RU2360361C2 - Method of interference-immune reception and transmission of information on communication channel with noise and deep fading and radio station - Google Patents

Abstract

FIELD: information technology; railway transport.

SUBSTANCE: present invention relates to information transmission systems, used in railway transport. In the method information to be transmitted is broken down into packets, each of which is broken into L characters of m bits each. The characters are explicitly replaced with corresponding standard sequences (SS), which possess inter-correlation properties. The encoded packet is alternated and transmitted in a radio channel. At the receiving side there is reception of elementary signals (ES) corresponding to bits of the transmitted encoded packet. The encoded packet is de-alternated, the attachment of each elementary signal to the number of the transmitted character and the bit number inside the replacing standard sequence are determined. The result of analogue-to-digital conversion of the elementary signal is successively multiplied by the corresponding bit number 2^m of the standard sequence. The products are accumulated in adders, corresponding to the number of standard sequences. From the maximum value of accumulated sums, each of the L received standard sequences is reconstructed. The information series of characters is reconstructed from the chosen conformity of the standard sequence and initial bits of the packet. The radio station contains a transceiver (1), codec (2), and an adjustment unit (3). The codec contains a unit for generating characters (7), display unit (8), alternation unit (9), unit for adding synchro-sequence (10), reference signal unit (11), analogue-to-digital converter (12), correlation adder unit (13), reconstruction unit (14), synchroniser unit (15) and a control unit (16).

EFFECT: higher probability of correct reception of information while retaining sufficient transmission speed.

2 cl, 3 dwg

Description

The method of noise-immune reception and transmission of information over a communication channel with interference and deep fading and a radio station with noise-resistant coding are designed to operate in the selected frequency range and can be used to receive / transmit information between remote objects. In particular, on the railways, when braking processes are controlled to transmit commands and test information from a locomotive to a tail carriage and vice versa in the frequency range allocated for the needs of the Ministry of Railways of the Russian Federation. Especially effective is the use of the proposed method and radio station for the safe braking of heavy trains and providing the driver with information about the pressure in the brake line.

A known method of noise-tolerant reception and transmission of information on a channel with interference and fading according to Prokis J. Digital communication. Moscow, Radio and Communications, 2000. The method is that on the transmitting side, the data arriving for transmission are encoded with reference sequences, interleaved, supplemented with a synchronizing sequence, modulate the carrier frequency signal with the received sequence and transmitted to the radio channel, and on the receiving side, the incoming signal is demodulated, convert to binary, deinterleave, decode, restore information data. In this case, linear block codes are used for coding. On the receiving side, information recognition is carried out after binary conversion (to "0" and "1") of demodulated elementary signals, in which the accuracy of the received information is significantly reduced.

The disadvantage of this method is:

- the final gain in the signal-to-noise ratio (of the order of 3-7 dB);

- the complexity of the calculations, and the calculations in this case have to be done only after the reception of the entire block of information is completed, and the implementation of soft correlation accumulation for linear block codes is not optimal;

- loss of information on reception with bit-wise sampling of the received digitized signal,

A known radio station according to RU 2158446 C2, H04B 1/38, 10.27.2000, containing a transceiver with an antenna, a codec and a control unit. The codec on the transmitting side contains sequentially connected devices for encoding, interleaving and packet formation. The codec on the receiving side contains a series-connected analog-to-digital converter, demodulator, deinterleaver, decoder. The radio station is controlled by a control unit that generates control and synchronization signals for all units. The disadvantage of the radio station is the bit detection at the reception of the transmitted linear block code before decoding, which leads to the above disadvantages.

The aim of the invention is to provide a method for noise-immune reception and transmission of information for a limited time through the communication channel with the presence of powerful pulsed interference and deep fading and radio stations, allowing to obtain a high probability of the correct reception of information while maintaining a sufficient transmission speed.

The goal is achieved thanks to the present invention, which provides a method of noise-tolerant reception and transmission of information over a communication channel with interference and deep fading, which is as follows. The information arriving at certain predetermined time intervals is divided into data packets representing binary information sequences of length N bits. Each information packet is encoded as follows. Break the packet (N bits) into L characters of m bits (L = N / m if N = m * L; L = the integer part (N / m) +1 if N = m * L + k, where k is remainder of integer division N / m), receiving an informational series of characters. Each symbol of m bits is replaced by one of 2 ^m pseudo-random binary sequences (PSPs) of length (2 ^m-1 -1) bits according to the chosen unique correspondence, and all PSPs have the property of minimal cross-correlation. All 2 ^m SRPs form a plurality of reference SRPs.

