RU2713384C1 - Method of transmitting information using broadband signals - Google Patents

Abstract

FIELD: radio engineering and communications.

SUBSTANCE: invention relates to radio engineering and specifically to transmission of discrete information by broadband wireless communication systems. Proposed method comprises generation on the transmitting side of a frequency-modulated Doppler-invariant signal, use thereof as a carrier wave, encoding each transmitted alphabet symbol a_i, individual time shift τ of the carrier oscillation argument origin, transmitting the modulated signal through the communication line. At the receiving side, the energy sums of the cross-correlation functions Y(τ) of the input signal with quadrature standards of frequency-modulated signals with given parameters and different time shifts τ_i origin of carrier oscillation signals. Received symbol is assigned the value a_i, for which the found energy sum of the cross-correlation signal processing Y(τ_i) turned out to be maximum.

EFFECT: invention is intended to increase noise immunity by providing a high level of signal/noise ratio.

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Description

The invention relates to the field of radio engineering, namely, to the transmission of discrete information by broadband wireless communication systems, and can be used in the operation of multi-channel systems with modulated carrier frequencies.

A known method of transmitting information in a communication system with broadband noise-like signals (RU 2279182, publ. 2006.06.27), which consists in the fact that they form the carrier signal and the clock frequency, from the clock signal form two quasi-orthogonal or orthogonal pseudorandom sequences, one of which is designed for synchronization (SP), and the other for transmitting information (IP), the phasing of pseudorandom sequences is carried out, two quasi-orthogonal or orthogonal pseudorandom are formed in the receiver random sequences SP and IP synchronize the input signal with reference pseudo-random sequences generated in the receiver and extract information, while digital data coming from the information source for a time equal to the period of the pseudo-random sequence is converted into a shift of one pseudo-random sequence relative to another, and when receiving a signal, the magnitude of this shift is determined and converted into digital data of the received information. Thus, the known method due to the conversion of information into the offset IP relative to the SP allows you to create in addition to the binary channel high-speed channel for transmitting information. However, signal processing by the known method does not provide sufficient noise immunity, which is a disadvantage of the known technical solution, which is especially evident in the case of complex signals of long duration. When working with such signals, the inclusion of the Doppler effect is much more complicated, which is explained by the significant decorrelation of signals distorted due to Doppler dispersion and phenomena of coherence violation during propagation in the medium. For a broadband signal, Doppler distortion leads to a nonlinear signal transformation, while the approximation of the Doppler conversion by a constant shift of the frequency components of the signal spectrum is inapplicable, since the shift does not reflect the signal deformation in the channel, as well as in the process of radiation and reception, under these conditions. Unlike a narrow-band signal, for which the shift can be compensated with a pilot signal, the pilot signal is not needed for a wide-band signal and can be used to increase the information component of the transmitted signal.

, K - число абонентов, объединенных в систему. В общем случае сигналы различных абонентов должны быть попарно ортогональны на интервале длительности двоичных символов T:A known method and system for transmitting information using broadband signals with multiple code division of information channels (CDMA) (Varakin L.E. Theory of signal systems. - M.: Soviet radio, 1970. - 376 s), according to which binary information symbols 1 and 0 are transmitted using multiple signals S _i (t), where i is the subscriber’s number,

, K is the number of subscribers united in the system. In the general case, the signals of different subscribers should be pairwise orthogonal on the interval of the duration of binary symbols T:

The transmission of message symbols using signals S _i (t) indicates that this message is intended for the i-th subscriber, i.e. the signal S _i (t) is simultaneously the address of the message. In systems with CDMA, the signals of various subscribers are transmitted simultaneously in a common frequency band equal to the system bandwidth. The signal spectrum width F is much larger than the message spectrum width F _message . The signals used in these systems have a wide band and, accordingly, a large base: B = FT = F / F _message >> 1. Broadband signals with a large base used in CDMA differ only in form (in structure). The magnitude of the signal base determines the possible number of orthogonal signals, i.e. the volume of the ensemble of signals. When combining the number of subscribers K >> 1 into the system, a large number of possible signals will be required, equal to approximately K, i.e. it is necessary to use signals with a base of B≥K. All signals of the selected ensemble should be formed using certain rules, according to which the cross-correlation responses of the input signal with the reference signals of the alphabet are minimal and only one channel has a maximum output corresponding to the transmitted symbol, which is described by expression (2):

where E is the signal energy S (t),

and satisfy the condition of orthogonality (1) or almost orthogonality. When implementing the known method, significant decorrelation of transmitted complex signals occurs, distorted due to Doppler dispersion at elevated speeds of movement of communication objects, i.e. The response of a matched filter may not be sufficient for stable operation of the system. This drawback is characteristic of all methods of transmitting information using broadband signals with a large base. This explains the loss of communication speed with mobile subscribers.

