RU2116001C1 - Communication system - Google Patents

Abstract

FIELD: transmission and reception of digital information by broad-band, multifrequency-signal-train systems. SUBSTANCE: system that has data sensor, multifrequency signal train generator, switch, output unit, input unit, variable-frequency filter unit for multifrequency signal train, resolving unit, clock generators, pseudorandom exchange generators, and reference-frequency sensors is provided, in addition, with the following units on sending and receiving ends: two P-channel multiplexors and two shapers of frequency-time pseudorandom Latin square (one on sending and one on receiving end) that are used for pseudorandom exchange of lines, columns, and for renaming Latin square items and modulating message characters by data sequence which involves selection of pseudorandom line of Latin square responding to data character transmitted at the moment and determining frequency sequence of multifrequency signal train thereby eliminating simulation of data character. Device for shaping frequency-time pseudorandom Latin square has control unit, two counters, three random-access storage devices, read-only storage, series-to-parallel code converter, two switches, and OR gate. EFFECT: improved noise immunity. 2 cl, 6 dwg

Description

 The invention relates to communication systems, in particular, can be used for transmission and reception of discrete information by broadband systems with sequential multi-frequency signals.

 Known communication systems with sequential multi-frequency (PMF) signals, also called discrete frequency-modulated (manipulated) signals [1-3].

 Of the known communication systems, the closest in combination of essential features and the effect achieved by using it is the system described in [4]. This communication system (prototype) contains on the transmitting side a reference frequency sensor (OCH), a serially connected information sensor, a modulator, a generator of sequential multi-frequency (PMF) signals and an output unit, as well as a series-connected clock generator (TI), a pseudo-random permutation generator ( PSPER) and a switch, the information inputs of which are connected to the outputs of the OCh sensor, and the output is connected to the information input of the modulator, while the second output of the TI generator is connected to the input of the OCh sensor and the second and the inputs of the PSPPER generator and the PMP signal generator, and the third output is connected to the input of the information sensor, and on the receiving side an OCh sensor, series-connected TI generator, PSPER generator, a switch, the information inputs of which are connected to the outputs of the OCh sensor, and a frequency modulator, and the input unit, the tunable filter unit and the deciding unit are also connected in series, while the second output of the TI generator is connected to the second input of the PSPER generator and the input of the OCh sensor, and the third output is connected to the additional input p the decision block and the second inputs of tunable filters, the third inputs of which are connected to the outputs of the frequency modulator.

 The block diagram of the prototype is shown in FIGS. 1 and 2, where 1 is an information sensor, 2 is an PMP signal generator, 3 is an output unit, 4, 11 are TI generators, 5, 12 are PSPER generators, 6, 15 are switches, 7 , 13 - OCh sensors, 8 - input block, 9-1, ..., 9-P - tunable filters, 10 - decision block, 14 - modulator, 16 - frequency modulator.

 Transmission and reception in the communication system of the prototype are as follows.

где
⊕ - суммирование по модулю P.On the transmitting side (Fig. 1), the SSPN generator 5, identical to the generator 12 on the receiving side, generates H different K-bit (2 ^K = M, H≤M) numbers (pseudo-random permutation of H numbers), which are sequentially in time, with a step τ (τ = T / H) along K address chains, are fed to the input of the switch 6, to the information inputs of which from the sensor 7 a grid of M reference frequencies is obtained, for example, by dividing one reference frequency F _op . Switch 6, depending on what code (the current value of the pseudo-random permutation) is received at its address inputs, allows the signal to go to the input of modulator 14 from one of the M information outputs of the reference frequency sensor 7. In the information modulator 14, the input signal is manipulated by the symbols of a discrete message received via D (D≤ K) circuits from the information sensor 1, say, the symbols 0 or 1, if the information sequence from the sensor 1 is binary, or the symbols 0, 1, ..., P -1 if the information sequence is P-ary (P = 2 ^D , P≤M). In the first case, with information symbol 0, a code sequence that determines the order of frequency change of the PMP signal passes modulator 14 without changes, with information symbol 1 it is inverted, i.e. in the modulator 14, the information sequence is summed modulo 2 with the code sequence from the output of the switch 6. In the second case (with a P-ary information sequence) in the modulator 14, modulo P summation of the sequences arriving at its inputs is performed. Thus, if a1, a2, ..., aH is the pseudo-random permutation generated by the generator 5 during the time T (duration of the PMP signal), then the operations are performed in the modulator 14: for transmission

Where
⊕ - summation modulo P.