Thus, an information series is obtained from L SRPs corresponding to L source symbols of length m bits. The resulting information series is transformed with a length of (2 ^m-1 -1) * L bits into a new series of the same length, using the alternation of its constituent sequences, the form of which is chosen for a given communication channel. For example, it is possible to use uniform interleaving through (2 ^m -1 -1) bits from (2 ^m -1 -1) cycles. The result is a new series of length (2 ^m -1) * L bits, in which the first L bits correspond to the first bits of the SRP sequences for each of L symbols, the next L bits are the second bits of the SRP sequences, etc. (that is, the symbols are the bits of the series of memory cards located in ascending order of numbers). The encoding method by replacing the transmitted characters with the SRP sequence followed by their interleaving (to obtain an information sequence) makes it possible to process data packets of any length with the formation of an encoded packet of information that is resistant to transmission at a high level of interference, as well as the possible loss of signal during transmission. The transmission of each encoded packet of information is preceded by the transmission of a special, given, fixed synchronizing sequence (sync sequence) with a length of p bits. Next, the carrier frequency signal is modulated by the resulting total binary information (total sequence) and transmitted to the radio channel.

On the receiving side of the communication channel, the incoming high-frequency signal is amplified to the required level, demodulated, and the demodulated sequence is analyzed. In the case of receiving a synchronization message at the maximum value of the correlation coefficient between the reference synchronizing sequence and the received signal, a decision is made to start receiving the information packet (frame synchronization), the reading intervals of the elementary signals of the received information (bit synchronization), corresponding to one bit of the transmitted encoded information packet, and accept a set of analog elementary signals in an amount of (2 ^m-1 -1) * L in a known time interval. In accordance with the chosen interleaving, the belonging of the received elementary signal to the number of the transmitted symbol and the bit number inside the PSP sequence is determined (position in the series of transmitted PSP sequences formed by replacing the characters). The result of the analog-to-digital conversion of the elementary signal is sequentially multiplied by the corresponding bits of 2 ^m reference SRP (elements of the reference signals). The results are summarized in the corresponding sequence number 2 ^m correlation adders. Thus, all L * (2 ^m-1 -1) elementary signals are received, each time summing the multiplication results in the corresponding correlation adders. After receiving the packet, 2 ^m * L correlation adders accumulated 2 ^m correlation sums for each of the L received with distortion SRP (the results of the convolution of the received SRP and 2 ^m reference SRP). For each of the L received SRPs, one maximum value is selected from 2 ^m correlation sums calculated for it. By the number (among 2 ^m correlation sums) a decision is made about which of the reference SRP is accepted. In this way, all L transmitted sequences are restored. By unambiguous correspondence, L SRPs are converted into L characters with a length of m bits. Discard (m * LN) the last bits and get the original packet of information.

So, interleaving of elementary constituent sequences with minimal cross-correlation in transmission and recognition of source information by elementary signals using the correlation method in reception (combining the advantages of interleaving for linear block codes and sequence properties with minimal cross-correlation, allowing correlation reception) allows the system to work with fading and interference of a significantly larger length proportional to the period of interleaving, as well as with It stores the ability to recover information using correlation accumulation, and also allows you to shift the probability curve of errors to the region of lower signal-to-noise ratios, while LBK only changes the slope of this curve and is characterized by a final gain of 3-7 dB in the signal-to-noise ratio. In this case, it becomes possible to distribute the calculations over the interval of message reception (i.e., to ensure the operation of the device in real time).

Preferably, in the described process, among the reference sequences, the last 2 ^m-1 additional sequences are inverse to the first 2 ^m-1 reference sequences, and on the receiving side for each of the L received sequences accumulated

2 ^m-1 correlation sums of the products of this sequence for each of

2 ^m-1 reference sequences, and when restoring the information series of the symbols of each of the L received sequences, one of the reference or additional sequences is assigned, which is determined by the sign of the maximum in absolute value from 2 ^m-1 correlation sums.