A well-known method developed by Qualkomm for transmitting information with code division multiplexing, which is used in a cellular mobile radio communication system of general use with code division multiplexing, described in the work of Gromakov Yu.A. Standards and systems for mobile radio communications. - M; AOZT Eco-Trends Co., 1996. Qualkomm code-based multiple access system is built on the principle of expanding the frequency spectrum based on the use of 64 types of sequences formed according to the law of Walsh functions. A base station transmitter can simultaneously transmit information on 64 channels. Each channel uses one of 64 Walsh sequences. When you change the sign of an informational message, the phase of the used sequence changes by 180 degrees. The synchronizing signal, against which information signals are transmitted, serves to introduce the transmitter of the base station and the receiver of the subscriber station in the cyclic phase and provides the transmission of service information. Since Walsh signals have a pronounced regular structure, which is well known, this method has low structural secrecy in multiple access systems with code division multiplexing, as well as poor correlation properties and not long enough code sequences. In addition, the used orthogonal sequences have a limited ensemble volume, and the orthogonality condition is only observed pointwise, and when there is a mismatch in time and frequency, it is necessary to use a synchronization signal, which complicates the system.

Closest to the proposed one is a method of transmitting discrete information using broadband signals (RU 2362273, publ. 2006.02.20), including modulating the carrier wave with a noise-like signal on the transmitting side, transmitting the modulated signal through the communication line, finding the autocorrelation function Y (T) of the signal on the receiving side and a decision on the transmitted symbol value by a comparative analysis of the values Y (T), calculated for different repetition periods T, each symbol a _i of the alphabet coded periodic skim spread spectrum signal with an individual, different from other repetition period T _i, and on the reception side calculated values of the autocorrelation function Y (T) at T = T _i and assign the received symbol, the value a _i, for which Y (t = T) turned out to be maximum.

The known method is characterized by relatively low noise immunity, which is due to a change in the Doppler parameter within the duration of the signal and signal parameters during its propagation to the subscriber.

As already noted, for a harmonic narrowband signal, the Doppler deformation practically consists of a shift, while an additional pilot signal allows one to determine and compensate for the frequency shift of the received signal, but for a broadband signal, the transformation has a complex nonlinear character and compensation by shift is not able to eliminate the decrease in noise immunity. Moreover, the wider the spectrum of the signal, the more difficult it is to isolate it at the reception, having only information about the transmitted signal in the absence of information about the dispersion of the channel. A matched filter, or correlator, "does not see" a distorted signal due to its deformation in the time-frequency plane.

The objective of the invention is to provide a noise-tolerant method for transmitting broadband signals, providing a high signal to noise ratio.

The technical result of the proposed method is to increase the noise immunity due to the use of multiplicative signals invariant to Doppler dispersion as carrier signals due to a change in the Doppler parameter within the signal duration.

The specified technical result is achieved by a method of transmitting information using broadband signals, including modulating the carrier wave on the transmitting side, transmitting the modulated signal through the communication line, finding the correlation function Y (τ) of the signal on the receiving side and deciding on the value of the transmitted symbol by comparative analysis of Y values (τ) calculated for the selected modulation and coding parameter, in which, in contrast to the known one, frequency modules are used as the carrier oscillation the signal is invariant to Doppler variation, each symbol a _{i of the} alphabet is encoded by an individual, different from the others, time shift t of the origin of the argument of the carrier oscillation, and on the receiving side, the energy sums of the cross-correlation functions Y (τ) of the input signal are found with quadrature standards of frequency-modulated signals with specified parameters and various time shifts and the origin of the argument of the carrier oscillation, while assigning the received symbol that value a _i , for the value of the mentioned energy sum turned out to be maximum.

