RU143804U1 - DATA TRANSMISSION DEVICE WITH ADAPTIVE ADJUSTMENT OF THE CORRECTIVE FILTER ON THE RESULTS OF THE SYNDROME DECODING OF INFORMATION CODE BLOCKS - Google Patents

Abstract

A data transmission device with adaptive adjustment of the correction filter according to the results of syndromic decoding of information code blocks containing a message source, a first encoder whose output is connected to the input of the first modulator, and the output of the first modulator is connected to the input of the communication channel, the first correction filter, the output of which is connected to the input of the first a demodulator, the output of which is connected to the input of the first decoder, a message receiver, a second encoder, the output of which is connected to the input of the second modulator, the output of the cat It is connected to the first input of the segment search unit, and the output of the segment search unit is connected to the first input of the impulse response calculation block of the correction filter, the output of which is connected to the first input of the second correction filter, the output of the second correction filter is connected to the input of the second demodulator, the output of which is connected to the input the second decoder, a decision block, characterized in that the first register of the syndrome is introduced, which is a block that determines the number of errors detected by the code by a the analysis of the incoming code syndrome, the input of which is connected to the output of the first decoder, the first output of the first syndrome register, through which the decoded information block is transmitted, is connected to the input of the message recipient, the second output of the first syndrome register, through which the decoded information block is transmitted, is connected to the input of the second encoder , and the third output of the first register of the syndrome, through which a signal is transmitted about the presence of an “unreliable" code block, with the first input of the decision block in which a decision is made about

Description

The utility model relates to the field of electro-radio engineering, namely to radio communication technology, and can be used in single-frequency data transmission systems with adaptive correction of signals at the receiving side using phase-shifted signals.

The essence of adaptive correction is to build a filter that compensates for signal distortions resulting from fading and multipath propagation in a communication channel, in particular in a short-wavelength communication channel.

Closest to the claimed technical solution is a method of transmitting data via a multipath communication channel with adaptive adjustment of the correction filter for information signals (application for invention No. 2012118425 of 11/10/2013), adopted as a prototype. The method contains a message source, the first encoder whose output is connected to the input of the first modulator, and the output of the first modulator is connected to the input of the communication channel, the first correction filter, the output of which is connected to the input of the first demodulator, the output of which is connected to the input of the first a decoder, a message receiver, a second encoder, the output of which is connected to the input of the second modulator, the output of which is connected to the first input of the segment search unit, and the output of the segment search unit, is connected to the first input of the impulse response calculation block of the correction filter, the output of which is connected to the first input of the second correction filter, the output of the second correction filter is connected to the input of the second demodulator, the output of which is connected to the input of the second decoder, the decision block. The method of transmitting data via a multipath communication channel with adaptive adjustment of the correction filter for information signals is that on the transmitting side, the useful information is converted by the modulator into an M-position phase-manipulated signal entering the communication channel, where M is the number of phase positions, and at the receiving the side is looking for the impulse response of the channel and the parameters of the correction filter, from the output of which the signal goes to the demodulator, the output of which receives useful transmitted information, and on The transmitting side receives fixed-length information blocks from the message source, for each of which a cyclic checksum (CRC) is added at the end of the block, after which the data block with CRC is encoded with a noise-resistant code, then the encoded data packet is sent to a modulator that generates an analog signal , which is transmitted via the communication channel to the receiving side, while the transmitted signal does not have a probing (test) signal, on the receiving side the signal is sent to the corrective filter, and then to the demodulator and decoder, after which the decoded data is checked by CRC, and if the checksum matches, the information sequence is transmitted to the message recipient, and in the current code block, after recovering the distorted bits, a segment is searched that matches the spectral properties as a test for calculating the impulse characteristics of the channel and the parameters of the correction filter.

The disadvantages of the prototype include the fact that the method assumes the use of CRC as part of code structures to control correctly decoded code words (or code blocks), which reduces the information transfer rate.

The purpose of the utility model is to provide reliable high-speed data transmission with adaptive correction of signals at the receiving side by information signals, without interrupting the transmission of useful information.

