RU2735419C1 - Method of transmitting information using a substituting logical ternary noise-resistant code - Google Patents

Abstract

FIELD: computer equipment.

SUBSTANCE: invention relates to the computer equipment. Method of transmitting information using a substituting logic ternary noise-immune code comprises steps of encoding a stream of digital data into a ternary code with symbols which are in form of pulse-width modulation (PWM₃); generated PWM₃ signal is summed with a meander pulse sequence, with amplitude, which assumes values "+1" and "-1", and as a result bipolar pulse sequence is obtained; formed pulse sequence of ternary code is divided into even and odd symbols with formation of half-flows, when receiving, transition from extended quadrature modulation of symbols of in-phase and quadrature component to accelerated representation thereof, is obtained using a "ban" logic element, on inhibiting input of which a meandering signal is sent; half-flows are merged, formed initial stream is summed with inverted meander, as a result, PWM₃ pulses of source code are restored, after which reverse conversion is performed from ternary code to binary one.

EFFECT: technical result consists in improvement of interference protection of data transmission.

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Description

The invention relates to telecommunication systems and can be used in data transmission systems over communication channels. Its use makes it possible to increase the reliability of information transfer without introducing structural redundancy into transmitted messages, to detect errors arising during transmission, both single and multiple, to increase, if necessary, the speed of information transfer and ensure its secrecy.

Known "Methods of transferring information and systems for their implementation" (patent RU No. 2475861 with a priority of 04/27/2013 [1] and patent RU No. 2581774 with a priority of 09/30/2014 [2]), the essential characteristics of which are enclosed in the transition in the transmission of information from the traditionally used binary code with the symbols "1" and "0" to the replacement logical ternary error-correcting coding with the symbols S ₂ , S ₁ and S ₀ , represented by three allowed values of pulse-amplitude modulation (PAM ₃ ), which are duplicated symbols T ₂ , T ₁ and T ₀ , representing the three allowed values of pulse width modulation (PWM ₃ ).

In the patent [2], which was awarded the Rospatent diploma in the nomination "100 Best Inventions of Russia - 2016", the proposed ternary code with symbols S ₂ (T ₂ ), S ₁ (T ₁ ) and S ₀ (T ₀ ) was used according to a new purpose - to increase the information load of the carrier frequency emitted by the transmitter, for which simultaneous (complex) modulation in amplitude, frequency and phase was used. In addition, the “comparability of the results of demodulation of relative phase modulation with base two, used over the main communication channel, and the proposed ternary phase modulation with base two (PM ₂ ³ ), which is based on logical noise-correcting codes with base three, represented by symbols S ₂ (T ₂ ), S ₁ (T ₁ ) and S ₀ (T ₀ ) "(claim 4 of the claims). However, to implement such a possibility, an additional (duplicate) information transmission channel is required, which cannot always be ensured in various practical applications. The essence of the proposed logical error-correcting coding of generated messages with a substitute ternary code is as follows [1, 2].

The method is based on the transformation formulas F associated with replacing the sequence of symbols a _i0 , a _i1 , ..., a _{in of the} binary alphabet A = {0,1} with sequences of symbols d _i0 , d _il , ..., d _{im of the} alphabet D = {00, 11 , 10, 001, 101} based on the following logical encoding schemes:

The proposed encoding establishes a logical correspondence between the binary characters represented in parentheses and their ternary equivalents S ₀ , S ₁ and S ₂ .

In addition, when receiving signals S ₀ , S ₁ and S ₂ provide their duplication signals T ₀ , T ₁ and T ₂ (Fig. 1 and Fig. 4, 5 (plots "a" - "f")). An example of the implementation of such a method for recoding the original bit stream into a logical error-correcting ternary code, proposed in the patent of the Russian Federation No. 2475861 [1], is shown in FIG. 2 and 3. In this case, in FIG. 2 shows a block diagram of the transmitting and receiving sides, and FIG. 4, 5 (diagrams "a" - "f") - the work of the ternary code generator.