The same goal is achieved thanks to the present invention, which provides a noise-resistant coding radio station, containing a Transceiver with an antenna for transmitting information and receiving commands over a radio channel, an Error-correcting codec and a Control Unit connected to the radio information port. The output of the Control Unit is connected to one of the inputs of the Transceiver device. For radio devices requiring power, a corresponding fixed voltage is provided.

The radio codec is implemented as follows. The codec on the transmitting side contains a series-connected character generation unit (L characters each m bits), a unit for mapping a plurality of characters to a plurality of sequences with minimal cross-correlation, an interleaving unit, and a sync sequence adding unit. At the same time, the Display Unit and the Add Sync Sequence Unit are connected to the Reference Signals Block. On the receiving side, the codec contains a series-connected analog-to-digital converter (hereinafter ADC), a block of correlation adders. The recovery unit and the matching unit with the user interface, while the input of the control unit is connected to the ADC output through the sync sequence allocation unit, the first output of the control unit is connected to the second input of the correlation adders unit, its second output is to the second input of the recovery unit, and the third is to the input The block of reference signals, the output of which is connected to the third input of the block of correlation adders.

The functional scheme of Codec 2 is implemented on a microprocessor and performs its functions through software with a modular (block) structure. Blocks interact with each other, isolating or querying the information they need for processing commands or incoming data from other modules.

The use of such radio stations on spaced objects (in particular, on a locomotive and in the tail of a train or in the head and tail of a convoy) makes it possible, when any conditions change, to quickly transmit the corresponding commands for execution and receive a report on their implementation without loss and distortion. The use of radio stations in systems for braking heavy train simultaneously from the head and tail is especially effective. This eliminates the longitudinal-dynamic reactions that occur when the braking spacing in time, leading to damage to the coupler, squeezing cars out of track and the rolling stock off the rails.

Figure 1 presents the functional diagram of a radio station in which a method for receiving and transmitting information on a communication channel with interference and deep fading is implemented.

Figure 2 is a variant of the unique correspondence of the rows of the PSP matrix m-bit characters.

Figure 3 presents the timing diagrams of the Codec on the receiving side and the transmitting side.

The present invention can be implemented in the noise-tolerance coding radio station shown in FIG. 1. An antenna for receiving / transmitting information on a radio channel in a given frequency range is connected to the Information Port (Inf. Port) of a radio station for receiving / transmitting data from user equipment through series-connected via I / O Ports Transceiver (hereinafter referred to as PPU) 1, Codec 2 error-correcting code and Control unit 3, the output of which is connected to the input of the PPU. The voltage supplied to the input of the radio station through power converters 4, 5, 6 is supplied respectively to the control panel, codec and control unit.

The functional diagram of Codec 2 is implemented on a microprocessor and performs its functions through software with a block structure. The blocks exchange information according to the functional diagram shown in Fig. 1.

In the Codec on the transmitting side, the Symbol Generator 7 is connected in series, the input of which is connected to Port 1 of the Codec, the Display Unit 8, the Interleaver 9 and the Add Sync Sequence 10 block, the output of which is connected to Port 2 of the Codec. At the same time, the Display Unit 8 and the Add Sync Sequence Unit 10 are connected to the input / output (I / O) of the Reference Signal Block 11. Moreover, Port 1 of the Codec is connected to the Control Unit, and Port 2 to the control panel.

On the receiving side of the Codec, an Analog-to-Digital Converter (hereinafter ADC) 12 is connected in series, the input of which is connected to Port 2 of the Codec, the Correlation Adder Block 13, Recovery Block 14 and the Coordination Block 15 with a user interface whose output is connected to Port 1 of the Codec, the input (Vx) of the Control Unit 16 is connected to the output of the ADC through the Synchronization Sequence Block 17, the first output (Out1) of the Control Unit is to the second input (Vx2) of the Correlation Adders Unit, and the second output (Out2) to the second input (Vx2) of the Recovery Unit The second output (Out3) is connected to the input (In) of the Block of reference signals, the output (Out) of which is connected to the third input (In3) of the block of correlation adders.

The implementation of the method of noise-resistant reception and transmission of information over the communication channel with interference and deep fading will be shown on the operation of the radio station with noise-resistant coding.