 The code sequence modulated in modulator 14, which determines the frequency switching order in the PMP signal, is fed to the input of the generator 2, which generates elementary oscillation of the PMP signal, which is amplified by power and emitted by the antenna in the output unit 3.

On the receiving side, the signal received by the antenna is amplified, pre-filtered in the input unit 8 and fed to the inputs of tunable filters 9-1, ..., 9-P (P = 2 ^D ) PMP signals, the other inputs of which are private the modulator 16 receives shifted by a discrete number of positions the signals of the sensor 13 of the reference frequency, switched by the switch 15 according to the signals from the generator 12 PSPER synchronized with the generator 5 PSPER on the transmitting side. For the tunable filter 9-1, the signal from the output of the switch 15 is supplied, for example, with a zero shift, on the filter 9-2 - with a shift by one position, on the filter 9-3 - by 2 positions, etc. Tunable filters based on the signal from the PSPPER generator 12 are tuned sequentially in time to the frequencies of elementary oscillations of the emitted PMF signal, the first filter 9-1 being tuned exactly to those frequencies set by the generator 12, the second filter 9-2 tuned with a shift of all frequencies by one position, the third filter 9-3 - 2 positions, etc. Thus, the decision block 10, the inputs of which receive signals from the outputs of all tunable filters 9-1,. . . 9-P will select the largest signal of that filter, the setting of which coincides with the discrete shift of the pseudorandom sequence as a result of information modulation of the elements of the PMP signal on the transmitting side.

 Synchronization of generators 5, 12 SSPPER, sensors 7, 13 of the reference frequency, sensor 1 information, generator 2 PMP signals, tunable filters 9-1, ..., 9-P, the decisive block 10 is carried out by generators 4, 11 clock pulses, identical on the transmitting and receiving sides.

 Note. In the primary source of the prototype [4], the generators 5 and 12 are called code sequence generators (GMS) of a frequency-manipulated (FM) broadband signal (WPS). In our description, the generators 5 and 12 are renamed to pseudo-random permutation generators, because, as noted in the original source, "M frequencies are used in total, and none of them are used twice in one SHPS", the PMP signal in our terminology, and this means that for the duration T of the PMF signal, generators 5 and 12 generate a set of H different pseudorandom numbers a1, a2, ..., aH, which, as you know, is called a permutation (see, for example, Bronstein I.N. Semendyaev K .A. Handbook of mathematics for engineers and students of VTUz. -M .: 1957, p.163 or - M .: 1980, p.199).

 Modulation of the PMP signal by shifting its elementary frequency signals to a certain fixed position associated with the value of the information signal generated by the information sensor 1 allows a simple technical implementation of the modulator 14 on the transmitting and frequency modulator 16 on the receiving side, but has a significant drawback - it allows you to simulate the information signal , for example, by reemitting PMP signals with a constant shift of its elements by the same frequency value. Indeed, let, for example, the PMP signal is formed from 16 frequencies, i.e. M = 16. Therefore, the alphabet of information symbols also does not exceed 16. Let us assume, for concreteness, that the numbers 0, 1, are used as information symbols. .., 15. Then, as already noted, the transmission of an information symbol, say 2, corresponds to a shift in the information modulator 14 of pseudorandom numbers a1, ... aH by two positions: a1 ⊕ 2, ..., aH ⊕ 2, which, in turn, corresponds to the frequency shift of the elements of the PMP signal at the output of the generator 2 also by two positions: f1 ⊕ 2, ..., fH ⊕ 2. It is clear that if information symbol 2 is transmitted and at the same time elements of the PMP signal of higher power are re-emitted with a shift, for example, by 3 positions, then the decision block 10 on the receiving side will select the PMP signal f1 ⊕ 5, ..., fM ⊕ 5, t .e. signal corresponding to information symbol 5.

 A similar drawback is the deterministic nature of the modulation function of the pseudo-random sequence that determines the switching law of the elements of the PMF signal, the information sequence is also inherent in analogues. So, in the system from pr. Zhuravlev V.I. Search and synchronization in broadband systems. - M.: Radio and communications, 1986, p. 9, fig. 1.3, a modulation method is used, similar to that already described, when "a broadband signal (BSC) is additionally manipulated with binary message symbols, with the 1 symbol corresponding to the original BSS, and the 0 symbol its inversion" (for this, an absolute code to relative code converter is inserted into the device (AK / OK), to the input of which binary signals of the discrete message d (t)) are received.