As a result, two modulating sequences are formed on the basis of signals S ₀ , S ₁ , S ₂ and signals T ₀ , T ₁ , T ₂ . In this case, if the signals S ₀ , S ₁ , S _{2 are} presented in the form of AIM ₃ into three states, then the corresponding signals T ₀ , T ₁ , T _{2 are} displayed in the form of PWM ₃ , which also has three allowed positions of the pulse duration T ₀ , T ₂ = 1.5T ₀ , T ₂ = 2T ₀ , where T ₀ is the time duration of the symbols "1" and "0" of the original binary code. As a result of this, the stream of digital data generated for transmission, first displayed by the sequences of symbols "1" and "0" of the binary code, after re-encoding into a logical noise-immune ternary code with symbols S ₂ (T ₂ ) ↔ <101> ₂ , S ₁ (T ₁ ) ↔ <10, 001> _2, and S ₀ (T ₀₎ ↔ <00.11> _2, are two redundant flows at the primary (pulse) modulation: PWM and PAM _{3 3.} The possibility of such a representation of the original stream of transmitted symbols at the level of primary (pulse) modulation with two copies of them using AIM ₃ and PWM ₃ has no analogs except for the original sources [1] and [2], which are prototypes.

The essential characteristics of the proposed invention are the following distinctive features:

1) in the transition at the final stage of the formation of new signal-code structures to the images of the generated pulse sequences used for the subsequent second stage of modulation (secondary modulation), when the primary pulse form of signals is transferred to the modulation of the carrier frequency (amplitude, frequency or phase);

2) in the use of ternary code to modernize the existing methods of quadrature modulation of the carrier frequency of the radio signal.

The transition to images of representation of transmitted information and its signal-code structures (SSC) is one of the most promising directions in the development of telecommunication systems. This is also facilitated by the emerging various forms of concise presentation of generated messages and signals. Among them are residual images, which leave the basis for additional coding of transmitted and processed information represented by a binary code (RF patents No. 2434301, No. 2434302, No. 2434303, No. 2434304, No. 2444066, No. 2445709, No. 2447492, No. 2457543, No. 2586605, No. 2586833, No. 2609747 [3], No. 2649291 [4], No. 2658795 [5]).

In the proposed invention, the formation of images of the transmitted SCC is performed at the subsequent (with respect to the representation of data and messages by image-residues) stages (i) of distributed structural-algorithmic transformations (SAP-i), when the binary code is converted into ternary with duplicate symbols S ₂ (T ₂ ) ↔ <101> ₂ , S ₁ (T ₁ ) ↔ <10.001> ₂ and S ₀ (T ₀ ) ↔ <00.11> ₂ . At the same time, for the transformation of the formed ternary code with symbols S ₂ (T ₂ ) ↔ <101> ₂ , S ₁ (T ₁ ) ↔ <10, 001> ₂ and S ₀ (T ₀ ) ↔ <00,11> ₂ into its The images use "meander" technologies, the essence of which is that the generated PWM signal ₃ with two levels of quantization in amplitude (-1, +1) and three durations: T ₀ = T ₀ , T ₁ = 1.5T ₀ and T ₂ = 2T ₀ (Fig. 6, plot "a") are summed on the transmitting side with a meander pulse sequence {λ _i } with an amplitude taking values "+1" and "-1" (Fig. 6, plot "c") having a repetition period T ₀ , as a result of which a bipolar pulse sequence is obtained with a pulse duration of T _0/2 (Fig. 6, plot "d"), taking the following amplitude values: "+2", "0" and "-2" ... Then, the generated ternary code pulse sequence with the symbols "+2", "0" and "-2" is used to upgrade existing quadrature secondary modulation of the carrier frequency.

In analogous inventions [1] and [2], cases of simultaneous use of several types of secondary modulation were considered, when a change in the initial information pulses corresponding to the code symbols manifests itself in the form of a corresponding change in the carrier frequency of radio signals in the form of amplitude, frequency and phase, which corresponds to the use of amplitude , frequency and phase modulation.

Also known are their more complex forms, which form the basis of various methods of quadrature modulation. They are associated with the formation of quadrature components, which are in-phase (Q (t)) and quadrature (I (t)) substreams of transmitted codewords, data and messages (Fig. 8) ([6], Feer K. Wireless digital communication. Methods modulation and spreading of the spectrum (Wireless Digital Communications: Modulation and Spread Spectrum Applications). - M .: Radio and communication, 2000. - 552 p. - ISBN 5-256-01444-7). For this, the initial stream of binary code symbols "1" and "0" formed for transmission, which is a digital baseband signal, is divided into two components, one of which is conditional "odd" bits (in-phase substream of bits (Q (t)), and the second "even" bits (quadrature sub-stream of split bits (I (t)) (FIG. 8).