The radio station operates as follows. The voltage supplied to the input of the radio station is converted in the power converters 4, 5, 6 into the voltage necessary for the operation of the control panel, codec, and control unit (implemented, in particular, on the microprocessor), respectively. Inf. The radio station port is intended for entering commands for the Control Unit and information for broadcasting, as well as for outputting information received by the radio station to those connected to the Inf. Device port (for example, a computer or other devices connected to RS232 port).

When you turn on the radio station (Inf. The port is connected to a device designed to transmit / receive information from the radio station, and power is supplied to its input - U _pit ), all devices included in it are set to the reception mode by default (waiting or receiving a signal). Upon receipt of data by Inf. The port in the control unit produce their analysis. In the case where the data are commands for the radio station, the control unit performs the corresponding radio station settings (for example, switches the radio station to another working channel in a given frequency range, sets a different transmitter power level, etc.). In the case of receipt of information for transmission, the radio station is transferred to the transmission mode as follows: in the control unit, a transmission signal is generated, which is transmitted to the input of the control unit through the output of the control unit, and then it is transferred to the transmission mode, data reception from Port 1 of the Codec is stopped (from the output of the approval unit ), and also begin the transfer of the information coming into the Regulation Unit through Port 1 of the Codec to the input of the Symbol Formation Unit, which puts the Codec into transmission mode. The radio station works in a transfer mode while on Inf. The port of the radio station receives data at certain time intervals necessary for the radio station to transmit encoded information (having a larger volume than the original) to the air. These intervals are set and their size is provided for the correct operation of the radio station. In particular, at a transmission speed of 9600 Baud, no more than 115 ms are required for transmitting 64 bits of source information with the selected transmission / reception method, this time is laid down as requirements for devices connected to Inf. Porto radio station.

On the transmitting side, the radio station sequentially receives data through Inf. Port to the Control Unit, which transmits it through Port 1 to the Codec, where the data is encoded, and transmit it through Port 2 to the control panel and then through the antenna to the air.

The Codec character generation unit receives from Port 1 information packets with a length of N = 64 bits. The encoding of each information packet is as follows. In the Character Generation Block, a packet of 64 bits is divided into 10 characters with a length of 7 bits (the last character is obtained by adding one bit with six bits - for example, “zeros”). In the display unit, each such symbol, out of 2 ⁷ = 128 possible, is replaced by a memory bandwidth of 2 ^7-1 = 63 bits according to the uniquely selected correspondence. A set of all reference sequences can be represented in the form of a PSP matrix, 2 ^m = 128 rows of which are the mentioned PSP, and (2 ^m-1 -1) = 63 columns are bits of these sequences.

An example of such a correspondence is shown in FIG. PSP matrix consists of 128 SRP. Reference SRP: the first line is the M-sequence (Hoffman code), the next 62 lines are obtained by cyclic shift of the first line, the 64th line is 63 units. An additional 64 sequences are formed by inverting the former. The reference PSP is conventionally assigned a plus sign, the rest of the PSP is conventionally assigned a minus sign. These reference SRP have the property of minimal cross-correlation.

The corresponding memory bandwidths are requested from the Block of reference signals, where 128 memory bandwidths and 128 unambiguously corresponding 128 variants of seven-digit symbols are stored or generated according to a given algorithm.

The resulting information series of 10 SRP (630 bits) corresponds to the original information series of 10 characters with a length of 7 bits. It can be represented in the form of a matrix, 10 rows of which are 63 bits long. In the Block of interleaving, the resulting sequence of information is converted into a new one using the selected interleaving. In particular, uniform interleaving: matrix columns are read sequentially. The result is a series of 63 characters with a length of 10 bits, in which the first 10 bits correspond to the first bits of ten SRP sequences, the next 10 bits are the second bits of these SRP sequences, etc. Receive an information sequence. The use of memory bandwidth with minimal cross-correlation with further interleaving makes it possible, when decoding, to recover the information lost or distorted during transmission as accurately as possible (in the event of a signal loss or noise), since the probability of the loss of most of some memory bandwidths is sharply reduced.

