RU2263405C1 - Method for synchronous data transfer with check communication and device for realization of said method - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: method includes leading transfer of fragment of main portion of packet of code symbols with code symbols frame, while number of repeated queries during synchronous transfer of message, data, separated on data packets with check communication.

EFFECT: higher bandwidth.

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Description

The group of inventions relates to radio engineering, in particular to a method and device for synchronous transmission of discrete data with decision feedback.

In synchronous transmission, data is transmitted in the form of data packets for equal transmission intervals. Asynchronous mode involves sending a header containing information about the duration of the transmission and / or the number of transmitted characters in the packet. A possible error in the header can lead not only to the loss of a data packet, but also to disrupt group synchronization of transmitted data packets.

The main problem is errors associated with the passage of a data packet over the air. To assess the noise immunity of data packet transmission, an additive model of Gaussian white noise is often used, which is characterized by the signal-to-noise ratio in the channel. With this approach, the probability of error in each modulation symbol is the same. The noise immunity criterion for a data transmission system is the burst error rate. In order to avoid them, use excessive coding and retransmission of data. Redundant coding is used both with error detection and error correction.

Widespread soft decoding of error correction codes, which consists in the fact that the decoder serves soft demodulator decisions about the reliability of the reception of each code symbol. Soft solutions are signed integers, for example (Viterbi A. Error limits for convolutional codes and the asymptotic optimal decoding algorithm // Sat. Some questions of coding theory. - M .: Mir, 1970, - pp. 142-165).

If an error is found that cannot be corrected, a retransmission of the data packet is requested by transmitting a request signal on the feedback channel. In the absence of errors in the data packet, a confirmation signal is transmitted via the feedback channel. These signals are transmitted periodically with a period equal to the transmission time interval. On the transmitting side, upon receipt of the signal, the request retransmits the data message packet. This process is called Automatic Repeat Request (ALR) or Decisive Feedback. They try to make the probability of an error in the feedback channel as small as possible, since an error in the feedback channel will lead to a failure of the data transmission system. Since only one binary symbol is transmitted in the return channel, in which a value of 1 corresponds to a confirmation signal, and a value of 0 corresponds to a request signal, the most effective type of modulation for synchronous data transmission will be modulation with binary opposite signals.

Depending on the purpose of the data transmission system, various requirements for transmission quality are possible. In real-time systems, retransmission of data is not possible. The direct opposite is data transmission systems, where the delay of an individual packet can be arbitrarily long, and the main task is the error-free transmission of all data packets. An example here is file transfer.

The most common are combined systems where it is possible to make only a limited number of retries, such as digital video transmission.

A known way to increase throughput is to use a hybrid automatic retransmission strategy. L. Lugand, D. Costello and R. Deng. Parity retransmission hybrid ARQ using rate 1/2 convolutional codes on a nonstationary channel // IEEE Transactions on Communications 37 (4), pp. 755-765. - 1989. The method consists in the fact that soft decisions before decoding are stored so that they can be used for repeated decoding, if necessary, and thereby increase the likelihood of successful repeated decoding. There is a classification of hybrid AZP methods. There are three types of hybrid retransmission strategies (S.Lin and D.J. Costello, Jr. Error Control Coding: Fundamentals and Applications. NJ: Englewood Cliffs. - 1983):

- Type I. The same data as the first time is transmitted. The gain is due to a decrease in the signal-to-noise ratio after summing the soft decisions in front of the decoder.

- Type II. Additional code characters are transmitted. The second package alone cannot be decoded, it is decoded only together with the first, and the second package is usually much smaller. The gain is due to increased redundancy of the code word. This method is the most promising, since it requires the least number of code symbols for retransmission.

- Type III. It is a combined type between types I and II. The imposed additional condition is that the second package is independently decodable and has the same size as the first.

In synchronous data transmission systems, methods of type 1 and 3 (type I and III) can be applied, since the size of the data packet for retransmission to them is the same as for the main transmission. But the method of type 2 is the most effective. It uses the divisibility property of the error-correcting code, which is formulated as follows:

- the code is systematic, i.e. consists of two parts: the original message and the verification characters,

- check characters can be grouped into several code groups, such that:

- the codeword, consisting of a systematic part and group 1, allows you to get a gain in noise immunity during decoding compared to an unencoded message,

- a codeword consisting of a systematic part and (N + 1) groups of test characters provides a gain in noise immunity compared to a codeword consisting of a systematic part and N groups of test characters (Jun Du, Masao Kasahara, Toshihiko Namecawa "Separable Codes on Type-2 Hybrid ARQ Systems (IEEE Transactions on communications Vol. 36, NO 10, October, 1988).

In other words, redundant symbols of the error-correcting code can be divided into several groups of code symbols, and the corrective ability of the code will depend on how many groups of test symbols have been transmitted.

When implementing this approach, there is a problem which, in the case of erroneous decoding, it is enough to transmit only a part of the redundant symbols (another group of code symbols into which the error-correcting code has been divided) in order to correctly decode the data block, however, most of the temporary the transmission interval in this case remains free, which negates the entire expected gain from a similar strategy.

The closest technical solution to the claimed invention is the invention W00237743 "Automatic Request Protocol Based Packet Transmission Using Punctured Codes", Int. C1. H 04 L 1/18, published 2002-05-10. The prototype method is as follows.

Upon receipt of a request for retransmission, a partial retransmission is formed, which is a group of previously transmitted verification characters.

Partial retransmission is introduced into the code symbol frame by reducing the redundancy of error-correcting coding in the next data packet.