 The aim of the invention is to increase the noise immunity of a communication system.

 This goal is achieved by the fact that in a communication system containing on the transmitting side an information sensor, a reference frequency sensor, a switch, a series-connected clock pulse generator and a pseudo-random permutation generator, as well as a series-connected multi-frequency signal generator and an output power amplification unit, while the third the output of the clock generator is connected to the input of the information sensor, on the receiving side, the reference frequency sensor, series-connected generator clock pulses and a pseudo-random permutation generator, as well as a pre-filtering input block, tunable filter block and a deciding block connected in series, while the third output of the clock pulse generator is connected to the second inputs of the tunable filter block and an additional input of the deciding block, a P-channel is introduced on the transmitting side a multiplexer and a former of a time-frequency pseudo-random Latin square, the information inputs of the P-channel multiplexer being connected to the outputs of the reference frequency sensor, and the outputs are connected to the information inputs of the switch, the address inputs and outputs of which are connected to the outputs of the information sensor and the first input of the sequential multi-frequency signal generator, the first, second, third and fourth inputs of the frequency-time pseudo-random Latin square shaper are connected respectively to the third , the second, first outputs of the clock generator and the outputs of the pseudo-random permutation generator, and the first, second and third outputs are connected respectively directly to the second input of the pseudo-random permutation generator, the address inputs and the combined gating input of the P-channel multiplexer, the input of the reference frequency sensor and the second input of the sequential multi-frequency signal generator, and on the receiving side, the P-channel multiplexer and the time-frequency pseudo-random Latin square, the information inputs of the P-channel multiplexer are connected to the outputs of the reference frequency sensor, and the outputs are connected to the third inputs of the tunable filter unit ov, the first, second, third and fourth inputs of the frequency-time pseudo-random latin square generator are connected respectively to the third, second, first outputs of the clock generator and the outputs of the pseudorandom permutation generator, and the first, second and third outputs are connected respectively to the second input of the pseudo-random permutation generator , the address inputs of the P-channel multiplexer and the combined gate input of the P-channel multiplexer and the input of the reference frequency sensor.

 The frequency-time pseudo-random Latin square shaper consists of a control unit, first and second counters, first, second and third random access memory, read-only memory, first and second keys, a serial to parallel converter and an OR element, with the first and third inputs, The first and third outputs of the frequency-time pseudo-random Latin square shaper are the first and third inputs, the first and fourth outputs of the control unit, the single installation input of the first counter and the second input of the control unit are the second input of the frequency-time pseudo-random Latin square shaper, the fourth input and second outputs of which are the combined information inputs of the first, second and third random access memory devices and the outputs of the serial code to parallel converter, while the outputs of the first counter are connected to the address inputs of the first random access memory and through the follower but the first key, the second key and the OR element are connected to the address inputs of the third random access memory, the outputs of the second counter are connected to the address inputs of the second random access memory and the inputs of the second key, the outputs of the first random access memory are connected to the first address inputs of the read-only memory, the second address the inputs and outputs of which are connected respectively with the outputs of the second random access memory and the second inputs of the OR element, sec the second, fourth, fourth, fifth, sixth and seventh outputs of the control unit are connected respectively to the combined counting input of the first counter and the clock input of the serial to parallel converter, the combined control input of the first key and the first control input of the first random access memory, combined the counting input of the second counter , the control input of the permanent storage device and the installation input of the serial to parallel converter, combined the control input of the second key and the first control input of the second random access memory, the combined installation input of the second counter and the second control inputs of the first, second and third random access memory and the first control input of the third random access memory, the outputs of which are connected to the inputs of the serial code converter in parallel.

 The block diagram of the inventive communication system is presented in FIG. 3 (transmitting part) and FIG. 4 (receiving part), where 1 is an information sensor, 2 is a generator of sequential multi-frequency signals, 3 is an output power amplification unit, 4, 11 are clock generators, 5, 12 are pseudorandom permutations generators, 6 is a switch, 7, 13 is reference frequency sensors, 8 - input pre-selection block, 9-1, ..., 9-P - tunable filters, 10 - decision block, 14, 16 - P-channel multiplexers, 15, 17 - frequency-time shapers (CV ) pseudo-random Latin square, 15-1, 15-2 (17-1, 17-2) - the first, second keys, 15-3 (17-3) - the converter in series go code in parallel, 15-4, 15-10 (17-4, 17-10) - first, second counters, 15-5, 15-6, 15-9 (17-5, 17-6, 17-9 ) - the first, second, third random access memory, 15-7 (17-7) - read-only memory, 15-8 (17-8) - the OR element, 15-11 (17-11) - the control unit.

