RU2304841C2 - Decoding device for noise-immune variable-length concatenated code - Google Patents

Abstract

FIELD: electrical communications; digital data transfer systems for decoding noise-immune variable-length concatenated code.

SUBSTANCE: proposed decoding device for noise-immune variable-length concatenated code has buffer memory and frame synchronization unit; their inputs are integrated to function as information input of device; outputs of buffer memory and frame synchronization unit are connected to internal-code decoder whose output is connected to external-code decoder; output of the latter functions as information output of device; newly introduced in device are time interval shaper, code word counter, and analysis unit; synchronization input of device is connected to input of time interval shaper whose control input is connected to output of frame synchronization unit; output of time interval shaper is coupled with inputs of code word counter and analysis unit whose other input is connected to output of code word counter whose synchronization input is coupled with internal-code decoder; output of analysis unit is connected to external-code decoder.

EFFECT: enhanced noise immunity of decoding device.

1 cl, 1 dwg

Description

The invention relates to the field of telecommunications and can be used in discrete information transmission systems for decoding a noise-resistant cascading variable-length code.

The device described in this application is used to decode a cascade code, the block length of which is not known in advance at the receiving side. In particular, the device can be used to decode cascading codes in adaptive information transmission systems. In such systems, to improve the accuracy of reception when changing the interference environment in the communication channel, a noise-tolerant cascade code having a different block length is transmitted. A short cascade code with a small redundancy is transmitted in a high-quality communication channel, and a long cascade code with a large redundancy in a low-quality channel. The proposed device provides a determination of the block length of the cascade code and its decoding.

A decoding device for a variable-length error-correcting cascade code is known, comprising a buffer memory and a cyclic synchronization device, the inputs of which are combined and are the information input of a variable-length error-correcting cascade code decoding device, the outputs of the buffer memory and a cyclic synchronization device are connected to a short cascading code decoding device and to decoding device of a long cascade code, the outputs of which are connected to the input mi OR circuit, the output of which is the information output of a decoding device of a noise-resistant cascading code of variable length [Shabanov V.K. To the question of decoding cascading codes of variable length. Communication technology, ser. TPN, 1988, issue 4].

However, this device has high complexity because it contains two decoding devices: a short cascade code decoding device and a long cascading code decoding device.

Closest to the proposed device is a decoding device of an error-correcting cascading variable-length code (prototype), comprising a buffer memory and a cyclic synchronization device, the inputs of which are combined and are the information input of a decoding device of an error-correcting cascading variable-length code, the outputs of the buffer memory and cyclic synchronization devices are connected to the decoding device of the internal code, the output of which is connected to the decoding device troystvom outer code, the output of which is the data output of error-correcting decoder concatenated variable length code [Kvashennikov VV Slepuhin FV Information transmission system with error-correcting code with variable parameters. Communication systems, television and radio broadcasting, No. 1-2, 2003, p. 54].

The disadvantage of this device is the lack of functional units for determining short or long noise-tolerant cascade code, which leads to low noise immunity code decoding. Depending on the quality of the communication channel, either a long or short cascade code is transmitted, however, the decoding device does not detect a long or short cascade code. In this case, various options are possible. If the device decodes a long cascade code when transmitting a short cascade code, then words of the internal cascade code code that were not transmitted for the short cascade code are decoded into erasures and transformations, which reduces the noise immunity of decoding the code. If, when transmitting a long cascade code, the device decodes the short cascade code, then the noise immunity of the device is reduced due to the small redundancy of the short cascade code.

The purpose of the invention is to increase the noise immunity of decoding a cascade code of variable length due to the fact that functional units are introduced into the device that determine the presence of a short or long cascade code at the input of the device.

To achieve the goal, it is proposed a device containing a buffer memory and a cyclic synchronization device, the inputs of which are combined and are the information input of the device, the outputs of the buffer memory and a cyclic synchronization device are connected to a decoding device of an internal code, the output of which is connected to a decoding device of an external code, the output of which is the information output of the device. What's new is that a time slot generator, a code word counter and an analysis unit are introduced into the device, while the device synchronization input is connected to the input of the time slot generator, the other input of which is connected to the output of the cyclic synchronization device, the output of the time slot generator is connected to the inputs of the code counter words and analysis unit, the other input of which is connected to the output of the codeword counter, the input of which is connected to the output of the decoding device of the internal code and the output of the analysis unit It is connected to an outer code decoder.

The drawing shows a structural diagram of the proposed device.