With this approach, the total number of code symbols in the code symbol frame is preserved, only they belong to different data packets.

In case of erroneous decoding of the data packet, it is queued, retransmission is performed for the oldest data packet in the queue.

In the case of successful decoding of the packet of the main stream and the packet for which the retransmission was transmitted, which in this case is of a more precise nature, a complex signal is transmitted via the feedback channel, containing confirmations for both received code symbol packets.

The prototype method allows you to transmit data with a fixed speed of 1 packet / message transmission interval on the channel, where there is a non-zero probability of a packet error.

The prototype method is illustrated in figure 1, where at position A) shows the formation of a sequence of partial retransmissions that are clarifying in nature, at position B) shows the transmission of a sequence of packets over the air, at position C) the operation of storing and decoding received packets on the receiving side, positions D) show the probabilities of successful decoding with an increase in the number of partial retransmissions that are of a more precise nature. The probabilities are related by the following relation P _-1 <P ₀ <P ₁ <P ₂ .

A significant drawback of this method is that it requires a large number of resets, which leads to a loss in the characteristics of systems with a limited number of resets.

The prototype method is carried out using the transmitter 1 and receiver 8, the structural diagrams of which are made respectively in figure 2 and 3.

The transmitter 1 (FIG. 2) contains a data packet encoding unit 2, a key 3, a memory unit 4, a control unit 5, an amplifier 6 and a modulator 7, while the first input of the data packet encoding unit 2 is the first input of the transmitter 1, the first input of which is the input of the sequence of data packets, the second input of the encoding block of data packets is connected to the first output of the control unit 5, the input of which is the second input of the transmitter 1, which is the input of the decision feedback signal, the second output of the control unit 5 is connected to the first input the house of the memory unit 4, the second input of which is combined with the first input of the key 3 and connected to the output of the encoding unit of the data packets, the output of the memory unit 4 is connected to the second input of the key 3, the third input of which is connected to the third output of the control unit 5, the output of the key 3 is connected to the first input of the amplifier 6, the second input of which is the third input of the transmitter 1, the input of the power control signal, the output of the amplifier 6 is connected to the input of the modulator 7, the output of which is the output of the transmitter 1.

The receiver 8 (figure 3) contains a demodulator 9, a key 10, the first 11 and second 12 memory blocks, the adder 13, the first 14 and second 15 decoding blocks, the first 16 and second 17 error detection blocks in the code symbol packet and the control unit 18, the input of the demodulator 9 is the input of the receiver 8, the output of the demodulator 9 is connected to the first input of the key 10, the second input of which is connected to the first output of the control unit 18, the first output of the key 10 is connected to the input of the first decoding unit 14 and the first input of the first memory block 11, the second output of the key 10 is connected to the lane the input of the adder 13, the second input of which is connected to the second output of the control unit 18, the third input of the adder 13 is connected to the output of the first memory unit 11, the second input of which is connected to the first output of the adder 13, the second output of the adder 13 is connected to the input of the second decoding unit 15, the output of the first decoding unit 14 is connected to the input of the first error detection unit in the code symbol packet 16 and the first input of the second memory unit 12, the output of the second decoding unit 15 is connected to the input of the second error detection unit in the pack e code symbols 17 and the second input of the second memory unit 12, the outputs of the first 16 and second 17 error detection blocks in the code symbol package are connected respectively to the first and second inputs of the control unit 18, the third output of which is connected to the third input of the second memory unit 12, the output of which is the first output of the receiver 8, the fourth and fifth outputs of the control unit 18 are respectively the second and third outputs of the receiver 8.

символов, где Р - период выкалывания, и сохраняют их в памяти. После этого данные передаются на усилитель 6, где осуществляется регулировка мощности. Сигнал на регулировку мощности формирует блок управления 5 в зависимости от количества пакетов в блоке памяти 4. При превышении порога передача текущего пакета прекращается, полностью передается самый старый пакет в блоке памяти 4. Выходной сигнал с блока 6 поступает на вход модулятора 7. В блоке 7 модулируют пакеты кодовых символов и передают.In the transmitter 1, data packets (a pre-divided data message into data packets) are received at the first input of the encoding block of data packets 2. The second input of block 2 receives a signal from the first output of control unit 5. In block 2, the data packets are encoded with a code that detects errors and the error correction code is encoded 2. The output signal from the data packet encoding block 2 is fed to the second input of memory block 4 and the first input of key 3. According to this signal, in block 4, the result of encoding data packets is stored in memory. In the case when the control unit 5 receives negative acknowledgment of the receipt of a packet of code symbols with an error in the signal from the second output of the control unit 5 to the first input of the memory unit 4, a re-request packet is generated in the memory unit 4 for the oldest of those stored in the unit memory 4 packets of code characters. According to the signal from the third output of the control unit 5 to the third input of the key 10, the key 10 replaces the corresponding code characters of the current package with code characters from the re-request unit. Re-request packets are formed from unsystematic code components, breaking it into packets by

characters, where P is the puncture period, and store them in memory. After that, the data is transmitted to amplifier 6, where the power is adjusted. The signal for power adjustment is generated by the control unit 5 depending on the number of packets in the memory block 4. When the threshold is exceeded, the transmission of the current packet stops, the oldest packet in the memory block 4 is completely transmitted. The output signal from block 6 is input to the modulator 7. In block 7 modulate code symbol packets and transmit.