 In the proposed communication system on the transmitting side (Fig. 3), the TI generator 4 is connected by a first output to the PSPPER generator 5, a 15 pseudo-random Latin square driver 15, a P-channel multiplexer 14, a switch 6, an PMP signal generator 2 and an output unit 3 power amplification, while the address inputs of the switch 6 and the information inputs of the P-channel multiplexer 14 are connected to the outputs of the sensor 1 information and sensor 7 OF, respectively, the third, second and first outputs of the generator 4 TI are connected respectively First, second and third inputs of the driver 15, the first and third outputs of which are connected respectively to the second input of the PSPN generator 5 and the combined gate input of the P-channel multiplexer 14, the input of the OP sensor 7, and the second input of the PMP signal generator 2.

 In the shaper 15 (the shaper 17 identical to it on the receiving side (Fig. 4)), the first input and the second outputs are the first input of the control unit 15-11 (17-11) and the outputs of the serial code converter 15-3 (17-3) to parallel , the combined installation input of the first counter 15-4 (17-4) and the second input of the control unit 15-11 (17-11) are the second input of the driver, the fourth, third inputs, the first and third outputs of which are the combined information inputs of the first, second and third RAM 15-5, 15-6 and 15-9 (17-5, 17-6 and 17-9), t this input, the first and fourth outputs of the control unit 15-11 (17-11), while the outputs of the first counter 15-4 (17-4) are connected to the address inputs of the first RAM 15-5 (17-5) and through the first connected in series key 15-1 (17-1), the second key 15-2 (17-2) and the OR element 15-8 (17-8) - with address inputs of the third RAM 15-9 (17-9), the outputs of the second counter 15 -10 (17-10) are connected to the address inputs of the second RAM 15-6 (17-6) and the inputs of the second key 15-2 (17-2), the outputs of the first RAM 15-5 (17-5) are connected to the first address inputs ROM 15-7 (17-7), the second address inputs and outputs of which are connected respectively to by the strokes of the second RAM 15-6 (17-6) and the second inputs of the OR element 15-8 (17-8), the second, third, fourth, fifth, sixth and seventh outputs of the control unit 15-11 (17-11) are connected respectively to the combined counting input of the first counter 15-4 (17-4) and the clock input of the serial code converter 15-3 to parallel, the combined control input of the first key 15-1 (17-1) and the first control input of the first RAM 15-5 (17- 5), combined by the counting input of the second counter 15-10 (17-10), the control input of the ROM 15-7 (17-7) and the installation input of the converter 15-3 (17-3) after code in parallel, the combined control input of the second key 15-2 (17-2) and the first control input of the second RAM 15-6 (17-6), the combined installation input of the second counter 15-10 (17-10) and the second control inputs the first, second and third RAM 15-5, 15-6 and 15-9 (17-5, 17-6 and 17-9) and the first control input of the third RAM 15-9 (17-9), the outputs of which are connected to the inputs Converter 15-3 (17-3) serial code in parallel.

 On the receiving side (Fig. 4), the input pre-selection block 8 is connected to the inputs of tunable filters 9-1, ..., 9-P, the outputs of which are connected to the corresponding inputs of the decision block 10; the generator 11 TI with the first output is connected to a series-connected generator 12 PSPER, the driver 17 FW pseudo-random Latin square and P-channel multiplexer 16, the information inputs of which are connected to the outputs of the sensor 13 OCh, and the outputs are connected to the third inputs of tunable filters 9-1, .. ., 9-P, while the third output of the generator 11 TI is connected to the first input of the former 17, the second inputs of the tunable filters 9-1, ..., 9-P and an additional input of the deciding unit 10, the second, the first outputs of the generator 11 TI are connected according tween a second, third inputs shaper 17, the first and the third output is connected respectively to the second input of the generator 12 and the combined PSPER strobe input of P-channel multiplexer 16 and sensor input 13 RON.