The essence of the method is as follows.

A signal of the form:

where Ω is the initial frequency (ω (t) = Ω / (t-τ));

τ is the offset of the beginning of the signal relative to the origin;

T is the additive signal duration;

γ = const (0≤γ≤1).

Received signal due to Doppler deformation and finite propagation velocity of electromagnetic waves (Cook C., Bernfeld M. Radar signals. - M .: Sov. Radio, 1971; VR Remli. Effect of Doppler dispersion on detection and resolution using matched filters. // TIIER. - 1966. - T. 54. - N 1. - p. 39-46) has the form:

where τ 'is the delay due to the finiteness of the propagation velocity of electromagnetic waves;

α = 1 ± 2V / C is the Doppler parameter;

V is the relative radial velocity between the emitter and the receiver;

C is the signal propagation velocity in the medium;

τ _α is the response time shift in the presence of Doppler distortions.

As a result of correlation processing of the input signal with a pair of orthogonal standards and their energy accumulation, a correlation response R, which is resistant to Doppler dispersion, has a contrast maximum. Comparison of the correlation responses of the channels corresponding to the selected attribute, for example, the signal shift, allows you to select the maximum of them and assign the received symbol a _i corresponding to this attribute.

In the proposed method, a frequency-modulated signal with invariance to the Doppler change, which is called multiplicative and is formed according to the law, is used as a broadband signal:

where t is the current time, τ = const, a parameter that determines the volume of an ensemble of orthogonal signals.

To transmit information, each character a _{i of the} alphabet is encoded by an individual, different from the others, time shift of the origin of the argument of the carrier oscillation. Thus, a modulated signal that is invariant to Doppler distortion is encoded (modeled) by changing, from symbol to symbol, the parameters of the multiplicative signal, namely, by changing the phase origin of the signal. In this case, an expanded volume of the ensemble of signals with increased noise immunity due to the nonlinear but controlled change in its internal phase structure is obtained by matching the scale of the argument on the transmitting and receiving sides.

With this method of transmitting information, the probability of correct identification of the received symbol is significantly increased. Also, the number of simultaneously operating and not interfering communication lines between pairs of subscribers using a known combination of frequency-modulated signal parameters and known to subscribers time shifts of the origin of the carrier wave argument is increasing.

According to the proposed method, in a given accordance with the developed sequence algorithm, the following operations are performed:

1. Form a frequency-modulated (FM) signal that is invariant to Doppler change.

2. Assign for transmission the symbol a _i from the m-dimensional alphabet, which is a frequency-modulated signal with an individual, different from the others, time shift x \ of the origin of the argument of the carrier oscillation.

3. The signal thus formed is transmitted over the communication line.

4. The set of values of the energy sums of the cross-correlation functions Y (τ) of the input signal with the quadrature reference frequency-modulated signals with the given parameters, which are characterized by different time shifts and the origin of the carrier wave, is calculated.

5. The obtained values of the energy sums of the cross-correlation functions are compared and the maximum is selected from them.

6. The accepted symbol, for which the value of the energy sums of the cross-correlation functions Y (τ _i ) turned out to be maximum, is assigned the value a _i .

The method is carried out using a radio communication system, a block diagram of which is shown in the drawing.

The system contains on the transmitting side: information source (s) 1, switch 2, analog-to-digital converter 3, driver of 4 shifts of the multiplicative signal (pulse) relative to the origin, block 5 of the memory with the alphabet of signals, controlled by 6 generator-transmitter multiplicative signals, the first block matching 7 with the radio communication channel 8; on the receiving side: a second coordination unit 9 with a communication line, a receiver 10, a multi-channel correlator 11, a digital conversion matrix 12, an information consumer 13 (indications, reproduction and registration); as well as power supplies of the transmitting and receiving sides, respectively, block 14 and block 15.

Information in analog form is fed to the information inputs of switch 2, which connects the corresponding input to its output, while the output voltage of the switch is supplied to analog-to-digital converter 3. Information from the outputs of converter 3, specified by five binary symbols that appear in parallel as signals " 0 "and" 1 ", is fed to the inputs of the shaper 4 of the shifts of the multiplicative signal relative to the origin. The output of the shaper 4 gives one of the values of the shift of the multiplicative signal relative to its origin (τ ₁ ÷ τ _n ), which is fed to the input of the memory unit 5 to select the signal corresponding to the alphabet element, and then this selected value is transmitted to the input of the controlled multiplier 6 generator signals with parameters specified in accordance with the expression:

and into the radio channel through the first block 7 coordination with the communication line (antenna).