At receiver 8, the received signal is demodulated in block 9, forming soft code symbol decisions. The output signal from block 9 is fed to the first input of key 10, the second input of which receives a signal from the first output of control unit 18. Key 10 performs demultiplexing of the output data, separating data from the current packet and the reset packet. In place of punctured code symbols in the current packet, neutral values (zeros) are inserted. In the adder 13, according to the signal from the second output of the control unit 18, the corresponding symbols of the re-packet are summed with the corresponding symbols of the primary encoded packet. If the re-request packet was not previously transmitted, then the place of the corresponding characters in the primary encoded packet must be zeros. Next, the resulting sequence is overwritten in the memory of the memory block 11 and is supplied to the second decoding unit 15. The data of the current packet are supplied to the first decoding unit 14. The output signals from the first 14 and second 15 decoding units are received respectively at the first and second inputs of the second memory block 12 and, accordingly, the inputs of the first 16 and second 17 error detection blocks in code symbol packets. In blocks 16 and 17, error detection in code symbol packets is performed. In the second memory block 12, correctly decoded packets are stored. It serves to ensure the correct data order. If the packet is decoded correctly, then it is deleted from the first memory block 11. The control unit 18 from the fourth and fifth outputs transmits confirmation of the receipt of two packets: the current and the one for which the re-transmission was transmitted.

A significant drawback of the described device is that it is designed in such a way that requires a large number of retries - this leads to a loss in the characteristics of systems with a limited number of retries.

The problem that is solved by the claimed method and device for its implementation is to increase the throughput of the data transmission system, in particular, in a system with a limited number of re-requests.

The problem is solved in that in a method of synchronous data transmission with crucial feedback, namely, that

- on the transmitting side, the data message is divided into data packets;

- encode data packets with a code that detects errors, and with a code that corrects errors, forming packets of code symbols;

- divide each received packet of code symbols into groups of code symbols and assign the order of transmission of groups of code symbols;

- for each package of code symbols from the groups of code symbols, in accordance with the assigned transmission sequence, the main and refinement parts of the code symbol packet are formed, while the same groups of code symbols can simultaneously be included in the main and refinement parts of the code symbol packet;

- form frames of code symbols, including in each frame different parts of different packets of code symbols in such a way that, if there are requests, the frame of code symbols contains the main part of the transmitted packet and the clarifying part of one of the previous packets or only the clarifying part of one of the previous packets;

- modulate and transmit the generated frames of code symbols over the air;

- at the receiving side, the received signal is demodulated, forming soft code symbol decisions;

- for each packet of code symbols, parts of which are included in the received frame of code symbols, soft decisions on code symbols of the main part and soft decisions on code symbols of all received refinement parts of this code code packet are combined, a code symbol packet is decoded and errors are detected in the decoded packet ;

- if the packet of code symbols is decoded with an error, a decision is made to request the next qualifying part of the packet of code symbols of this packet and the soft decisions about the code symbols of this packet are stored, forming a queue of packets decoded with an error;

- if the packet of code symbols is decoded without errors, then a decision is made to confirm the receipt of this packet and the soft decisions about the code symbols of this packet are removed from the queue of packets decoded with an error, provided that they were saved during previous decodings;

- based on the decisions made, a feedback signal is generated and transmitted at a specified time to the transmitting side;

- if there is at least one request for the transmission of the refinement of the code symbol packet, and the number of outstanding requests does not exceed a predetermined value, then on the transmitting side the main part of the next code symbol packet is reduced and the next frame is formed from the reduced main part of the next code symbol packet and another qualifying part of the first packet of code symbols from the queue of packets decoded with an error;

- otherwise, the next frame is formed only from the next clarifying parts of the first packet of code symbols from the queue of packets decoded with an error;

according to the invention, in the absence of outstanding requests for the transmission of the qualifying part of any of the code symbol packets, the main part of the next code symbol packet is transmitted ahead of schedule, for which:

- reduce the main part of the next packet of code symbols and form the next frame of the reduced main part of the next packet of code symbols and a fragment of the main part of the next packet, occupying the remainder of the frame of code symbols;

- the following frames are formed from the non-transmitted remainder of the reduced main part of the next packet of code symbols and a fragment of the main part of the next packet, thus increasing the amount of data transmitted ahead of time,

- and in the case of receiving a packet with an error, instead of the next leading groups of code symbols, the groups of code symbols are refined for the data packet in which the error occurred during decoding.

Moreover, if the amount of data transmitted ahead of time reaches a predetermined value, then the following frames are formed from the non-transmitted remainder of the full main part of the next packet of code symbols and a fragment of the main part of the next packet.

If the amount of data reaches a value sufficient for independent decoding, then it is decoded, and when decoding without error, the following frames are formed from a reduced at least one group of code symbols of the main part of the next packet of code symbols and a fragment of the main part of the next packet.

Moreover, confirmation on decoding the leading part is transmitted as part of the feedback signal instead of confirmation on the clarifying part.

The problem is also solved due to the fact that the synchronous data transmission device with decision feedback containing a transmitter that contains a data packet encoding unit, a key, a memory unit, a control unit and a modulator, while the first input of the data packet encoding unit is the first input the transmitter and, accordingly, the input of the data packets, the second input of the encoding block of the data packets is connected to the first output of the control unit, the input of which is the second input of the transmitter and, accordingly, the signal input la decisive feedback, the second output of the control unit is connected to the first input of the memory unit, the second input of which is connected to the output of the encoding unit of data packets, the third output of the control unit is connected to the first input of the key, the output of the modulator is the output of the transmitter, and the receiver, which contains a demodulator , the key, the first and second memory blocks, the first and second decoding blocks, the first and second error detection blocks in the code symbol packet and the control unit, while the demodulator input is the receiver input, output d the modulator is connected to the key input, the output of the first decoding unit is connected to the input of the first error detection unit in the code symbol package and the first input of the second memory unit, the output of the second decoding unit is connected to the input of the second error detection unit in the code symbol package and the second input of the second memory unit, the third input of which is connected to the first output of the control unit, the output of the second memory unit is the first output of the receiver, the outputs of the first and second error detection units in the code symbol packet in connected respectively with the first and second inputs of the control unit, the second output of which is the second output of the receiver;