The encoded information packet is transmitted to the Synchronization Sequence Addition Block, where a synchronizing start packet is added to its beginning in the form of a special binary SRP of a fixed length (for example, 127 bits), requesting it from the Reference Signal Block. Thus, a total sequence consisting of synchronization and information sequences is supplied to Port 2 of the Codec.

Then, in the Transceiver configured for transmission, the carrier signal is modulated by the incoming binary signals, amplified to a predetermined level, and broadcast. Similarly, all incoming information is transmitted.

At the end of the receipt of data from the Port of the radio station (in particular, when the waiting time exceeds the waiting interval), a reception signal is generated in the Control Unit, which is transmitted to the input of the control unit through the output of the Control Unit, which translates it into a receive mode (waiting for receipt and reception of information), data transfer to Port 1 of the Codec (input of the Symbol Formation Unit), and also start receiving information from Port 1 of the Codec (from the output of the Coordination Unit) to the Radio Station Port. Thus, the radio station is transferred to the reception mode, in which the information is sequentially received, decoded and transmitted through the Control Unit to Inf. The port of the radio station.

On the receiving side, when a signal arrives in the operating frequency band from the antenna to the control panel, the incoming high-frequency signal is amplified to the required level, demodulated and transmitted through the Codec Port 2 to the ADC, where the analog signal is digitized and transmitted to the Sync Sequence Selector and Correlation Adders Block . The sync sequence allocation unit compares the received information with a known starting premise, partially distorted or missing. In the case of receiving a synchronization sequence for the maximum value of the correlation coefficient between the reference synchronizing sequence and the received signal in the Control Unit, a signal for receiving the information packet is generated, which frame and bit synchronize the Correlation Adder Block and the Reference Signal Block. Until the synchronization sequence is selected, synchronization is not carried out. Thus, the random information received by the PPU is cut off and only useful information is received. After the arrival of the signal, the beginning of receiving the information packet in the Block of correlation adders starts receiving a set of elementary signals in the amount of (2 ^7-1 -1) * 10 = 630 (with the number of transmitted symbols known in the time interval - 10). Upon receipt of each elementary signal corresponding to one bit of the transmitted encoded information packet, in its place in accordance with the received interleaving determine the number of the SRP (from the first to the tenth) from which it is received, and the number inside the SRP. From the block of reference signals, bits of 64 reference SRPs corresponding to the number inside the SRP are supplied (sequentially from the 1st to 64th), 64 corresponding products are calculated by multiplying the latter by this digitized elementary signal and summed in 2 ^7-1 = 64 correlation adders, relevant accepted by the SRP. For example, taking the first elementary signal (the first bit of the first SRP transmitted interleaved), 2 ^7-1 = 64 products are calculated by multiplying the last by 64 first bits of 64 reference SRPs and write them to 2 ^7-1 = 64 zeroed correlation adders. The second elementary signal (the first bit of the second SRP) is received, 64 products are calculated by multiplying the last by 64 first bits of the 64 reference SRPs and write them to the next 64 zero correlation adders. Accepting the eleventh elementary signal (second bit of the first SRP), 64 products are calculated by multiplying the last by 64 second bits of 64 reference SRPs and add them to the first 64 correlation adders. Thus, all L * (2 ^m-1 -1) = 630 chips are received, gradually calculating 64 correlation sums for each of the ten SRPs contained in the received message. At the end of packet reception, 2 ^m-1 * L = 640 correlation adders accumulated 64 correlation sums for each of the 10 received with distortion SRP (the results of adding the products of the corresponding bits of the received SRP and 2 ^m reference SRP are the convolutions of the received SRP and 2 ^m reference SRP) . In the Recovery block, for each of the 10 received SRPs, one value is selected, the maximum in absolute value, from the 64 correlation sums calculated for it (the maximum modulo sum means that it is calculated for the most similar to the accepted and reference SRP). Based on the number (among 64 correlation sums) and the sign value of this sum, a decision is made which of the reference or additional SRPs is accepted (a negative correlation sum means that one of the additional SRPs is accepted). Similarly, restore all 10 transmitted bandwidth. According to the unambiguous correspondence, 10 PSPs are converted into 10 characters with a length of 7 bits. Discard (7 * 10-64) = 6 last bits of the last character and receive the original information packet (64 bits), which is transmitted to the Coordination Unit, where this packet is converted into a format adapted for transmission through the Radio Station Port (in particular, 8 bytes for transmission via RS232 port). The control unit configured for reception receives data from Port 1 and transmits to Inf. The port of the radio station.