This goal is achieved by the fact that in the data transmission device with adaptive adjustment of the correction filter according to the results of syndrome decoding of information code blocks containing a message source, a first encoder, the output of which is connected to the input of the first modulator, and the output of the first modulator is connected to the input of the communication channel, the first correction filter the output of which is connected to the input of the first demodulator, the output of which is connected to the input of the first decoder, a message receiver, the second encoder, the output of which is connected is connected to the input of the second modulator, the output of which is connected to the first input of the segment search unit, and the output of the segment search unit, is connected to the first input of the impulse response calculation block of the correction filter, the output of which is connected to the first input of the second correction filter, the output of the second correction filter is connected to the input the second demodulator, the output of which is connected to the input of the second decoder, the decision block, the first register of the syndrome, which is a block that determines the number of detected an error code by analyzing the incoming syndrome of the code, the input of which is connected to the output of the first decoder, the first output of the first register of the syndrome, through which the decoded information block is transmitted, is connected to the input of the message recipient, the second output of the first register of the syndrome, through which the decoded information block is transmitted, is connected to the input of the second encoder, and the third output of the first register of the syndrome, through which a signal is transmitted about the presence of an “unreliable" code block, with the first input of the decision block, in which they decide that they do not calculate the new impulse response of the correction filter, the second register of the syndrome, the input of which is connected to the output of the second decoder, and the output through which the code syndrome is transmitted, with the second input of the decision block, where they decide that a new impulse response of the correction filter is found if the number of errors has not increased, or not found if the number of errors has increased, while the output of the message source is connected to the input of the first encoder, the first output q the communication channel is connected to the first input of the first correction filter, the second output with the second input of the impulse response calculation block of the correction filter, and the third output with the second input of the second correction filter, the first output of the decision block, which sends a command to search for a new segment, if accepted the decision that a new impulse response of the correction filter was not found is connected to the second input of the segment search unit, and the second output, through which the new impulse response is transmitted If the decision is made that a new impulse response of the correction filter is found, it is connected to the second input of the first correction filter.

The block diagram of the proposed device is shown in FIG. It contains a message source 1, the output of which is connected to the input of the first encoder 2, the output of which is connected to the input of the first modulator 3, the output of which is connected to the input of the communication channel 4. The first output of the communication channel 4 is connected to the first input of the first correction filter 5, the second output to the second input of the impulse response calculation unit 13, the third output to the second input of the second correction filter 14. The first correction filter 5, the output of which is connected to the input of the first demodulator 6, the output of which is connected to the input of the first encoder 7. The output of the first decoder 7 is connected to the input of the first register of syndrome 8, the first output of which is connected to the input of the message recipient 9, the second output with the input of the second encoder 10, the third output with the first input of the decision block 18. The output of the second decoder 10 is connected to the input the second modulator 11, the output of which is connected to the first input of the search unit for segment 12. The output of the search unit for segment 12 is connected to the first input of the block calculating the impulse response 13, the output of which is connected to the first input of the second correction filter 14. the output of the second correction filter 14 is connected to the input of the second demodulator 15, the output of which is connected to the input of the second decoder 16, the output of which is connected to the input of the second register of the syndrome 17. The output of the second register of the syndrome 17 is connected to the second input of the decision block 18, the first output of which is connected to the second input of the search unit segment 12, and the second output to the second input of the first correction filter 5.

The operation of the device is as follows.

On the transmitting side from message source 1, information blocks of a fixed length of K bits are fed to the input of the first encoder 2 with parameters (N, K), where K is the number of information bits received at the input of the encoder, N is the number of bits in the code block received at the output of the encoder . As a result, code blocks of length N bits are fed to the input of the first modulator 3, from the output of which an information signal is fed to the input of communication channel 4. Communication channel 4 is the medium through which the signal is transmitted, in particular, it can be a radio channel, and the signal undergoes distortion. From each of the three outputs of the communication channel 4 receive the same distorted information signal.

On the receiving side from the first output of the communication channel 4, the signal is supplied to the first input of the first correction filter 5. The impulse response of the first correction filter 5 was initially calculated in the process of establishing a communication session, then in the process of operation of the device. The corrected signal from the output of the first correction filter 5 is fed to the input of the first demodulator 6, the output of which receives a sequence of bits (code block) of length N, which is transmitted to the input of the first decoder 7. At the output of the first decoder 7, a decoded information block of length K bits and syndrome the code that is transmitted to the input of the first register of syndrome 8. The first register of syndrome 8 is a block that determines the number of errors detected by the code by analyzing the incoming code syndrome. From the first output of the first register of the syndrome, the decoded information block is given to the message recipient 9. In addition, based on the received syndrome, it is determined whether the number of errors of the specified threshold value is exceeded, thereby determining “reliable” or “unreliable” code blocks. If the code block is “unreliable”, then from the third output of the first syndrome 8 register, the signal about the presence of an “unreliable” code block is transmitted to the first input of the decision block 18, where they decide that the new impulse response of the correction filter is not calculated and from the second output of the decision block 17 to the second input of the first correction filter 5, a command is transmitted about using the impulse response of the correction filter received earlier. If the received code block is “reliable”, then from the second output of the first register of syndrome 8, the decoded information block is transmitted to the input of the second encoder 10, from the output of which a new code block is transmitted to the input of the second modulator 11. The signal at the output of the second modulator 11 is transmitted to the first input block search segment 12.

