RU2239952C1 - Method for transferring messages in systems with feedback - Google Patents

Abstract

FIELD: communications technology.

SUBSTANCE: method includes transferring shortened interference resistant cascade code, on receiving side of communication system on basis of results of decoding of inner code of shortened interference resistant cascade code number of additional words of inner code of interference resistant cascade code, necessary for correct decoding of outer code of interference resistant cascade code and then a query is formed for transfer of these additional words of inner code of interference resistant cascade code.

EFFECT: higher speed of information transfer in communication channel and simplified hardware and software realization of method.

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Description

The invention relates to the field of communication technology and can be used to send and receive messages protected by a correction code, in particular a noise-resistant cascading code.

The method is used in feedback systems. In these systems, to increase the likelihood of receiving a message, at the request of the receiving side, retransmit received messages. At the same time, for a significant part of unaccepted messages, based on the results of decoding the error-correcting code, you can evaluate the quality of message reception and retransmit only that part of the information that is necessary to recover unaccepted messages taking into account previously transmitted information (reception with accumulation). The most effectively proposed method can be used in the case of the transmission of messages protected by noise-resistant cascading code. In this case, the quality of message reception is evaluated by decoding the words of the internal code of the cascading code, and it is possible to determine not only the number of erased words of the internal code, but also approximately estimate the number of transformed words. The method can be effectively used to transmit large amounts of digital information, for example, for transmitting and receiving video images in facsimile communication systems. A significant role in such systems is played by video transmission time. The video transmission time is the sum of the video transmission time and the retransmission time of unaccepted portions of the video image. The proposed method is aimed at solving the urgent problem of reducing the time of retransmission of information, in particular, unaccepted fragments of a video image.

A known method of transmitting messages, in which on the transmitting side the array of input information is divided into blocks of a certain length, which are encoded with an error-correcting code and then transmitted to the communication channel. An error-correcting code with error detection is decoded on the receiving side. If errors are detected in the error-correcting code, a request for retransmission of the error-correcting code is generated. This request is transmitted via the feedback channel to the transmitting side. Upon request, a retransmission of an unaccepted error-correcting code is performed [1].

The disadvantage of this method is the decrease in the transmission rate of information, due to the fact that when retransmitting the unaccepted code words are transmitted entirely, which can lead to a significant increase in the total amount of information transmitted over the communication channel.

Closest to the proposed method is a method (prototype) for transmitting messages in a feedback system, according to which, on the transmitting side of the communication system, the input information array is divided into blocks of a certain length, which are encoded by an error-correcting code and then transmitted to the communication channel. On the receiving side of the communication system, the error-correcting code is decoded with error detection and correction. If errors are detected in the error-correcting code, the multiplicity of which lies outside the correcting ability of the error-correcting code, a request is sent to transmit additional symbols of the error-correcting code. This request is transmitted via the feedback channel to the transmitting side. Upon request, additional symbols of the error-correcting code are transmitted. Further, upon receipt of additional symbols of the error-correcting code, the code is re-decoded [2].

The disadvantage of this method is the low speed of information transmission over the communication channel and the complexity of the implementation of the method, since the number of additional symbols of the error-correcting code required for correct decoding is not estimated, and several transmission of additional symbols and, accordingly, several attempts to decode the error-correcting code may be required. This can lead to an increase in the amount of information transmitted over the communication channel and to the complexity of the method.

The purpose of the invention is to increase the information transfer rate and simplify the method, due to the fact that a shortened error-correcting code is transmitted in the communication channel and, depending on the quality of the communication channel, only the number of additional symbols of the error-correcting code necessary for repeated decoding is transmitted, which reduces the total amount of information transmitted over the communication channel and reduces the number of retries of decoding the error-correcting code.

To achieve the goal, a method is proposed, which consists in the fact that on the transmitting side of the communication system, the input information array is divided into blocks of a certain length, which are encoded with an error-correcting code and then transmitted to the communication channel. On the receiving side of the communication system, an error-correcting code is decoded with error detection and correction. If errors are detected in the error-correcting code, the multiplicity of which lies outside the correcting ability of the error-correcting code, a request is made for retransmission of the error-correcting code. This request is transmitted via the feedback channel to the transmitting side. Upon request, additional symbols of the error-correcting code are transmitted. Then, upon receiving additional symbols of the error-correcting code, the code is re-decoded. What is new is that a shortened noise-resistant cascade code is transmitted to the communication channel, on the receiving side of the communication system, the number of erased words of the internal code is first determined by the results of decoding the internal code of the shortened noise-resistant cascade code, then the number of transformed words of the internal code is estimated, then the number of additional words of the internal code is determined error-correcting cascade code required to correctly decode the external error-correcting cascade code code and form a request for the transmission of these additional words of the internal code of the noise-resistant cascading code.