In the proposed invention, the generated stream of pulses of the ternary code with the symbols "+2", "0" and "-2" having a duration T _0/2 (Fig. 6, plot "d") is divided into even ones (Fig. 6, plot "e") and odd pulse subsequences (Fig. 6, plot "e"), taking the following two amplitude values "+2", "0" (Fig. 6, plot "e"), and "0", " -2 "(Fig. 6, plot" e ").

Then, in accordance with the fundamental principles of quadrature modulation, the pulses of each of the obtained subsequences "+2", "0" (Fig. 6, plot "e") and "0", "-2" (Fig. 6, plot "e") are expanded twice, as a result of which their duration is doubled and it becomes equal to T ₀ , both for the in-phase component (Q (t)) (Fig. 6, plot "g"), and for the quadrature component (I ( t)) (Fig. 6, plot "h"). As a result, the in-phase component (Q (t)) (Fig. 6, plot "g") changes the phase of the carrier by 0 ° and 180 ° in its analytical description according to the law of "cosine", and the quadrature component (I (t)) ( Fig. 6, plot "h") also changes the phase of the carrier by 0 ° and 180 ° when it is analytically described according to the "sine" law. As a result, a result of secondary carrier modulation is obtained, similar to that observed using the existing method of quadrature modulation (Fig. 8).

When receiving, the reverse operation of restoring the transmitted symbols of the ternary code T ₀ , T ₁ = 1.5T ₀ , T ₂ = 2T _{0 is} carried out, where T ₀ is the time duration of the symbols “1” and “0” of the original binary code. For this, the meander signal, recovered after demodulation by the phase detector of the carrier frequency, the sequence of the in-phase component (Q (t)) (Fig. 6, plot "g"), is fed to the inhibiting input of the logic element "Disable", while implementing the operation denoted as ( λ _i ^-1 ) (Fig. 7, plot "h ^* "). The same is done with respect to the quadrature component (I (t)) (Fig. 7, plot "x ^* "). From similar representations on the transmitting side (Fig. 6, plot "g") and (Fig. 6, plot "h") reconstructed sequences (Fig. 7, plot "g ^* ") and (Fig. 7, plot "h ^*" »)) May differ only due to the effect of interference and distortions that they undergo when transmitting information. In this case, the transition from the symbols of the in-phase (Q (t)) and the quadrature component (I (t)) extended during quadrature modulation to their accelerated representation with durations T _{0/2 is} obtained, as noted earlier, using the "Forbid" logic element, on the inhibiting input of which a meander signal is applied.

After that, the symbols of the inphase (Q (t)) (Fig. 7, plot "e ^* ") and the inverted quadrature component (I (t)) (Fig. 7, plot "w ^* ") are added, as a result of which the ternary code is restored in the form: "+2", "0" and "-2", having a duration of T _0/2 (Fig. 7, plot "d ^* ")).

Finally, the original sequence of symbols of the ternary code T ₀ , T ₁ = 1.5T ₀ , T ₂ = 2T ₀ , which was originally formed on the transmitting side, is obtained by summing the ternary code with the symbols: "+2", "0" and " -2 ", having duration T _0/2 (Fig. 7, plot" d ^* ") with an inverse meander signal, realizing with respect to its form shown in Fig. 6, plot "c"), the reverse operation (λ _i ^-1 ).

As a result, the noise immunity of the transmitted signals will be increased. One of the components of this technical effect is due to the fact that the noise immunity of the meander restored on the receiving side will be significantly higher compared to the received signal, since it is formed on the basis of receiving synchronization signals, for which, in accordance with the communication theory, higher requirements are imposed on a similar indicator.

The patent [1] shows a sequence of operations by means of which the proposed algorithm for recoding a binary code into ternary code with duplicate symbols S ₀ (T ₀ ), S ₁ (T ₁ ) and S ₂ (T ₂ ) is implemented based on logic circuits. Block diagrams of devices that implement the method [1] are shown in Fig. 2 and 3. In this case, in FIG. 3 shows the logic diagram of the ternary code generator 5. FIG. 3 are represented by letters from "a" to "f" information sections, which coincide with the corresponding designations used for the designations of the diagrams, which are shown in FIG. 4 and FIG. 5 (A).

The main objective of the patent [1] was to show the possibility of a fairly simple implementation of the process of transition from a binary code to the proposed ternary coding based on binary logic, which is the basis for the functioning of the existing element base.