according to the invention introduced:

to the transmitter, a code symbol packet selection block for transmission and a code symbol packet forming block for transmission, the first input of the code symbol packet selection block for transmission is connected to the output of the memory unit, the second input of the code symbol packet selection block for transmission is connected to the fourth output of the block control, the first and second outputs of the block selection of code symbols for transmission are connected respectively to the first and second inputs of the block forming parts of the packets of code symbols for transmission, third input coupled to the fifth output of the control unit, the first and second outputs forming unit parts packet code symbols for transmission are connected respectively to the third and fourth key inputs, whose output is connected to the input of the modulator;

to the receiver, the first and second blocks combining parts of the code symbol packets, the first inputs of which are connected respectively with the first and second outputs of the key, the second inputs of the first and second blocks combining parts of the code symbol packets are connected, respectively, with the first and second outputs of the first memory block, the third input of which is combined with the input of the first decoding unit and connected to the output of the first unit combining parts of the code symbol packets, the fourth input of the first memory unit is combined with the input of the second decoder tion and connected to the output of the second combining unit parts packet code symbols, the third inputs of the first and second blocks of combining parts packet code symbols are respectively connected to third and fourth outputs of the control unit.

The essence of the claimed group of inventions is to initiate the process of combining groups of code symbols belonging to different data packets, not only in case of unsuccessful decoding, where the next data packet is supplemented by a group of code symbols for a packet decoded with an error, but also upon successful decoding of the data packet supplementing it with leading groups of code symbols of the next data packet. The claimed invention provides a backlog in the transmitted code symbols. In the case of receiving a packet with an error, instead of the next leading groups of code symbols, a refinement of the transmission of code symbol groups is carried out for the data packet in which the error occurred during decoding.

The technical result of reducing the number of required retries is achieved due to the following factors:

- reducing the quality requirements of the first reception, which allows you to organize advanced transmission of groups of code symbols of the next packet;

- Strengthening the requirements for reception quality after the first re-request, which is possible due to the fact that the qualifying groups for the packet decoded with an error are transmitted instead of the leading groups of the next packet.

Conducted patent and scientific and technical studies in this technical field did not reveal the features claimed in the characterizing part of the claims, therefore, the claimed method and device, created in a single inventive concept, have novelty in comparison with the known technical solutions that meet the criterion of "inventive step" and can be implemented in data transmission systems with a limited number of possible re-requests, while maintaining the main property - the transfer of data blocks with the maximum access Izhimei speed data transmission system: 1 packet / transmission interval.

The description of the invention is illustrated by examples and drawings.

Figure 1 illustrates a prototype method, which shows a partial retransmission with its placement in the next packet of code symbols.

Figure 2 is a structural diagram of the transmitter of the prototype device.

Figure 3 is a block diagram of the receiver of the prototype device.

Figure 4 illustrates the operation of the proposed method for synchronous data transmission with crucial feedback.

Figure 5 is a structural diagram of a transmitter of the inventive device for synchronous data transmission with crucial feedback.

Figure 6 is a block diagram of the receiver of the inventive device for synchronous data transmission with crucial feedback.

The inventive synchronous data transmission device with decision feedback (Fig. 5) comprises a transmitter 1 comprising a data packet encoding unit 2, a key 3, a memory unit 4, a control unit 5 and a modulator 7, the first input of the data packet encoding unit 2 being the first the input of the transmitter 1, the second input of the encoding unit of data packets 2 is connected to the first output of the control unit 5 whose input is the second input of the transmitter 1, the second output of the control unit 5 is connected to the first input of the memory unit 4, the second input of which is connected to during the course of the encoding unit for data packets 2, the third output of the control unit 5 is connected to the first input of the key 3, the output of the modulator 7 is the output of the transmitter 1, according to the invention, the transmitter 1 further comprises a block for selecting code symbol packets for transmission 19 and a block for generating parts of code symbol packets for transmission 20, wherein the first input of the code symbol packet selection block for transmission 19 is connected to the output of the memory unit 4, the second input of the code symbol packet selection block for transmission 19 is connected to the fourth output of the block board 5, the first and second outputs of the code symbol packet selection block for transmission 19 are connected respectively to the first and second inputs of the code symbol packet forming block for transmission 20, the third input of which is connected to the fifth output of the control unit 5, the first and second outputs of the part forming block packets of code symbols for transmission 20 are connected respectively to the third and fourth inputs of the key 3, the output of which is connected to the input of the modulator 7.