The decoding device of the error-correcting cascading variable-length code contains a buffer memory 1, a cyclic synchronization device 2, an internal code 3 decoding device, a time interval generator 4, a code word counter 5, an analysis unit 6, an external code decoding device 7.

The proposed device operates as follows.

Either a short cascade code with a block length equal to n ₂ or a long cascade code with a block length n ₁ (n ₁ > n ₂ ) is generated on the transmitting side of the noise-immune communication system. 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.

As a result of encoding information, the code word of the Reed-Solomon code (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 source information for each word of the BCH code is the Reed-Solomon code characters, considered as a sequence of binary characters. As a result of encoding the BCH code for all the characters of the Reed - Solomon code, n binary words of the BCH code (n _b , k _b ) or a binary sequence with ₁ are obtained. This binary sequence is a noiseless cascading code.

Next, the symbols of the cascade code, converted into signals, enter the communication channel. In the communication channel, distortion of the transmitted signals is possible and this leads to the fact that the symbols of the cascade code are received with errors.

The cascade code, whose symbols are input to the receiver, can have a block length equal to either n ₁ or n ₂ (n ₁ > n ₂ ). The decoding device of the cascading code is not known in advance the block length of the cascading code. First, the symbols of the cascade code are input to the buffer memory 1 and the cyclic synchronization device 2. The cyclic synchronization device 2 determines the end of the cascade code. This device can be performed, for example, as described in the source "RF Patent No. 2197788 IPC 7 H04L 7/04, Kvashennikov V.V., Slepukhin F.V., Trushin S.A. Code cyclic synchronization device. Prior. 05.03. 2001, publ. 2003. "

The volume of the buffer memory 1 is designed to record all the characters of a long cascade code, that is, it is designed to record n ₁ × n _b characters. The buffer storage device can be implemented, for example, in the form of a shift register, to which a working clock frequency equal to the rate of arrival of symbols from a communication channel is constantly applied.

The signal from the cyclic synchronization device 2, corresponding to the end of the cascade code, is supplied to the decoding device of the internal code 3. By this signal, the symbols from the output of the buffer device 1 are copied to the decoding device of the internal code 3. At the same time, the signal from the cyclic synchronization device 2 is sent to the time slot generator 4 , at the synchronization input of which the operating clock frequency is supplied. Shaper time intervals 4 sets the time intervals equal to the decoding time t ₂ and t ₁ words of the internal codes of the short and long cascading code, respectively.

The decoding device of the inner code 3 performs decoding of the words of the inner code of the cascading code. This device can be performed as described in the source "Patent of the Russian Federation for utility model No. 42143, IPC 7 Н03М 13/05. VV Kvashennikov. Decoding device of noise-resistant code. Prior. 07.05.2004, publ. 20.11.2004". The decoding device of the internal code 3 decodes the words of the internal code of the long cascade code copied from the buffer memory 1. When transmitting the long cascade code, n ₁ words of the internal code are decoded, and when transmitting the short cascade code, n ₂ words of the internal code and n ₁ -n are decoded ₂ words consisting of characters received from the communication channel at times when code symbols are not transmitted for the short code, that is, consisting of channel noise characters. At the output of the decoding device of the internal code 3, upon successful decoding of the code, symbols of the external code of the cascading code are obtained. These symbols are supplied to the decoding device of the external code 7. The symbols of the external code of the cascade code corresponding to the words of the internal code of the cascade code, errors in which are detected but cannot be corrected, are deleted. The signals of successful decoding of the words of the inner code (unwritten words) from the decoding device of the inner code 3 are supplied to the counter of code words 5. At the same time, from the time slot generator 4 to the code word counter 5, a resolving signal is supplied during the decoding time interval of the short cascade code t ₂ , and the counter codewords 5 counts the number s of words of the inner code that were taken in place of the words of the inner code of the cascade code, which transmit for a long cascade code and do not transmit in the case short cascading code. At the end of the time interval t _{2, the} signal from the output of the time interval generator 4 is fed to the codeword counter 5 and analysis unit 6. According to this signal, the binary combination corresponding to the number s of codewords of the internal code is copied from the output of the codeword counter 5 to the analysis unit 6 and 5 codeword counter is reset to zero. After that, the counter of code words 5 for a time interval equal to t ₁ -t ₂ counts the number s _{2 of} words of the internal code, taken in place of the words of the internal code of the cascade code, which are transmitted for both the long cascade code and the short cascade code. When transmitting a long cascade code, the number s can vary in the range from 0 to n ₁ -n ₂ depending on the quality of the communication channel. At the end of the time interval t ₁ -t _2, according to the signal from the time interval shaper 4, the codeword counter reading 5, that is, the binary combination expressing the number s _{2 of} words of the internal code, is rewritten into analysis block 6. Analysis block 6 according to two codeword counter readings 5, equal to the number s and s _{2 of the} received words of the internal code, determines the presence of a long or short cascading code. The number s of received codewords from the number of transmitted n ₁ -n ₂ code words for a long cascade code is expressed by the equation

where γ is the probability of receiving words of the internal code of the cascade code.