With regard to the on-board radio telemetry system (BRTS), the transmitting side contains [1] (Fig. 2): sensors - 1 ₁ , 1 ₂ , ..., 1 _N , the outputs of each of which are connected to the corresponding N inputs of the block 2 for signal compression and synchronization, the output which is connected to the input of the transmitter 3. The block 2 of compression and synchronization of signals contains a switch 4, N inputs of which are the inputs of block 2, a generator 5 of a logical ternary code and a generator 6 of sync signals. In this case, the output 7 of the switch 4 is the first output of block 2 and the first input of the generator 5 of the logical ternary code, the first output 8 of which is the second output of block 2, and the second output 9 is connected to the input of the generator 6 of sync signals, the output of which is connected to (N + 1) the input of the switch 4. The output of the transmitter 3 through the communication channel 10, subject to interference 11, is connected to the input of the receiver 12.

The receiving side contains a receiver 12 having four outputs - one service output 25 connected to the input of the synchronization signal selector 13, and three informational ones connected to the first inputs 28, 29, 30 of the demodulators 16, 15 and 14 of the information signals, respectively, the second inputs of which combined and connected to the first output 26 of the synchronization signal selector 13, the second output 27 of which is connected to the combined second inputs of the transmission error correctors 17, 19 and 22, the first inputs of which are connected to the outputs of the corresponding demodulators 14 through the corresponding decoders 18, 20 and 21 of ternary symbols , 15 and 16 information signals, the outputs of the transmission error correctors 22, 19 and 17 are connected respectively to the first 31, the second 32 and the third 33 inputs of the generator 23 of the general message flow, the output of which is connected to the input of the de-switch 24, N outputs of which are 34 ₁ , 34 ₂ ,…, 34 _N , are system outputs.

The disadvantage of the invention [1] lies in the fact that the potential of the proposed ternary coding using symbols T _i , i = 0, 1, 2, represented by pulses (PWM ₃ ) with three permitted durations: T ₀ , 1.5T ₀ and 2T ₀ , where T ₀ is the duration of symbols "1" and "0" of the original binary code, have not been fully disclosed. First of all, this was due to the need for such a coordination of the proposed technology of logical noise-immune ternary coding of information with the existing principles of building radio modems and data transmission systems (DTS), as a result of which the possibility of transition from a binary code to the proposed replacement noise-immune ternary could be implemented in practice without additional improvements. The main disadvantage of replacing the primary pulse-code modulation of the binary code with PWM ₃ when using the proposed three-base code is the different duration of the ternary symbols T _i , i = 0, 1, 2: T ₀ , 1.5T ₀ and 2T ₀ instead of the original value T ₀ ... And at the same time, many of the existing methods of transferring information include operations that are focused only on binary symbols that have the same duration in time T ₀ . These include, for example: Fast Fourier Transform (FFT) operations and existing technologies for using pseudo-randomly jumping radio frequencies (RFHF), which form the basis for expanding the spectrum of radio signal frequencies and providing on this basis the secrecy and security of transmitted information. As a result, it becomes necessary to re-transition from the proposed logical ternary code, operating with symbols T _i , i = 0, 1, 2, to a binary code with symbols "1" and "0", but with their reduced duration T ₀ / n.

One of these options (application for invention No. 2019226490/08 (051949) dated August 22, 2019 [7]) involves filling the durations T ₀ , 1.5T ₀ and 2T _{0 with} "chips", which are pseudo-random sequences in the form of Barker codes with the number of bits N ₀ = 3; N ₁ = 5 and N ₂ = 7 shorter duration. One such option is shown in the illustration in FIG. 5 B). It follows from it that the duration of the symbols "1" and "0" of the Barker codes should be equal to T _0/4 . Thus at the end of each PWM pulse ₃ corresponding to the symbols of the ternary code T _0, 2T, and 1.5T _{0 0} after inscribing Barker codes corresponding empty space remains, which is substituted in the character "1" having a duration of T _0/4. As a result, not a ternary code represented by PWM pulses ₃ , but a continuous sequence of bits with a duration 4 times less than the original symbols "1" and "0" of the binary code, is subject to transmission to the communication channel. As a result, from a narrow-band communication channel, they switch to a broadband one with a base B = 4. In addition, such replacement of the original symbols "1" and "0" with bits of "chips" of a shorter duration does not contradict the possibility of using other technologies and transformations that are used in modern radio modems and SPD. So, for example, the FFT and frequency hopping algorithms should be reoriented to work not with bit durations equal to T ₀ , but with their corrected values T _0/4 .

