RU2647656C1 - Method of transmission of digital information over a multipath channel - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: invention relates to the transmission of digital information over a multipath channel and can be used in communication systems to ensure the correct reception of the transmitted information. To this end, the method includes generating, on the transmitting side, an information signal as a sequence of symbols, consisting of a sequence of tone pulses transmitted consecutively in time on frequency-spaced subcarriers, the number of which corresponds to the number of time positions for a single symbol duration, and the frequencies of all the subcarriers corresponding to the symbol belong to such a frequency range that the whole sequence of tone pulses constituting this symbol is processed on the receiving side as one tone pulse with a duration equal to the symbol duration.

EFFECT: increasing the stability of the channel for transmitting discrete messages (increasing the coefficient of effective operation of communication channels) subject to selective fading, without complicating communication equipment and without the associated increase in energy consumption.

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Description

The invention relates to the transmission of digital information over a communication channel with multipath propagation and can be used in communication systems to ensure the correct reception of transmitted information.

It is known that when information is transmitted over a communication channel with multipath propagation due to interference of incoming rays, fading occurs in the received signal. These fades affect the transmitted message randomly, selectively in terms of frequency and time of exposure (L. M. Fink. Theory of transmission of discrete messages. M.: Soviet radio, 1970). They have the greatest impact on reducing the likelihood of correctly receiving the transmitted message.

Known methods to mitigate the effect of fading by spacing in frequency. The signal is transmitted through M transmitters and M receivers operating at M different carrier frequencies. The carrier frequency difference is selected so that the signals at the outputs of the receivers are uncorrelated. Since fading affects each of the M transmission channels in different ways, the depth of fading in the total (combined) signal is reduced. The disadvantages of frequency diversity are the need for additional costs of the frequency band (costs increase by M times) and the increase in the number of hardware (transmitters, receivers, and means for generating the resulting signal from M received). Also, the power consumed by this equipment increases either by a factor of M, or the power of each individual transmitter decreases.

Similar methods of data transmission are described in (Theory of electrical communication: study guide / K.K. Vasiliev, V.A. Glushkov, A.V. Dormidontov, A.G. Nesterenko; edited by K.K. Vasiliev. - Ulyanovsk: UlSTU, 2008, p. 305; Theory of electrical communication: Textbook for universities / A.G. Zyuko, D.D. Klovsky, V.I. Korzhik, M.V. Nazarov; Edited by D.D. Klovsky . - M.: Radio and Communications, 1998, p. 208).

In digital data transmission systems, the combined time-frequency methods of mitigating the effect of fading are also actively used, which use an algorithm for generating and detecting signals that are frequency-manipulated taking into account the time-frequency matrices corresponding to a multi-element symbol sequentially transmitted by tone pulses along frequency-spaced subchannels, the number of which corresponds to the number of temporary positions for the duration of one character. For example, the method of DTT (double frequency telegraphy) is known, which consists in the fact that one bit character of a message is transmitted on one of four parallel subcarriers of frequencies F1, F2, F3 and F4. If, for example, the radiation is transmitted at a frequency of F1, then it may correspond to the transmission of a dibit “00”. The radiation at the frequency F2 can correspond to the transfer of the dibit “01”, the radiation at the frequency F3 can correspond to the transfer of the dibit “10”, and the radiation at the frequency F4 can correspond to the transfer of the dibit “11” [L. Fink Theory of discrete message transmission. - Soviet Radio, 1963. - S. 133, 289].

Closest to the claimed is a method of transmitting discrete information via a sonar communication channel in the conditions of multipath signal propagation, described in paragraph RF №2519011 C1. This method of frequency-diversity transmission of discrete messages determines an algorithm for generating and detecting radio signals manipulated in amplitude and frequency, taking into account time-frequency matrices corresponding to a multi-element symbol sequentially transmitted by radio pulses on frequency-spaced subcarriers, the number of which corresponds to the number of time positions for a duration of one symbol . The probability of the correct reception of a symbol is increased by replacing one subcarrier during the symbol with a sequence of subcarriers, the probability of simultaneous defeat of which by frequency selective fading is significantly lower than the probability of damage of one frequency.

However, the need to receive and extract from the received signal several time subcarriers successively over the duration of one symbol reduces the information transfer rate or, with a proportional decrease in the detection time of each subcarrier, reduces the frequency selectivity of the receiver. In addition, the complexity of the algorithm for receiving several subcarriers with their subsequent processing compared to the algorithm for receiving a single subcarrier leads to the cost of computing resources and a corresponding increase in energy consumption for implementing the method.