 The principle of operation of the proposed system is illustrated in FIG. 5 and 6.

 The formation of the PMP signals in the communication system of the prototype is reduced to the generation of a pseudorandom permutation a1, a2, .. over time T (duration of the PMP signal). , aH, modulation of this sequence with an information symbol (say, summing modulo P the values of the permutation and the information symbol J: a1 ⊕ J, ..., aM ⊕ J, where J = 0,1, ..., P-1) and sequential radiation with a τ-cycle (τ = T / H) of the PMF signal elements at frequencies fK corresponding to the values aK ⊕ J, K = 1, ..., H of the modified (modulated) pseudorandom permutation.

The main difference of the proposed system is that during the time T of the PMP signal, not one line is formed from the pseudo-random permutation, but a set of lines is a matrix of P • H pseudo-random numbers,
a11 a12 ... a1H
a21 a22 ... a2H
. . .

. . . (1)
. . .

aP1 aP2 ... aPH,
whose rows and columns are respectively H-permutations (H≤M) and P-permutations (P≤M), i.e. permutations consisting of H and P elements.

 We will call such a matrix a time-frequency (FW) Latin (P • H) rectangle (time-frequency - since the rectangle determines the order of switching the frequency of the PMP signal elements for its duration T; Latin - because all the elements in the rows and columns of the rectangle are different ), and the block that produces it is used by the former of the pseudo-random Latin square (blocks 15 and 17, respectively, on the transmitting and receiving sides).

Note. A Latin (P • H) rectangle is a rectangular table of size P • H, in each row and each column of which the elements are not repeated (they are H and P permutations, respectively). For example, location
2 1 5 7 3
1 3 2 4 6
7 4 1 8 5
is a Latin (3 • 5) -rectangle whose rows and columns are 5- and 3-permutations, respectively (that is, consist of 5 and 3 elements) for the set of numbers {1,2 ..., 8}.

 A Latin square of order M is a square table of size MxM filled with M different elements so that each element appears once in each row and each column (see, for example, Hall M. Combinatorics. M .: Mir, 1970; Combinatorial analysis. Tasks and exercises.Edited by K. A. Rybnikov: Nauka, 1982; K. A. Rybnikov Introduction to Combinatorial Analysis (Moscow: Moscow State University, 1985).

 The pseudo-random character of the FW (P • H) -Latanian rectangle (1) is provided by the pseudo-random permutation of rows, columns and re-designation of elements of the Latin square of order M, P, H≤M (of which it is an integral part), recorded in read-only memory 15-7 ( 17-7) of the shaper 15 (17), as illustrated in FIG. 5 by the example of a standard Latin square of order M = 6.

Obviously, any Latin square by rearranging rows and columns can be converted to such a form that its elements in the first row and first column are arranged in a pre-fixed order (most often 1,2, ..., M). Such a Latin square is called standard or normalized (see, for example, Rybnikov K.A. Introduction to combinatorial analysis. M: Moscow State University, 1985). Standard Latin square of order M = 6, whose elements are determined by the expression
aij = ixj (mod (M + 1)), 1≤i≤M, 1≤j≤M,
shown in FIG. 5a.

При подстановке А на место первой строки следует поставить шестую строку, вторая строка остается без изменений и т.д., при подставке B на место первого столбца ставится четвертый и т.д., при подставке C элемент 1 заменяется элементом 3 и т.д.Consider the conversion of rows, columns and elements of this Latin square using, for example, permutations (constructions in the first row of which is the natural order, in the second - broken, the implementation of some kind of permutation of the elements 1,2, ..., 6):

When substituting A, the sixth row should be put in the place of the first row, the second row remains unchanged, etc., when substituting B, the fourth column is replaced by the fourth, etc., when substituting C, element 1 is replaced by element 3, etc. .

 After substituting A (permutation of strings), we get the Latin square depicted in FIG. 5b, after substituting B (column permutation), the Latin square in FIG. 5c, after substituting C (renaming elements), the Latin square in FIG. 5g Taking from the last Latin square (Fig. 5d), let's say the first 4 rows and the first 5 columns (of course, nothing prevents us from using the whole Latin square), we get (4 • 5) - a Latin rectangle that can be considered as a pseudo-random one, if permutations A, B, C are implementations of a pseudo-random permutation generator (in our case, generator 5 (12)).