However, the disadvantage of this method lies in the need to reduce the information transmission rate by 4 times, which may be unacceptable for the case of high-speed information transmission.

In the proposed method, this drawback is partially eliminated: its implementation will lead to the effect when the corrected values of the duration of the pulse sequences will be equal: T _0/2 .

At the same time, additional new essential characteristics of the invention appear, which did not exist before.

As an additional explanation of the essence of the invention, the following should be noted.

The in-phase component Q (t), in accordance with the principles of quadrature modulation of the carrier frequency of a radio signal [6], is represented by a cosine law of change in its values, and the quadrature component I (t) turns out to be phase-shifted by π / 2 = 90 ° and correspond to the sinusoidal law of change in the carrier radio frequencies. Each of the impulse components controls the phase change law of 0 ° and 180 ° of the carrier radio frequency, but due to their shift relative to each other by π / 2 = 90 °, it turns out that each of their modulation states differs by π / 4 = 45 °, which shown in the illustration in FIG. eight.

Thus, a fundamental difference of the proposed method for quadrature modulation of its known analogue [6] is that semiflows not shared bits represented by the symbols "1" and "0", and formed by the addition of a meander with a period of change of T ₀ the image source a three-base code with symbols T _i , i = 0, 1, 2: T ₀ , 1.5T ₀ , 2T ₀ .

On the receiving side, doubled pulses of the reconstructed in-phase and quadrature components of the ternary code, differing from the analogous diagrams given for the transmitting side, only by the influence of interference. Their amplitudes take two values +2 and 0, into which they are converted into changes in the phase of the radio signal 180 ° and 0 °. In this case, the recovered pulses of the in-phase channel Q (t) are fed to the Inhibit logic element, the prohibiting input of which receives an inverted copy of the meander with a repetition period T ₀ , as a result of which an odd sequence of ternary symbols with a pulse duration is restored (Fig. 7, plot “e ^* ")) Equal to T _0/2 , which differs from the same sequence formed on the transmitting side (Fig. 6, plot" d ") by the influence of interference.

In a similar way, the pulses of the quadrature channel I (t) of the ternary code (Fig. 7, plot "and ^* "), expanded twice, are restored, for which they are fed to the Inhibit logic element, the prohibiting input of which receives a direct copy of the meander with a repetition period T ₀ . As a result, an even sequence of ternary symbols is restored with a pulse duration (Fig. 7, plot "k ^* ") equal to T _0/2 , which differs from the same sequence formed on the transmitting side (Fig. 6, plot "e") by the influence interference. The result obtained in this case is inverted (Fig. 7, plot "g ^* ") and summed up with the restored sequence (Fig. 7 (plot "e ^* ")), as a result of which the image of the transmitted ternary code is restored (Fig. 7 (plot "d ^* ")), Taking values +2, 0, -2. It is (without taking into account interference) a copy of what was formed on the transmitting side (Fig. 6, plot "d").

The resulting recovered ternary code T ₀ , 1.5T ₀ , 2T ₀ , identified with PWM pulses ₃ , subject to various kinds of transmission distortions, will be recovered with a higher quality. This effect is caused by the fact that the transmission over the communication channel was not subject to the ternary code itself with symbols: T ₀ , 1.5T ₀ , 2T ₀ , identified with PWM pulses _{3 of the} corresponding duration in time, but its image, presented in Fig. 6, plot "d" in the form of pulses with a duration of T _0/2 with values of +2, 0, -2. This means that it was not a full-fledged signal that was to be transmitted, but its image, devoid of some of its original features. It can simply be said that the signal shown in FIG. 6, the plot "d" in the form of pulses with a duration T _0/2 with values +2, 0, -2, is a "semi-finished product" of the original ternary code shown in FIG. 6, plot "a"), in the form of PWM ₃ .