To solve the technical problem of reducing the effect of fading during multipath signal propagation (caused by interference of signals of different beams at the reception) using frequency modulation, a method is proposed in which an information signal is formed on the transmitting side as a sequence of characters consisting of a sequence of tone pulses transmitted sequentially in time to frequency-spaced subcarriers, the number of which corresponds to the number of temporary positions in the duration of one s a symbol, while the frequencies of all subcarriers corresponding to a symbol belong to such a frequency range that the entire sequence of tonal pulses making up this symbol is processed on the receiving side as one tonal pulse with a duration equal to the duration of the symbol.

The inventive method allows to increase the stability of the channel for transmitting discrete messages to fading without complicating the communication equipment and without the associated increase in energy consumption.

The following was the basis for solving this problem. In any communication system formed and transmitted by the subcarrier frequency ƒ in the receiver, a certain frequency band ƒ ± Δƒ is associated. When the frequency of the received signal falls into this band, the receiver decides that the subcarrier ƒ has been received. The width Δƒ is determined by the specific problem solved by the communication system used. For example, Δƒ can be determined by the Doppler frequency shift acceptable in a given communication system, or it can be determined by the data transfer rate in the communication system (as is known, the data transfer rate and the required bandwidth are interconnected).

It is proposed to expand the spectrum of the generated signal within the above-described frequency band ƒ ± Δƒ. The expansion of the spectrum can be performed by known methods, for example, by sequentially transmitting tonal pulses on frequency-spaced subchannels, the number of which corresponds to the number of temporary positions for the duration of one symbol, as in the prototype, or, for example, using LFM (linear frequency modulation).

To receive the symbol formed in the above-described way, the algorithm for receiving a single-tone pulse with a duration equal to the duration of the symbol is used without complication, that is, the restrictions imposed by the claimed method on Δƒ allow us to accept the entire multi-tone symbol as single-tone, which is one of the advantages of the claimed method.

Since the frequency of the subcarrier changes during the transmission of the symbol, the degree of the effect of fading on the received signal also changes, and since the signal is processed on the time interval (duration) of the entire symbol, and not its part, the effect of fading is averaged over the duration of the symbol and the frequency band width 2Δƒ, and as a result of averaging, the depth of fading decreases. Moreover, even a small difference in the frequencies transmitted over the duration of the subcarrier symbol is an effective means of suppressing fading, since with increasing distance between the receiver and the transmitter, the phase difference of the signals of the different subcarriers also increases.

An experimental verification of the proposed method was implemented in acoustic communication equipment of a sonar measuring and recording complex used to communicate with autonomous bottom stations from the ship via the sonar channel, as well as to search for stations if they are displaced from the set points. Bottom stations of the complex are designed for long periods of deployment at sea and have small dimensions, therefore, the power consumed by the station in working condition is a critical parameter. For acoustic communication, a frequency range of 8500-9000 Hz was used. The channel alphabet included 4 characters, so each character contains information about 2 bits of transmitted information. The frequency bandwidth ƒ ± Δƒ corresponding to each symbol in the described communication system is determined by the maximum permissible displacement speed of the vessel relative to the bottom station, equal to 2.65 m / s. Such a permissible relative vessel displacement velocity leads to possible Doppler frequency shifts of the received subcarrier up to ± 15 Hz. Accordingly, the bandwidth of the received frequencies corresponding to the symbol cannot be less than 30 Hz. According to the claimed method, ten subcarriers with a 3 Hz spacing are generated and sequentially transmitted during the symbol duration in the transmitter for each transmitted symbol. At the reception, they all fall into the frequency band that corresponds to the transmitted symbol and are processed in the FFT (fast Fourier transform) procedure, the length of the input data series for which corresponds to the duration of the entire symbol.

The algorithms of the receiver and transmitter of the acoustic modem are implemented as additional routines in the main work program of the station. The simplicity of these algorithms made it possible to ensure their operation without increasing the processor clock speed. Thus, in the standby reception mode, which is the longest and most important from the point of view of energy consumption, the station’s acoustic modem does not increase its energy consumption. At the same time, the application of algorithmic methods to increase the communication range simultaneously with the claimed method of combating fading, increased the range of reliable operation of the communication system from 400 m to 6 km without increasing the transmitter power.

Thus, by expanding the spectrum of the transmitted signal, the proposed solution allows to increase the stability of the discrete message transmission channel (increasing the service factor of communication channels subject to selective fading) using frequency manipulation to fading without complicating communication equipment and without an associated increase in power consumption, then there is a solution to the technical problem posed with the achievement of the claimed technical result.

Claims (1)

A method for transmitting discrete information over a multipath communication channel using frequency-manipulated signals generated and detected as a sequence of tonal pulses sequentially transmitted on frequency-separated subcarriers, the number of which corresponds to the number of temporary positions for a duration of one symbol, characterized in that the frequencies of all subcarriers corresponding to the symbol belong to such a frequency range that the entire sequence of tonal pulses constitutes boiling the symbol is processed in the receiver as a single tone pulse of duration equal to the symbol duration.