At the receiving side, the received signal through the second block 9 matching with the communication line (antenna) is fed to the input of the receiver 10, performing band-pass filtering of the carrier frequency of the incoming signal. The signal from the output of the receiver 10 is fed to the input of the multi-channel correlator 11, to the second input of which signals of the alphabet a _i are sent from the memory unit 5 with the mentioned alphabet.

The reference signals (signals of the alphabet a _i ) are frequency-modulated signals of a given shape with parameter Ω, characterized by different τ _i shifts of the beginning of the multiplicative signal relative to the reference frame.

The outputs of the multi-channel 11 correlator are connected to the inputs of the digital conversion matrix 12, which converts the output number of the said correlator 11, corresponding to the shift of the beginning of the multiplicative signal relative to its reference point (τ ₁ ÷ τ _n ), into five binary symbols that appear in parallel in the form of signals "0 "and" 1 "at the outputs of matrix 12. This five-digit combination coincides with the combination applied to the information inputs of the shaper 4 of the shifts of the beginning of the multiplicative signal relative to the beginning of counting on the transmitting side. Further, the signals from the outputs of the digital conversion matrix 12 are supplied to the information consumer 13, for example, to the inputs of the indication and registration equipment.

In the information transmission system that implements the proposed method, a multi-channel correlator of a known type can be involved, in particular, made according to the schemes described in the works of Penin P.I. Digital information transmission systems. - M: Soviet Radio, 1976, p. eleven); Okuneva Yu.B. Digital transmission of information by phase-shifted signals. - M .: Radio and communications, 1991 .-- 196 p. and others.

The proposed method using the radio communication system described above can be implemented with varying degrees of noise immunity due to the possibility of additional use of the channel resource, freed up by the lack of the need to use a pilot signal to increase the transmission capacity of information. The pilot signal allows you to determine the Doppler shift and compensate for it in the receiver (when shifting the spectrum of the signal so that it appears in the bandwidth of the matched filter, all the energy of the received signal is involved in the formation of the signal to noise ratio). However, in the proposed method, the applied signal is invariant to Doppler transformation and there is no need to compensate for its influence.

Thus, the replacement of noise-like and wideband signals that exhibit high sensitivity to increasing channel dispersion by multiplicative signals invariant to Doppler deformation, coupled with replacing the autocorrelation process with multichannel cross-correlation processing of the received signal with the quadrature components of the alphabet signals, followed by energy storage, steady peak response characterized by increased noise immunity and low level of lateral le petals provide a fundamental increase in noise immunity. This increase is determined by the level of cross-correlation responses of the matched filter, which, in turn, depend on changes in the parameters used to encode the symbol.

A new set of parameters for separating channels (communication lines), described by a mathematical model of a multiplicative signal, allows you to expand the signal space of the alphabet of transmitted information components through the use of combinations of parameters known to subscribers of an information connection.

In addition, for the implementation of the proposed method does not need synchronization channels and the use of a pilot signal is not essential.

Claims (1)

A method of transmitting information using broadband signals, including modulating the carrier wave on the transmitting side, transmitting the modulated signal through the communication line, finding the correlation function Y (τ) of the signal on the receiving side and deciding on the value of the transmitted symbol by comparative analysis of the values of Y (τ), calculated for the selected modulation and coding parameters, characterized in that as a carrier wave use a frequency-modulated signal that is invariant to the Doppler change, p At the same time, each symbol a _{i of the} alphabet is encoded by an individual, different from the others, time shift τ of the origin of the argument of the carrier oscillation, and on the receiving side, the energy sums of the cross-correlation functions Y (τ) of the input signal with quadrature standards of frequency-modulated signals characterized by predetermined parameters and different time offsets τ _i starts sampling the argument of the carrier wave, the received symbol is assigned the value a _i, for which the value of the energy amount in aimno-correlation processing of signals Y (τ _i) appeared maximal.

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