The same "semi-finished product" of the original ternary code, differing only in that it can be distorted by interference in the transmission of information, is obtained upon restoration on the receiving side (Fig. 7, plot "d ^* "). However, during the subsequent operation of its summation with a meander, which is restored on the basis of synchronization signals, the requirements for noise immunity of which, by definition, are significantly higher, then the meander used in this case more accurately reproduces the shape of PWM ₃ information pulses compared to the case of their direct transmission. In addition, the transmitted image (or a semi-finished product in accordance with the previously given explanation) of the transmitted symbol sequence will be restored in its original form only when information is received. This is also the fundamental difference and essential characteristics of the proposed invention. Thus, the transmitted information at the structural-code level will be additionally protected from interference, unauthorized access (NSD) and information technology impacts (ITV).

This new scientific direction in the synthesis of complex noise-like signals, structural-code and signal-code structures has been actively developing recently under the name "meander noise-like signals (BOS signals)", which are designed to improve the efficiency of satellite radio navigation systems [8] (M. S. Yarlykov "Meander noise-like signals (VOS signals)" and their varieties in satellite radio navigation systems, M .: Radiotekhnika, 2017. - 416 p.).

In this invention, meander technologies were used for a new purpose - to provide comprehensive protection of information from interference, tampering, and ITV when using a new method of economical noise-immune coding of data based on replacement logical ternary codes.

Distinctive features of the proposed invention are also associated with the need to combine various EPS related to coding and modulation of signals into a single consistent information system, which forms the basis for the synthesis of various problem-oriented structured code and SQC.

The novelty and essential characteristics of the proposed method of transmitting information using a substitute logical ternary error-correcting code, which consists in collecting signals from message sources, synchronizing them in time, forming a compressed digital group signal from synchronized collected signals, generating a carrier signal, modulating a carrier signal with compressed digital group signal based on the generated video code and in the subsequent transmission of the modulated signal over the communication channel are as follows. It differs in that, on the transmitting side, digital messages of information sources, represented by an N-bit positional binary code, are subjected to SAP, carried out in the following sequence: first, additional economical coding, using the natural redundancy of the transmitted information to increase noise immunity, followed by a randomizer of the binary code symbols, the purpose of which is to equalize the probabilities of the appearance of the symbols "1" and "0" at its output to approach the value equal to 0.5, after which a compressed digital group signal is formed and encoded with a noise-immune code with the introduction of redundant check symbols, the obtained results of digital transformations the group signal, represented by a binary code with the symbols "1" and "0", are converted into a replacement logical error-correcting code with the symbols S ₀ and T ₀ , S ₁ and T ₁ "S ₂ " and "T ₂ ", While the binary combinations (" 00 "and" 11 ") of the original sequence are two symbols are matched simultaneously formed symbols of the ternary code "S ₀ " and "T ₀ ", the code combinations of the original binary code of the group signal ("001" and "10") are replaced by the generated symbols of the ternary code "S ₁ " and "T ₁ ", And the code combinations of the form" 101 "remaining in the original sequence of the binary code of the group signal are simultaneously put in a one-to-one correspondence with the symbols of the ternary code" S ₂ "and" T ₂ ", after which the first modulating component of the converted first tri-basic video signal containing the symbols" S ₀ "," S ₁ "and" S ₂ ", represent in the form of pulse-amplitude modulation, and the second modulating component of the video signal with the symbols of the three-base code" T ₀ "," T ₁ = 1.5T ₀ "and" T ₂ = 2T ₀ ", Where T ₀ is the duration of one symbol of the original binary code" 1 "and" 0 ", is used for bipolar PWM ₃ , which is a second video signal, the pulses of which with three allowed values: T ₀ , 1.5T ₀ and 2T ₀ take values amplit beats "+1" and then they are summed up with clock synchronization signals, which are a bipolar meander with a period of its repetition T ₀ and the duration of each of the pulses T _0/2 and amplitude values "+1" and as a result of which a replacement three-base code is obtained sequence of symbols "+2", "0" and "-2", each of which has the duration of bipolar pulses equal to T _0/2 , as a result of which, in the new logical sequence, the idea of the original bipolar PWM _{3 is} preserved, but based on the symbols of one the same duration T _0/2, instead of T _0, 2T, and 1.5T _{0 0,} then the generated logical sequence tribasic symbols "2", "0" and "-2" are divided into in-phase and quadrature sub-streams, the first of they are represented by odd symbols, and the second - by even counting symbols of the ternary code, then the duration of each symbol in the substreams with the subsequent quadrature modulation of the carrier is doubled, while in the in-phase and quadratic In the alternate sub-streams of the transmitted data, the change in the polarity of the extended pulses is represented by manipulating the phase of the carrier frequency by 0 ° and 180 °, corresponding to the cosine law for the in-phase component, and by changing the phase of the carrier frequency by 0 ° and 180 °, corresponding to the sine law for the quadrature component, as a result of which the generated and the common signal with quadrature modulation transmitted over the radio channel in its appearance will not have any fundamental differences from existing analogs using a binary code with the symbols "1" and "0" as a basis, on the receiving side each of the received doubled as a result of quadrature modulation binary code symbols belonging to the in-phase and quadrature streams of ternary code symbols, perceived as ordinary pulsed symbolic symbols of the same duration, lead to their original pre-modulated form using the "Forbid" logic element, for which meander signals are fed to its inhibiting input. iodine T ₀ and the duration of each pulse of T _0/2 used in this meander signals are inverted for phase substream and a direct copy of the quadrature component, then the received signals are summed, and the result of this logic sequence is reduced tribasic "2" symbols, "0" and "-2" in the form in which it was formed on the transmitting side, which is then summed with an inverted copy of the meander signal with a period of T ₀ and the duration of each of the pulses T _0/2 for the subsequent transition to PWM _{3 of a} three-basic logic noise-immune code with the symbols "T ₀ ", "1.5T ₀ " and "2T ₀ ", control the reliability of reception based on the parity criterion of the symbols "1.5T ₀ ", enclosed between adjacent symbols "2T ₀ ", with a positive control result integrity and reliability of the information received, decoding of the three-base code with the symbols "T ₀ ", "1.5T ₀ " and "2T ₀ " into the original binary code on Again the following correspondences: "T ₀ " ↔ <11.00> ₂ , "1.5T ₀ " ↔ <10.001> ₂ and "2T ₀ " ↔ <101> ₂ and the established rule of recurrent relationship, in which the last binary character "1 "Or" 0 "of the previous decryption of the ternary code becomes the first character" 1 "or" 0 "of the decoding of the subsequent character of the ternary code" T ₀ "," 1.5T ₀ "and" 2T ₀ ", when restoring these repeated symbols are combined, as a result which restore the original sequence of bits of the transmitted information.