The probability of receiving words of the internal code of the cascade code γ characterizes the quality of the communication channel, since when the quality of the channel changes, the number of received code words of the internal code of the cascade code changes. The probability of receiving words of the internal code of the cascade code γ will be estimated by the frequency of receiving words of the internal code according to the formula

When receiving a short cascade code, the number s is determined by the number of transformed words of the internal code dialed from the communication channel at times when the code symbols are not transmitted for the short code, i.e., consisting of noise symbols

where β is the probability of an undetected error in the words of the internal code of the cascade code, consisting of noise symbols.

The probability β of an undetected error is estimated by the expression [Elements of the theory of information transfer. Under. ed. L.P. Purtova, M., Communication, 1972, p. 127].

As a rule, n _b -k _b ≫1 and the inequality γ> β holds.

The criterion by which the presence of a short or long cascade code in a communication channel is determined is the value of the number s of code words. Difference

ε = s _dl -s _core = γ (n ₁ -n ₂ ) -β (n ₁ -n ₂ ) = (γ-β) (n ₁ -n ₂ )> 0,

because γ-β> 0 and n ₁ -n ₂ > 0.

Therefore, there is some threshold value

when exceeded, a long cascade code in the communication channel is determined, i.e., logical expressions are true

Next, respectively, decode the long or short external code of the cascading code.

The choice of the optimal threshold value s _{1 is of} no small importance in the implementation of the proposed device. In a non-stationary communication channel with variable parameters, the estimate of the threshold value s ₁ should change depending on the quality of the communication channel at the current time.

Substituting in the formula (5) the values of the variables from equations (1) - (3) we obtain the following estimate of the threshold value s ₁

In the proposed device, the assessment of the threshold value s _{1 is} carried out according to the formula (7). This estimate is computed in each cascade code reception session after determining the number s ₂ of internal words taken in place of the words of the internal cascade code, which are transmitted for both the long cascade code and the short cascade code and the quality of the communication channel s ₂ / n ₂ (estimates of the average probability of receiving words of the cascading code internal code).

First, in the analysis unit 6, based on the number of codewords s ₂ obtained from the output of the codeword counter 5, an estimate of the threshold value s _{1 is} calculated by formula (7). Then, in the analysis unit 6, based on the number s of codewords counted by the codeword counter 5, using a logical expression (6), a long or short cascading code is determined. To perform these calculations, the analysis unit 6 can be implemented, for example, on a microcontroller. In this case, the counter of received codewords is connected to the input port of the microcontroller. The signal from the output of the time interval shaper 4 is used as an interrupt signal of the microcontroller, according to which data from the input port is read into the internal memory of the microcontroller and the calculation process is initialized by formula (7) and logical expression (6). Then the signal of the long or short cascade code through the output ports of the analysis unit 6 is supplied to the decoding device of the external code 7.

The decoding device of the external code 7 decodes a short or long external code in accordance with the incoming signal, and transmits the decoded information to the output of the decoding device of the error-correcting cascading variable-length code.

The proposed device provides the definition of a short or long cascade code, which increases the noise immunity of decoding a cascade code with variable parameters. The claimed technical solution expands the arsenal of tools for this purpose, allows you to use the decoding device in the communication channels of low quality.

Achievable technical result of the proposed decoding device intermittent cascading variable-length code is to increase the noise immunity of the decoding code.

Claims (1)

A decoding device for a variable-length error-correcting cascading code, comprising a buffer memory and a cyclic synchronization device, the inputs of which are combined and are an information input of the device, the outputs of the buffer memory and a cyclic synchronization device are connected to an internal code decoding device, the output of which is connected to an external code decoding device, the output of which is the information output of the device, characterized in that for a time slot generator, a code word counter and an analysis unit, wherein the device synchronization input is connected to an input of a time slot generator, another input of which is connected to an output of a cyclic synchronization device, the output of a time slot driver is connected to inputs of a code word counter and an analysis unit, another input of which connected to the output of the codeword counter, the input of which is connected to the output of the decoding device of the internal code and the output of the analysis unit is connected to the decoding device of the external code.