The inventive synchronous data transmission device with decision feedback (Fig. 6) comprises a receiver 8 comprising a demodulator 9, a key 10, a first 11 and a second 12 memory blocks, the first 14 and second 15 decoding blocks, the first 16 and second 17 error detection blocks in a code symbol packet and a control unit 18, wherein the input of the demodulator 9 is the input of the receiver 8, the output of the demodulator 9 is connected to the input of the key 10, the output of the first decoding unit 14 is connected to the input of the first error detection block in the code symbol packet 16 and the first input of the second about the memory unit 12, the output of the second decoding unit 15 is connected to the input of the second error detection unit in the code symbol packet 17 and the second input of the second memory unit 12, the third input of which is connected to the first output of the control unit 18, the output of the second memory unit 12 is the first output of the receiver 8, the outputs of the first 16 and second 17 error detection blocks in the code symbol packet are connected respectively to the first and second inputs of the control unit 18, the second output of which is the second output of the receiver 8, according to the invention ik additionally contains the first 21 and second 22 blocks combining parts of the code symbol packets, the first inputs of which are connected respectively with the first and second outputs of the key 10, the second inputs of the first 21 and second 22 blocks combining parts of the code symbol packets are connected with the first and second outputs of the first block memory 11, the third input of which is combined with the input of the first decoding unit 14 and connected to the output of the first unit of combining parts of the code symbol packets 21, the fourth input of the first memory block 11 is combined to the input of the second decoding unit 15 and is connected to the output of the second combining unit parts packet code symbols 22, third inputs of first 21 and second 22 units combining parts packet code symbols are respectively connected to third and fourth outputs of the control unit 18.

A synchronous data transmission method with decisive feedback is implemented as follows:

- on the transmitting side, the data message is divided into data packets;

- encode data packets with a code that detects errors, and with a code that corrects errors, forming packets of code symbols;

- divide each received packet of code symbols into groups of code symbols and assign the order of transmission of groups of code symbols;

- for each package of code symbols from the groups of code symbols, in accordance with the assigned transmission sequence, the main and refinement parts of the code symbol packet are formed, while the same groups of code symbols can simultaneously be included in the main and refinement parts of the code symbol packet;

- form frames of code symbols, including in each frame different parts of different packets of code symbols in such a way that, in the presence of re-requests, the frame of code symbols contains the main part of the transmitted packet and the clarifying part of one of the previous packets, or only the clarifying part of one of the previous packets;

- modulate and transmit the generated frames of code symbols over the air;

- at the receiving side, the received signal is demodulated, forming soft code symbol decisions;

- for each packet of code symbols, parts of which are included in the received frame of code symbols, soft decisions on code symbols of the main part and soft decisions on code symbols of all received refinement parts of this code code packet are combined, a code symbol packet is decoded and errors are detected in the decoded packet ;

- if the packet of code symbols is decoded with an error, a decision is made to request the next qualifying part of the packet of code symbols of this packet and the soft decisions about the code symbols of this packet are stored, forming a queue of packets decoded with an error;

- if the packet of code symbols is decoded without errors, then a decision is made to confirm the receipt of this packet and the soft decisions about the code symbols of this packet are removed from the queue of packets decoded with an error, provided that they were saved during previous decodings;

- based on the decisions made, a feedback signal is generated and transmitted at a specified time to the transmitting side;

- if there is at least one request for transmitting the refinement of the code symbol packet and the number of outstanding requests does not exceed a predetermined value, then on the transmitting side the main part of the next code symbol packet is reduced and the next frame is formed from the reduced main part of the next code symbol packet and the next qualifying part of the first packet of code symbols from the queue of packets decoded with an error;

- otherwise, the next frame is formed only from the next clarifying parts of the first packet of code symbols from the queue of packets decoded with an error;

- in the absence of outstanding requests for the transfer of the qualifying part of any of the code symbol packets, the main part of the next code symbol packet is transmitted ahead of schedule, for which:

- reduce the main part of the next packet of code symbols and form the next frame of the reduced main part of the next packet of code symbols and a fragment of the main part of the next packet, occupying the remainder of the frame of code symbols;

- the following frames are formed from the non-transmitted remainder of the reduced main part of the next packet of code symbols and a fragment of the main part of the next packet, thus increasing the amount of data transmitted ahead of time.

Moreover, if the amount of data transmitted ahead of time reaches a predetermined value in advance, then the following frames are formed from the non-transmitted remainder of the full main part of the next packet of code symbols and a fragment of the main part of the next packet.

If the amount of data reaches a value sufficient for independent decoding, then it is decoded, and when decoding without error, the following frames are formed from a reduced at least one group of code symbols of the main part of the next packet of code symbols and a fragment of the main part of the next packet.

Moreover, confirmation on decoding the leading part is transmitted as part of the feedback signal instead of confirmation on the clarifying part.

Consider in more detail the implementation of the proposed method on a synchronous data transmission device with crucial feedback, the structural diagram of which is made in FIGS. 5 and 6.

On the transmitting side, the data message is divided into data packets using, for example, a physical layer packet switch operating in accordance with the OSI standard (Reference Model for Open Systems Interconnection. - RM-OSI / ITU-T X.200 (1994) ; ISO / IEC 7498. - 1, 2, 3, 4: 1994.).

Using the control signal (bus) from the first output of control unit 5 in block 2, data packets are encoded with an error-detecting code, using, for example, CRC (cyclical redundancy check), (S.Lin and DJCostello, Jr.) Error Control Coding: Fundamentals and Applications. NJ: Englewood Cliffs, - 1983), and error-correcting code, using, for example, any of the class of convolutional codes, in particular, a parallel convolutional turbo code (C. Berrou, A Glaviex, P. Thitimajshma. Near Shannon limit error - correcting coding and decoding // IEEE Transactions on information theory. - 2/1993), forming packages of code systems oxen, storing packets received code symbols, forming a queue of packets stored code symbols to be transferred to the memory unit 4.