The needs of the existing practice of information transfer, taking into account the new economic conditions, require that, on the one hand, all new information technologies are quickly introduced, which is often hampered by the basic technical solutions implemented in existing practice, and at the same time, the modernization of existing systems and complexes should be minimal at cost. In conditions of such contradictions, those technical solutions that involve the introduction of a minimum of corrections at the hardware level into already existing systems and telemetry complexes acquire special significance. As a rule, traditional methods cannot be used to resolve such contradictions, therefore, a special urgency is felt in the search for various non-traditional reserves. They are based on the establishment of new relationships, both logical and analytical, including between new types of modulation that appear during the transition from a binary code to a more economical logical ternary code that forms the basis of the prototype invention ([2]).

The invention contributes to the development of theory and wider dissemination of the program "Digital Economy of Russia", providing comprehensive protection of information from interference, unauthorized access and information and technical influences.

Sources of information used

1. A method of transferring information and a device for its implementation, patent RU No. 2475861 C1, publ. 04/25/2013, bul. No. 21.

2. A method of transferring information and a system for its implementation, patent RU No. 2581774 C2, publ. 04/20/16, bul. No. 11.

3. Methods for transferring information and systems for their implementation, patents RU No. 2434301, No. 2434302, No. 2434303, No. 2434304, No. 2444066, No. 2445709, No. 2447492, No. 2457543, No. 2586605, No. 2586833, No. 2609747.

4. Method for economical presentation and transmission of bipolar data and signals, patent RU No. 2649291.

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Claims (1)