The drawing shows a sequence of operations illustrating the process of processing input information on the transmitting and receiving sides of the communication channel.

The proposed method for transmitting messages in a feedback system is implemented as follows.

On the transmitting side, a shortened error-correcting code is generated, for example, a shortened error-correcting cascade code. To do this, on the transmitting side, the original message, with a volume of k m-ary (m> 1) characters, is first encoded with an m-ary noise-resistant code, for example, an m-ary noise-resistant Reed-Solomon code. The Reed-Solomon code is the external code or the code of the first stage of the noise-resistant cascading code. The Reed-Solomon code defined over the Galois field GF (2 ^m ) generally consists of 2 ^m -1 characters. The shortened Reed-Solomon code is formed from n <2 ^m -1 characters of the Reed-Solomon code. In practice, shortened Reed-Solomon codes are often used to transmit messages on a communication channel. The Reed-Solomon code is the code with the maximum achievable minimum code distance (MDS code). In this code, adding each new code character increases the minimum code distance of the code by one. Therefore, the noise immunity of the Reed-Solomon code is determined only by its redundancy, and the use of a shortened code does not affect its ability to correct and detect errors, provided that the shortened code has the same redundancy as the full code.

As a result of encoding information, the Reed-Solomon code word (n, k) is obtained, the information length of which is k, and the block length is n characters.

Further, the information is encoded with a binary code, for example, the Bose-Chowdhury-Hockingham binary code (BCH codes). The BCH code is an internal code or a second-stage code of a noise-free cascading code. The BCH code has the following parameters: n _b is the block length of the code, k _b is the information length of the code.

The initial information for each word of the BCH code is the symbols of the shortened Reed-Solomon code, considered as a sequence of binary characters. As a result of encoding with the BCH code, n binary words of the BCH code (n _b , k _b ) or a binary sequence with ₁ are obtained. This sequence is a shortened noise-resistant cascade code.

Further, the symbols of the shortened cascade code, converted into a signal, enter the communication channel. The communication channel may distort the transmitted signal. This can lead to the fact that the shortened cascading code will be received with errors.

On the receiving side, a shortened cascade code is first received. Next, decoding of the cascade code is performed. The cascade code received at the input of the receiver contains n words of the internal code of the cascade code. The decoding of the cascade code begins with the decoding of the words of the internal code of the cascade code with the detection and correction of errors. The internal code of the shortened cascade code is guaranteed to correct t and less errors in the codeword. If the number of errors in the internal code is greater than t, in the case of using the incomplete decoding algorithm of the internal code, there will be erasure and transformation of the code words.

As a result of decoding the words of the internal code of the cascade code, characters of the external code of the cascade code are obtained. If the number of received symbols of the cascade code external code is sufficient to decode the external code, then the cascade code external code is decoded.

A refusal to decode a shortened cascade code is possible if the number of erased s and transformed r words of the internal code of the cascade code exceeds the correcting ability of the external code of the cascade code

where d _min is the minimum code distance of the external code of the shortened cascading code. Otherwise, the external cascading code will be decoded correctly. Note that for the external Reed-Solomon code, the equation

In case of refusal to decode the shortened cascade code, the number of unaccepted (erased) words of the internal code s is determined from the results of decoding the words of the internal code of the shortened cascade code.

Next, determine the number of transformed words of the internal code. The number of transformed words of the internal code of the cascade code r can be approximately estimated as follows.

The ratio of the number r of transformed codewords to the number of erased s code words of the inner code is approximately estimated by the transformation coefficient β by the "volume of spheres", based on the following considerations.

When correcting exactly i errors in the codeword, the number of binary combinations that can lead to transformation will be equal to

The total number of binary combinations that can lead to erasure of the accepted words will be equal

from here we get

Hence, the number of transformations will be approximately equal

After obtaining an estimate of the number r of transformed words, it is easy to determine the number w of additional words of the internal code of the shortened cascade code necessary for the correct decoding of the cascade code

Through the feedback channel, information on the number of additional words of the cascading code is transmitted to the transmitting side. On the transmitting side, upon this request, the required number of words of the internal code is transmitted to the receiving side, and cascading code is re-decoded taking into account the newly received words of the internal code.