When constructing reference sequences with minimal cross-correlation in other ways (without inverting the first half of the SRP), 2 ⁷ * 10 = 1280 correlation sums are calculated for each SRP received with distortions.

The timing diagram of the reception / transmission of one information packet is shown in Fig.3, which shows the duration of the time intervals for the stages of reception / transmission.

The proposed inventions allow, with various methods of interleaving, to recover more than 25% of information periodically lost or received with interference (the greatest effect is obtained with uniform interleaving, considered in the example), as well as to cut off randomly received information while maintaining a sufficient transmission speed.

The present invention may find application in any communication systems for diversity objects with a dedicated frequency range. Although the present invention has been described by way of example, the scope of the present invention is not limited to it, but is defined only by the claims, taking into account possible equivalents.

Claims (3)

1. The method of noise-tolerant reception and transmission of information over the communication channel with interference and deep fading, which consists in the fact that on the transmitting side the binary information arriving for transmission at certain time intervals is divided into packets of length N bits, each of which is divided into L characters by m bits, with L = N / m, if N = m · L and L = the integer part (N / m) +1, if N = m · L + k, the characters of the obtained information series of characters are replaced unambiguously by the corresponding reference sequences of greater length, interspersed them with education m of the information sequence, the beginning of which is supplemented with a fixed synchronization sequence, the carrier signal is modulated with the resulting total sequence and transmitted to the radio channel, and on the receiving side, the incoming signal is amplified, demodulated, when the synchronization sequence is recognized, the beginning of reception of the encoded information packet is synchronized, elementary signals corresponding to the bits of the transmitted signal are received encoded packet of information, according to the maximum value of the accumulated correlation x sums, each of the L reference sequences received with distortion is restored, the information series of symbols is restored from the selected correspondence of symbols and reference sequences, the initial N bits of the packet are restored from the information series of symbols, characterized in that the reference sequences have the property of minimal cross-correlation, and after each elementary signal, in accordance with the interleaving selected for a given communication channel, determine its membership in the number of the transmitted symbol and the bit number inside the replacement reference sequence, the result of the analog-to-digital conversion of the elementary signal is sequentially multiplied by the bits of 2 ^m reference sequences corresponding to it by the number, the correlation sums are accumulated from these products in the adders corresponding to the number of the reference sequence. 2. The method according to claim 1, characterized in that among the reference sequences, the last 2 ^m-1 sequences are inverse to the first 2 ^m-1 sequences, and the result of the analog-to-digital conversion of each elementary signal is sequentially multiplied by the corresponding ones according to number bits 2 ^m-1 the first sequence number in the recovery information symbols of each of the L received from distortion reference sequences put in the corresponding one of the first or the last sequence As determined by the sign of the maximum absolute value of the correlation sum. 3. A radio station containing a serial transceiver device with an antenna, a Codec and a Control Unit, the information port of which is the information port of a radio station, the output of the Control Unit is connected to the input of a transceiver device, and the Codec on the transmitting side contains a series of Symbol Formation Unit, Display Unit, Block interleaving, block adding sync sequences, and on the receiving side the codec contains a series-connected analog-to-digital conversion Namer, Correlation adders block, Symbol information series recovery block, and User equipment matching block, characterized in that the Codec further comprises a reference signal block containing reference sequences with minimal cross-correlation to replace the symbol information series in encoding, to which the display block and The block for adding a synchronization sequence, and the input of the Control Unit intended for synchronization of the Block of correlation adders and this Block of the bosom signals, connected to the output of the analog-to-digital converter via the Synchronization Sequence Block, the first output of the Control Unit is connected to the second input of the Correlation Adders Unit, its second output is to the second input of the Recovery Unit, and the third to the input of the Reference Signals Unit, the output of which is connected to the third input of the Block of correlation adders, and the Block of correlation adders is designed for the gradual accumulation of correlation sums from the products of the results of analog-to-digital conversion the generation of each of the elementary signals corresponding to the bits of the transmitted encoded information packet to the bits corresponding to them according to the number of all reference sequences in the adders corresponding to the number of the reference sequence.

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