A method for transmitting information using a replacement logical ternary error-correcting code, which consists in collecting signals from message sources, synchronizing them in time, generating a compressed digital group signal from synchronized collected signals, generating a carrier signal, modulating a carrier signal with a compressed digital group signal based on the generated video code and in the subsequent transmission of the modulated signal through the communication channel, characterized in that on the transmitting side digital messages of information sources, represented by an N-bit positional binary code, are subjected to structural and algorithmic transformations carried out in the following sequence: first, additional economical coding is used to increase noise immunity natural redundancy of transmitted information, followed by a binary code symbol randomizer, the purpose of which is to equalize the probabilities the appearance of the symbols "1" and "0" at its output to approach the value equal to 0.5, after which a compressed digital group signal is generated and encoded with a noise-immune code with the introduction of redundant check symbols, the results of converting a digital group signal, represented by a binary code with the symbols "1" and "0" are converted into a replacement logical error-correcting code with the symbols S ₀ "and" T ₀ "," S ₁ "and" T ₁ "," S ₂ "and" T ₂ ", while binary combinations ("00" and "11") of the original sequence of binary symbols are associated with simultaneously generated symbols of the ternary code "S ₀ " and "T ₀ ", the code combinations of the original binary code of the group signal ("001" and "10") are replaced by the generated symbols of the ternary code "S ₁ " and "T ₁ ", and the code combinations of the form "101" remaining in the original sequence of the binary code of the group signal are simultaneously put in a one-to-one correspondence with the symbols of the ternary code "S ₂ " and "T ₂ ", after which the first Maud the modulating component of the converted first tri-basic video signal containing the symbols "S ₀ ", "S ₁ " and "S ₂ " is represented in the form of pulse-amplitude modulation, and the second modulating component of the video signal with the symbols of the tri-basic code "T ₀ ", "T ₁ = 1.5T ₀ "and" T ₂ = 2T ₀ ", where T ₀ is the duration of one symbol of the original binary code" 1 "and" 0 ", are used for bipolar pulse width modulation, which is a second video signal, the pulses of which are with three allowed values: T ₀ , 1.5T ₀ and 2T ₀ take the values of the amplitudes and then they are summed up with the clock synchronization signals, which are a bipolar meander with a repetition period T ₀ and the duration of each of the pulses T _0/2 and the values of the amplitudes "+1" and "-1", as a result of which a replacement three-base code is obtained, represented by a sequence of symbols "+2", "0" and "-2", each of which has a bipolar pulse duration equal to T _0/2 , as a result of which in a new logical sequences retain the original idea of the bipolar pulse width modulation, but on the basis of symbols of the same duration T _0/2, instead of T _0, 2T, and 1.5T _{0 0,} then the generated logical sequence tribasic symbols "2", " 0 "and" -2 "are divided into in-phase and quadrature substreams, the first of which is represented by odd symbols, and the second - by even counting symbols of the ternary code, then the duration of each symbol in the substreams with subsequent quadrature modulation of the carrier is doubled, while in the in-phase and quadrature substreams of the transmitted data, the change in the polarity of the extended pulses is represented by manipulating the carrier phase by 0 ° and 180 °, corresponding to the cosine law for the in-phase component, and by changing the carrier frequency by 0 ° and 180 °, corresponding to the sine law for the quadrature component at the receiving side, each of the received doubled as a result of quadrature modulation of the symbol in the binary code, belonging to the in-phase and quadrature streams of ternary code symbols, perceived as ordinary pulse symbols of the same duration, lead to their original pre-modulated form using the "Forbid" logic element, for which meander signals with a period of T are fed to its inhibiting input ₀ and the duration of each pulse of T _0/2 used in this meander signals are inverted for phase substream and a direct copy of the quadrature component, then the received signals are summed, and the resulting reduced tribasic logical sequence of symbols, "two", "0 "And" -2 "in the form in which it was formed on the transmitting side, which is then added to the inverted copy of the meander signal with the period T ₀ and the duration of each of the pulses T _0/2 for the subsequent transition to the pulse-width modulated pulses of the tri-basic logic noise-immune code with symbols "T ₀ ", "1.5T ₀ "and" 2T ₀ ", control the reliability of reception based on the parity criterion of the symbols" 1.5T ₀ "enclosed between adjacent symbols" 2T ₀ ", with a positive result of integrity and reliability control of the information received, decoding of the three-base code with the symbols" T ₀ "," 1.5T ₀ "and" 2T ₀ "into the original binary code based on the following correspondences:" T ₀ "↔ <11.00> ₂ ,“ 1.5T ₀ ”↔ <10.001> ₂ and“ 2T ₀ "↔ <101> ₂ and the established rule of recurrent relationship, in which the last binary character" 1 "or" 0 "of the previous decoding of the ternary code becomes the first character" 1 "or" 0 "of the decoding of the subsequent character of the ternary code" T ₀ "," 1 , 5T ₀ "and" 2T ₀ ", during restoration these repeated symbols are combined, as a result of which the original sequence of bits of the transmitted information is restored.

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