 The information symbol J (J = 0, ..., P-1) modulates the latitudinal rectangle FW, more precisely, the reference frequencies of the sensor 7, corresponding to the values of the pseudo-random permutations generated by the PSPPER generator 5 (by means of the 15 FW pseudo-random Latin quadrator), in the proposed system, by choosing the row of matrix (1) corresponding to the value of the transmitted character J. Suppose that the value J = O corresponds to the first row a11 ... a1H, the value J = 1 corresponds to the second row a21 ... a2H, etc., then the transmission of the character J will match the selection ki a (J + 1) 1 ... a (J + 1) H, J = 0,1,2, ..., P-1.

 With this modulation method, the advantage of the prototype is preserved (in one PMP signal “M frequencies are used and none of them are used twice”), and at the same time, a new quality appears: for different values of the information symbol, the modulation results are the rows of the FW matrix ( 1) - are not connected with each other by a functional dependence, which excludes the possibility of imitating an indescribable character by regular exposure to transmitted elements of the PMP signal, for example, by re-emitting an element with a shift in its frequency by a fixed number of poses Icy.

 In more detail, the system operates as follows.

 Generators 4 TI, 5 SSPPER, a reference frequency sensor 7, a P-channel multiplexer 14, and a FW generator 15 of a pseudo-random Latin square on the transmitting side (Fig. 6) are identical to the corresponding blocks 11, 12, 13, 16 and 17 on the receiving side (Fig. 4).

 The synchronization of the blocks on the transmitting and receiving sides is carried out by generators of 4 and 11 clock pulses, which generate signals at the second outputs with a period equal to the duration of the PMP signal element (cyclogram 2, Fig. 6; further, only the cyclogram is indicated for brevity), at the third outputs - with a period T = Hτ (H≤M) equal to the duration of the PMP signal (sequence 1), at the first outputs - with a period μτ (μτ << τ) ..

 The clock pulses of the generators 4 and 11, supplied to the first, second and third inputs of the drivers 15 and 17 with periods T, τ and μτ respectively, are, in turn, clock signals for blocks 15-11 and 17-11, which directly control the operation of the blocks 15-1 - 15-10 and 17-1 - 17-10 and for the first, second, third outputs of the shapers - the operation of the generators 5 and 7 PSPER, P-channel multiplexers 14 and 16, sensors 7 and 13 of the reference frequencies and generator 2 PMES (on the transmitting side).

On the transmitting side (Fig. 3), on each T-cycle along the leading edge of the τ-pulse (sequence 2), three pulses (sequence 3) are generated sequentially at the first output of the control unit 15-11, which are supplied by the first output of the driver 15 to the second input 5 PSPER generator to start it. Generator 5 generates three packs of M different K-bit (2 ^K = M) numbers, which are sequentially fed along the K circuits along the fourth input of the former 15 to the combined information inputs of the first, second and third RAMs 15-5, 15-6 and 15- 9.

 Each pack of M numbers is clocked by a synchronization sequence (cyclograms 4.1, 4.2 and 4.3) supplied from the second output of the control unit 15-11 to the counting input of the first counter 15-4 to M, which is pre-zeroed at the installation input by the leading edge of the τ-pulse supplied to the second input of the shaper 15 from the second output of the generator 4 TI. The signals from the output of the counter 15-4 go through K circuits to the address inputs of the first RAM 15-5 directly, to the address inputs of the second RAM 15-6 through the first key 15-1 and to the address inputs of the third RAM 15-9 through the serial chain: the first key 15-1 - the second key 15-2 and the element OR 15-8.

 Random access memory 15-5, 15-6 and 15-9 are controlled by two circuits - the first and second control inputs. The first control inputs of RAM 15-5, 15-6 and 15-9 connected respectively to the third, fifth and seventh outputs of the control unit 15-11 support the "Write / Read" mode, say a signal "0", or the "Storage" mode information, say the signal "1" (sequence diagrams 5, 6, 7). The second control inputs of RAM 15-5, 15-6 and 15-9, combined and connected to the sixth output of block 15-11, supports the mode "Record", say the signal "0", or the mode "Read", say the signal "1" (sequence 8).