Each stored code symbol packet is split into equal code symbol groups and the transmission order of code symbol groups is assigned in accordance with one of the known methods, for example (J. Hagenauer. Rate Compatible Punctured Convolutional Codes (RCPC Codes) and their Applications // IEEE Trans. Commun ., Vol. 36, Apr. 1988, pp. 389-400 or DN Rowitch and LB Milstein. Rate Compatible Punctured Turbo (RCPT) Codes in a Hybrid FEC / ARQ System // in Proc. Communications Theory Mini-Conference of GLOBECOM ' 97.- Phoenix, AZ, Nov. 1997. - pp. 55-59). The operation is carried out in the block selection of code symbol packets for transmission 19.

The main frame of the code symbols includes only the main part of the first packet of code symbols or a variant is possible in which the encoding is started in advance, thereby ensuring a sufficient length of the queue of packets of code symbols for transmission, and the first frame of code symbols consists of a reduced main part of the first packet and the leading part the next packet after the presence of this packet in the queue of packets of code symbols for transmission.

The selection of packets for transmission is carried out by the code symbol packet selection block for transmissions 19, which, in accordance with the base address in the memory block 4, received from the control unit 5, determines the necessary address offset and remembers the location of the selected blocks in the memory block 4 and transcribes the selected packets into the memory block 19.

For each of the selected code symbol packets, in accordance with the assigned sequence of transmission of the code symbol groups, the main and refinement parts of the code symbol packet are formed, thus highlighting the HARQ-2 blocks and remembering the addresses at which they are located in memory block 4 and the internal memory of the block selecting code symbol packets for transmission 19 and rewriting the selected parts in the memory of block 20, noting the number of transmissions made for each of the selected groups of code symbols.

If all parts of the code symbol packet are marked as transmitted, then an additional qualifying part of the code symbol packet is formed, cyclically repeating the sequence of code symbol groups in accordance with the previously assigned sequence, while incrementing the transmission counter of each group in the code block packet generation block for transmission 20.

In block 20, code symbol frames are generated, including, in each frame, different parts of different code symbol packets by multiplexing with key 3, in accordance with the sequence of received acknowledgments on the reception of previous packets, so that in the presence of outstanding requests for refinement transmission, there are no more than N packets form the next frame of code symbols from a code group symbol reduced by at least one group of code symbols of the main part of the next packet received from the code symbol packet selection block and at least one group from the qualifying part for a code symbol packet transmitted earlier of the remaining packets for which there is a request to transmit additional code symbols and which form a queue of transmitted code symbol packets in the memory block 4, the selection of which is carried out in the packet selection block code characters for transmission 19.

If there are requests for a refinement transmission of more than N packets, the next frame of code symbols is formed from the groups of the refinement part or an additional refinement part for a packet transmitted earlier than the remaining packets for which there are requests for a refinement transmission, the selection of which is carried out in the block for selecting code symbol packets for transmission 19.

At the same time, according to the signal from the control unit 5, the next data packet is encoded in the encoding block of data packets 2 and stored in the memory block 4, thus increasing the queue of packets of code symbols for transmission in the memory block 4.

Packets of code symbols, the main part of which is included in the frame of code symbols, are transferred from the queue of packets of code symbols for transmission in the memory unit 4 to the queue of transmitted packets of code symbols in the memory unit 4. The operation is performed by the block of selection of code symbol packets for transmission 19. The operation may be made by storing in the block selection of the packet for transmission 19 of the separating address in the memory block 4 so that the addresses of packets smaller than the stored address are defined as packets of code symbols for transmission, and packets address more defined as the transmitted packets or perform operations instead of physical addresses with reference to these addresses (Knut "Art of Computer Programming" publishing house "Williams" 2002, 720 pp.), or any other known memory management techniques.

Packets of code symbols for which an acknowledgment of receipt has been received is removed from the queue of transmitted packets, after which redistribution of the arrangement of packets of code symbols or links to them in memory is carried out.

In the absence of outstanding requests for the transmission of the qualifying part of any of the code symbol packets, the main part of the next code symbol packet is transmitted ahead of time, if such a packet is in the packet queue for transmission, its presence is determined by the block for selecting code symbol packets for transmission 19.

In the block forming part of the code symbol packets for transmission 20, the main part of the next code symbol packet is reduced by at least one group of code symbols.

In the unit for forming parts of code symbol packets for transmission 20, the leading part of a given code symbol packet is formed from a fragment of the main part of this code symbol packet, selecting at least one group of code symbols in it in accordance with a predetermined sequence.

In the block forming part of the code symbol packets for transmission 20, the next code symbol frame is generated by multiplexing from the reduced main part of the next code symbol packet and the leading part of the next packet from the code symbol packet queue for transmission, which occupies the remainder of the code symbol frame.

In the block forming the parts of the code symbol packets for transmission 20, in the presence of a confirmation of receipt of the packet by the signal from the fifth output of the control unit 5, the following code symbol frames are generated by multiplexing. The code symbol frames are formed from the non-transmitted remainder of the reduced main part of the next code symbol packet and increased by at least one group of code symbols of the leading part of the next code symbol packet from the packet queue for transmission, thus increasing the amount of data transmitted ahead of schedule .

In block 7, code symbol frames are modulated and the generated code symbol frames are transmitted over the air.

The receiver 8 (Fig.6) receives a signal that is input to the demodulator 9. In the demodulation unit 9, the received signal is demodulated, forming soft decisions about code symbols.

In the first block combining the parts of the code symbol packet 21, soft code decisions of all the accepted parts of each code symbol packet are combined, the parts of which are included in the received code symbol frame if the main part of this packet was part of the received frame, and the result of combining is stored in the first block memory 11. Combining is carried out by one of the known methods, for example (D. Chase. Code Combining - A Maximum-Likelihood Decoding Approach for Combining an Arbitrary Number of Noisy Packets // IEEE Trans. Comm., vol. 33, pp. 385-393 . - May 1985) or (L. Lugand, D. Costello and R. Deng. Parity retransmission hybrid ARQ using rate 1/2 convolutional codes on a nonstationary channel // IEEE Transactions on Communications 37 (4), pp. 755-765. - 1989).

