) the receiver (E). Device (S) according to claim 7 with means (MAPPER) for forming symbols (SYM), in each of which at least one due the at least one error message (NAK) sent coded bit received. Device (E) for receiving information from a transmitter (S) with Means for receiving symbols (SYM) from the transmitter (S), at the transmitter side into the symbols (SYM) respectively an encoded bit (KB1, KB2, KB3) of each of a plurality of parallel currents (PS1, PS2, PS3) of information bits, Means (DECODER) for determining the correctness of the received coded bits, funds to generate and send at least one error message (NAK) concerning received coded bits of a subset of parallel streams of the Plurality of parallel streams (PS1, PS2, PS3) to the transmitter (S), Means for receiving - before already received coded bits in the at least one error message (NAK) indexed coded bits, and / or - previously not received encoded Bits based on information bits of the subset of parallel streams which indicated in the at least one error message (NAK) Based on bits from the transmitter (S).