At the same time, the numbers of the erased code words of the internal code can be transmitted to the transmitting side via the feedback channel, and when retransmitted, the erased words or part of them are repeated. In the event that the repetition of previously deleted words of the internal code is not sufficient to compensate for the transformed words of the internal code, the numbers of which are unknown, the words of the internal code that were not previously transmitted are additionally transmitted. This is possible due to the fact that the shortened cascading code was originally transmitted and a certain number of words of the cascading code remained in reserve. Moreover, the number of additional code words to compensate for the transformed words is equal to twice the number of transformed words of the internal code.

We also note that when retransmitting the words of the internal code in these words, errors are also possible. With this in mind, the number of retransmitted words of the internal code should be increased, and the increase should be approximately proportional to the fraction of the number of erased and transformed words of the internal code of the cascading code.

Example. Messages are transmitted on the communication channel by a shortened noise-tolerant cascade code, the internal code of which is the binary BCH code (31, 16) with triple error correction, and the external code is the Reed-Solomon code (32, 16), whose symbols are Galois field elements GF (2 ⁸ ) The decoding of the Reed-Solomon code is carried out with the correction of errors and erasures. For sending messages, only 32 characters of the Reed-Solomon code are used out of 255 possible for the full code.

When transmitting a message, 17 words of the internal code were accepted, and the remaining 15 were deleted. When decoding the Reed-Solomon code, decoding was rejected due to the detection of an uncorrectable combination of errors (the first 16 characters of the external code do not correspond to 17 characters). The transformation coefficient of the internal BCH code calculated by formula (3) is 0.18. Hence, the number of transformed words can be estimated from above taking into account rounding with the value r = 15 · 0.18≈3. The number of additional words of the internal code necessary for the correct decoding will be equal to (5) according to the formula

w = 15 + 2 · 3-17 + 7 = 5

Considering that about half of the words of the internal code are not accepted during transmission, the total number of words that should be transmitted additionally will be approximately 8. Therefore, when generating a request for the repeated transmission of words of the internal code, it is sufficient to indicate the numbers of eight erased words during the first transmission of words.

In the proposed method, the quality of the communication channel is evaluated by the reception results (reception statistics) of the words of the internal code of the cascading code. In this case, unlike the known method, it is easy to estimate the number of erased and transformed words of the cascade code internal code and, when repeating the symbols of the error-correcting code, transmit only the necessary number of words of the cascade code internal code. In the event that the number of errors in the communication channel significantly exceeds the corrective ability of the code, it is possible to compensate for these errors due to additional words of the internal code of the shortened cascade code that were not transmitted before.

The proposed method allows to provide a higher speed of information transmission in the communication channel due to the fact that the decoding of the shortened cascade code estimates the number of unaccepted code symbols and, upon retransmission, only additional symbols of the error-correcting code are necessary for correct decoding. In addition, the proposed method reduces the number of retries of decoding, and therefore reduces its complexity.

Achievable technical result of the proposed method for transmitting messages in a feedback system is to increase the speed of information transfer in the communication channel and reduce the complexity of the method.

Sources of information

1. Elements of the theory of information transfer. Ed. L.P. Purtova. M.: Communication, 1972, p. 39.

2. Sovetov B.Ya., Stakh V.M. Building adaptive information transfer systems for automated control. L .: Energoizdat, 1982, p. 16.

Claims (1)

A method for transmitting messages in a feedback system, which consists in the fact that on the transmitting side of the communication system, the input information array is divided into blocks of a certain length, which are encoded by an error-correcting code and then transmitted to the communication channel, and on the receiving side of the communication system, an error-correcting code is decoded with detection and error correction, if errors are detected in the error-correcting code, the multiplicity of which lies outside the correcting ability of the error-correcting code, form a request for retransmission of the interference stable code, this request is transmitted via the feedback channel to the transmitting side and, upon request, additional symbols of the error-correcting code are transmitted, then, when additional symbols of the error-correcting code are received, this code is re-decoded, characterized in that a shortened noise-resistant cascade code is transmitted to the communication channel, the receiving side of the communication system according to the results of decoding the internal code of the shortened error-correcting cascade code, first determine the number of erased inner code words further estimate the number of transformed inner code words, and then determining the number of additional words of error-correcting inner code concatenated code needed for correct decoding of error-correcting outer code concatenated code and generating a request to transfer these additional error-correcting inner code words concatenated code.