In the second block combining the parts of the code symbol packets 22, soft decisions about the code symbols of all the accepted parts of each code symbol packet are combined, the parts of which are included in the received code symbol frame if the received frame included a qualifying or leading part of this packet, and the result of combining is stored in first memory block 11.

In the first decoding unit 14, the code symbol packet that was generated in the first block for combining parts of the code symbol packets 21 is decoded and stored in the second memory block 12. In the first error detection block in the code symbol packet 16, the error is decoded in the block 14 a packet of code symbols and transmit the test results to the first input of the control unit 18, which determines the data packet ready for output in the second memory block 12. The data packet is ready for output if there is no erroneously decoded s packets that were transmitted earlier than the above packet. Thus, the operation of alignment of the decoded data in the second memory block 12 is carried out.

In the second decoding unit 15, the code symbol packet that was generated in the second block for combining portions of the code symbol packets 22 is decoded and stored in the second memory block 12.

In the second block for detecting errors in the code symbol packet 17, the presence of errors in the code symbol packet decoded in block 15 is checked and the test results are transmitted to the second input of the control block 18, which determines the data packet ready for output in the second memory block 12. The data packet is ready for output, if there are no erroneously decoded packets that were transmitted earlier than the above packet. Thus, the operation of alignment of the decoded data in the second memory block 12 is carried out.

If, in the first decoding block 14, the code symbol packet is decoded with an error, a decision is made to request the next qualifying part of the code symbol packet of this packet and soft decisions about the code symbols of this packet are stored, forming a queue of packets decoded with an error in the first memory block 11.

If, in the second decoding unit 15, the code symbol packet is decoded with an error, a decision is made to request the next qualifying part of the code symbol packet of this packet and soft decisions about the code symbols of this packet are stored, forming a queue of packets decoded with an error in the first memory block 11.

If in the first decoding unit 14 the code symbol packet is decoded without errors, then a decision is made to confirm the receipt of this packet and soft decisions about the code symbols of this packet are removed from the queue of packets decoded with an error, provided that they were saved during previous decoding in the first memory unit 11.

If in the second decoding unit 15 the code symbol packet is decoded without errors, then a decision is made to confirm the reception of this packet and soft decisions about the code symbols of this packet are removed from the queue of packets decoded with an error, provided that they were saved during previous decoding in the first memory unit 11.

If in the second decoding unit 15 the amount of data transmitted ahead of time is sufficient for decoding, then it is decoded independently, in the absence of errors on the receiving side, and soft decisions about the code symbols of this packet are removed from the packet queue in the first memory block 11, the decoded data is stored in the second memory unit 12 according to the results of the verification in the second error detection unit in the code symbol packet 17. The control unit 18 generates and sends an acknowledgment signal for this code symbol packet in the reverse channel alu. Upon receipt of this confirmation on the transmitting side, the control unit 5 generates a corresponding signal by which this frame is removed from the code symbol packet queue for transmission in the memory unit 4. If in the second decoding unit 15 the amount of data transmitted ahead of time is insufficient for decoding on the transmitting side, when transmitting the remaining packets of code symbols, the leading part of each subsequent packet of code symbols is increased until the volume of this part reaches a predetermined value. After that, the following frames are formed from the non-transmitted remainder of the full main part of the next packet of code symbols and the same leading part of the next packet from the packet queue for transmission in the block of packet code packet generation for transmission 20 by multiplexing with key 3.

The control unit 18 on the receiving side (in the receiver 8), based on the decisions made by the first 16 and second 17 error detection blocks in the code symbol packet, generates a feedback signal and transmits it at a set point in time to the transmitting side (transmitter 1), and the feedback signal is complicated i.e. carries information about the decisions for each of the error detection blocks in the code symbol packet.

The control unit 18 in the receiver, if there is confirmation of successful decoding of the leading part, which is received in the second error detection block in the code symbol packet 17, generates a complex feedback signal so that the decision on the leading part is transmitted instead of the decision on the clarifying part, the transmission request of which actually was not.

The extension of the leading part of the fragment of the main part of the code symbol packet as a part of the code symbol frame is shown in FIG. 3, which shows the code symbol frame composed of parts of different packets, the presence of packets in the first block of the receiving device before and after receiving and decoding packets of code symbols included into a frame of code characters. Position A) shows the transmission of only the main part of the code symbol packet as part of the code symbol frame. Position B) shows the transmission of the reduced main part of the code symbol packet and one leading group of the next code symbol packet. At position C), the transmission of the non-transmitted remainder of the main part of the code symbol packet and two leading groups of the next code symbol packet is shown. Position D) shows the transmission of the unreported remainder of the main part of the code symbol packet and three leading groups of the next code symbol packet.

In practice, the transmitter 1 and receiver 8 can be implemented on a digital processor and a programmable logic integrated circuit, or a mixed implementation on the two aforementioned devices can be implemented.

Thus, due to the forward transmission of a fragment of the main part of the code symbol packet as a part of the code symbol frame, it is possible to reduce the number of retransmissions when synchronously transmitting a data message divided into data packets with decisive feedback, thereby increasing the throughput of the radio data transmission system as a whole.