In the search unit of segment 12, a search is made for such a segment of the signal, which in its spectral characteristics is suitable as a test one, in particular, one of the main requirements is the absence of zeros in the spectrum.

The found signal segment from the output of the search unit for segment 12 is fed to the first input of the block for calculating the impulse response of the correction filter 13, and is considered a test signal, that is, a signal without distortion. The signal from the second output of communication channel 4 is transmitted to the second input of the impulse response calculation unit of the correction filter 13, and a segment of this signal corresponding to the segment received as a test signal is highlighted. To calculate the impulse response of the correction filter in the block calculation of the impulse response of the correction filter 13 can be implemented by the method of least squares (LMS algorithm) [Dzhigan V.I. Adaptive signal filtering: theory and algorithms. M .: Technosphere, 2013. - S.135-139.], Or the RLS algorithm [Dzhigan V.I. Adaptive signal filtering: theory and algorithms. M .: Technosphere, 2013. - S.194-196.]. The calculated impulse response of the correction filter is fed to the first input of the second correction filter 14, to the second input of which a signal is transmitted from the third output of the communication channel 4. The newly corrected signal from the output of the second correction filter 14 is fed to the input of the second demodulator 15, from which a bit sequence of length N and pass to the input of the second decoder 16. At the output of the second decoder 16 receive an information block and a second syndrome, which are transmitted to the input of the second register of the syndrome 17. With you Ode to the second register of syndrome 17, the second syndrome is transmitted to the second input of the decision block, where it is determined that the new impulse response of the correction filter does not impair the quality of the correction compared to the impulse response of the correction filter currently used in the first correction filter 5. If the number of errors has increased then from the first output of the decision block to the second input of the segment search block, a command is sent to search for a new segment and the sequence of actions after finding a new segment is repeated. If the number of errors has not increased, decisions are made that a new impulse response of the correction filter is found, and a new impulse response is transmitted from the second output of the decision block to the second input of the first correction filter.

The proposed device can be used for single-frequency data transmission systems with adaptive correction of signals at the receiving side using phase-shifted signals. A distinctive feature of the described device is the ability to configure the correction filter directly by the information signal without introducing special test signals that do not carry information, as well as without introducing CRC into the transmitted code structures. Thus, the presence of such a device allows you to abandon the introduction of additional redundancy to calculate the impulse response of the correction filter.

The proposed device provides:

- correction of received signals, which improves noise immunity;

- calculation of the impulse response of the correction filter without introducing additional redundancy in the form of transmission of test signals, which increases the information transfer rate, while there is no need to add CRC to each code block, which also increases the information transfer rate.

Claims (1)

A data transmission device with adaptive adjustment of the correction filter according to the results of syndromic decoding of information code blocks containing a message source, a first encoder whose output is connected to the input of the first modulator, and the output of the first modulator is connected to the input of the communication channel, the first correction filter, the output of which is connected to the input of the first a demodulator, the output of which is connected to the input of the first decoder, a message receiver, a second encoder, the output of which is connected to the input of the second modulator, the output of the cat It is connected to the first input of the segment search unit, and the output of the segment search unit is connected to the first input of the impulse response calculation block of the correction filter, the output of which is connected to the first input of the second correction filter, the output of the second correction filter is connected to the input of the second demodulator, the output of which is connected to the input the second decoder, a decision block, characterized in that the first register of the syndrome is introduced, which is a block that determines the number of errors detected by the code by a the analysis of the received syndrome of the code, the input of which is connected to the output of the first decoder, the first output of the first register of the syndrome, through which the decoded information block is transmitted, is connected to the input of the message recipient, the second output of the first register of the syndrome, through which the decoded information block is transmitted, is connected to the input of the second encoder , and the third output of the first register of the syndrome, through which a signal is transmitted about the presence of an “unreliable" code block, with the first input of the decision block in which a decision is made about ohm, that the calculation of the new impulse response of the correction filter is not carried out, the second register of the syndrome, the input of which is connected to the output of the second decoder, and the output through which the syndrome of the code is transmitted, with the second input of the decision block, where it is decided that the new impulse response a correction filter is found if the number of errors has not increased, or not found if the number of errors has increased, while the output of the message source is connected to the input of the first encoder, the first output of the communication channel is connected it is connected with the first input of the first correction filter, the second output with the second input of the block for calculating the impulse response of the correction filter, and the third output with the second input of the second correction filter, the first output of the decision block, which sends a command to search for a new segment, if a decision is made that a new impulse response of the correction filter is not found, is connected to the second input of the segment search block, and the second output, through which the new impulse response is transmitted, if Nima solutions that a new impulse response correction filter is found, connected to the second input of the first correction filter.