Claims (5)

1. The method of synchronous data transmission with crucial feedback, namely, that on the transmitting side, the data message is divided into data packets, the data packets are encoded with an error detecting code and error correction code, forming code symbol packets, each received packet is broken code symbols into groups of code symbols and designate the transmission order of groups of code symbols, for each package of code symbols from groups of code symbols in accordance with the assigned transmission sequence of the form the main and refinement parts of the code symbol packet, while the same groups of code symbols can simultaneously be included in the main and refinement parts of the code symbol packet; if there are requests for retransmission, code symbol frames are generated, including different parts of different packets in each frame code symbols so that the frame of code symbols contains the main part of the transmitted packet and the qualifying part of one of the previous packets or only the clarifying part of one of the previous packets, modulate and the generated code symbol frames are transmitted over the radio channel, the received signal is demodulated at the receiving side, forming soft code symbol decisions for each code symbol packet, parts of which are included in the received code symbol frame, soft code code decisions of the main part and soft code symbol decisions are combined of all received refinement parts of a given code symbol packet, decode the code symbol packet and check for errors in the decoded packet if the code symbol packet is decoded with error In this case, they decide to request the next qualifying part of the packet of code symbols for this packet and remember soft decisions about the code symbols of this packet, forming a queue of packets decoded with an error, if the packet of code symbols is decoded without errors, then they make a decision to confirm the reception of this packet and delete soft decisions about the code symbols of a given packet from the queue of packets decoded with an error, provided that they were saved during previous decodings, form a signal about call and transmit it at a specified time to the transmitting side, if there is at least one request for transmission of the qualifying part of the code symbol packet and the number of outstanding requests does not exceed the predetermined value, then the main part of the next code symbol packet is reduced on the transmitting side and form the next frame from the reduced main part of the next packet of code symbols and the next qualifying part of the first packet of code symbols from the queue of packets decoded with an error, in contrast in the case, the next frame is formed only from the next qualifying parts of the first code symbol packet from the queue of packets decoded with an error, characterized in that in the absence of unfulfilled requests to transmit the clarifying part of any of the code symbol packets, the main part of the next code symbol packet is transmitted ahead of time why reduce the main part of the next packet of code symbols and form the next frame from the reduced main part of the next packet of code symbols and a fragment of the main part of the next packet, which occupies the rest of the frame of code symbols, the following frames are formed from the unsent balance of the reduced main part of the next packet of code symbols and a fragment of the main part of the next packet, thus increasing the amount of data transmitted ahead of time, and if the packet is received with an error instead The next leading groups of code symbols carry out the refinement of the transmission of groups of code symbols for the data packet in which an error occurred during decoding. 2. The method according to claim 1, characterized in that if the amount of data transmitted ahead of time reaches a predetermined value, then the following frames are formed from the unsolicited remainder of the full main part of the next packet of code symbols and a fragment of the main part of the next packet. 3. The method according to claim 1, characterized in that if the amount of data reaches a value sufficient for independent decoding, then it is decoded and when decoding without error, the following frames are formed from at least one group of code symbols of the main part of the next packet code characters and a fragment of the main part of the next package. 4. The method according to claim 3, characterized in that the confirmation on decoding the leading part is transmitted as part of the feedback signal instead of confirmation on the clarifying part. 5. A synchronous data transmission device with decisive feedback, comprising a transmitter that comprises a data packet encoding unit, a key, a memory unit, a control unit and a modulator, wherein the first input of the data packet encoding unit is the first input of the transmitter and, accordingly, the input of data packets , the second input of the encoding unit of the data packets is connected to the first output of the control unit, the input of which is the second input of the transmitter and, accordingly, the input of the decision feedback signal, the second output of the control unit A line is connected to the first input of the memory block, the second input of which is connected to the output of the data packet encoding block, the third output of the control unit is connected to the first input of the key, the modulator output is the output of the transmitter, and the receiver, which contains the demodulator, key, first and second memory blocks, the first and second decoding blocks, the first and second error detection blocks in the code symbol packet and the control unit, wherein the demodulator input is the receiver input, the demodulator output is connected to the key input, the output of the first the decoding eye is connected to the input of the first error detection unit in the code symbol packet and the first input of the second memory block, the output of the second decoding unit is connected to the input of the second error detection unit in the code symbol packet and the second input of the second memory block, the third input of which is connected to the first output of the block control, the output of the second memory block is the first output of the receiver, the outputs of the first and second error detection blocks in the code symbol packet are connected respectively to the first and second inputs a control unit, the second output of which is the second output of the receiver, characterized in that a code block for selecting code symbols for transmission and a block for generating parts of code symbol packets for transmission are input to the transmitter, wherein the first input of the code symbol packet selection block for transmission is connected to the output of the block memory, the second input of the code symbol packet selection block for transmission is connected to the fourth output of the control unit, the first and second outputs of the code symbol packet selection block for transmission are connected respectively Actually, with the first and second inputs of the code symbol packet forming block for transmission, the third input of which is connected to the fifth output of the control unit, the first and second outputs of the code symbol packet forming block for transmission are connected to the third and fourth inputs of the key, the output of which is connected to modulator input; the first and second blocks of combining parts of code symbol packets are introduced into the receiver, the first inputs of which are connected respectively to the first and second outputs of the key, the second inputs of the first and second blocks of combining parts of code symbol packets are connected to the first and second outputs of the first memory block, the third input of which combined with the input of the first decoding unit and connected to the output of the first block combining parts of the code symbol packets, the fourth input of the first memory block is combined with the input of the second block and decoding and is connected to the output of the second combining unit parts packet code symbols, the third inputs of the first and second blocks of combining parts packet code symbols are respectively connected to third and fourth outputs of the control unit.

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