When applying the first packet of clock pulses to the counting input of the counter 15-4 (sequence 4.1), the signals "0" (sequence 5 and 8) are fed to the first and second control inputs of only the first RAM 15-5, while the signal "0" applied simultaneously to the control input of the first key 15-1 closes the last, blocking the passage of signals from the output of the counter 15-4 to the address inputs of the second and third RAM 15-6 and 15-9. Therefore, the output signals of the counter 15-4, working with the count coefficient M (it cycles through M = 2 ^K steady states), are sent via K circuits only to the address inputs of the first RAM 15-5, into which, say, 1,2 , ..., M, a packet of M different numbers (pseudo-random permutation) is written, which is fed to its information inputs from the outputs of the 5 PSPER generator. The last pulse of the pack (Mth pulse) at the counting input of the counter 15-4 sets it to zero (initial) state.

 With the arrival of the second packet of clock pulses to the counting input of the counter 15-4 (sequence 4.2), the signals "0" (sequence 6 and 8) are applied only to the first and second control inputs of the second RAM 15-6, while the first key 15-1 is opened by the signal " 1 "at its control input (cyclogram 5), and the second key 15-2 is closed by a signal" 0 "at its control input (cyclogram 6) and the output signals of the counter 15-4 are sent via K circuits to the address inputs of the second RAM 15-6, in which the addresses, also say 1, ..., M, record the second packet of M different numbers (pseudo-random permutation), under Vai at its data inputs from the generator 5 outputs PSPER.

 Similarly, the third pack of M numbers (pseudo-random permutation) supplied to the information inputs of all RAMs is recorded only in the third RAM 15-9, since the output signals of the counter 15-4, if there is a third packet of clock pulses on its counting input (cyclogram 4.3), to the address inputs of only the third RAM, because only its first and second control inputs receive a signal "0" (sequence 7 and 8), while the keys 15-1 and 15-2 are opened by signals "1" on their control inputs (sequence 5 , 6).

 Note that although the output signals of the counter 15-4 when a second, third burst of clock pulses are applied to its counter input also arrive at the address inputs of RAM 15-5 and RAM 15-5, 15-6, respectively, information is not rewritten into the indicated RAMs, so how they are in the "Information storage" mode, since the signals "1" are sent to their first control inputs at this time (cyclograms 5 and 6).

 When the fourth burst of clock pulses arrives at the counting input of the 15-4 counter (cyclogram 4.4), the signals “0” are sent to the first control inputs of the RAM 15-5, 15-6 and 15-9 from the third, fifth and seventh outputs of the control unit 15-11 ( sequences 5-7), locking keys 15-1 and 15-2 and supporting the "Write / Read" mode, and at the second combined control inputs of the indicated RAM, the signal from the sixth output of block 15-11 is switched from the "Write" mode (signal "0 ") to the" Read "mode (signal" 1 ") (sequence 8), while using its slice (differential from 0 to 1) applied to the installation input Meters withstand 15-10, sets the latter in the zero state. Simultaneously with the RAM, it enters the “Read” mode and the read-only memory (ROM) 15-7 with the “0” signal supplied to its control input from the fourth output of block 15-11 (cyclogram 9).

 In the "Read" mode, the signals from the output of the first RAM 15-5 are fed to the first address inputs (lowercase) of the ROM 15-7, the signals from the output of the second RAM 15-6 are sent to the second address inputs (column) of the ROM 15-7, and the signals from the output of the third RAM 15-9 - to the inputs of the Converter 15-3 serial code in parallel.

 Over the duration of the fourth burst of clock pulses, the addresses of the cells of the first RAM 15-5, specified by the output signals of the first counter 15-4, vary from 1 to M (due to the cyclic enumeration of all counter states by the burst of clock pulses at its input), the cell address of the second RAM 15-6, set by the output signal of the second counter 15-10, changes by one (at the first τ-cycle takes the value 1) by a signal, say "0", applied to its counting input from the fourth output of block 15-11 (sequence 9), and the addresses of the cells of the third RAM 15-9 are set by the output signals of the ROM 15-7, fed through element 15-8 to its address inputs.

 As a result of the transition of RAM 15-5, 15-6, 15-9 and ROM 15-7 to the "Read" mode, rows, columns of the Latin square written in ROM 15-7 are rearranged and its elements are renamed, the nature of which is determined by pseudorandom permutations recorded in the first RAM 15-5 (controls the permutation of the rows), the second RAM 15-6 (controls the permutation of the columns) and the third RAM 15-9 (renames the elements).

 The column of the Latin square (the reading order of the elements of which (permutation of lines) is determined by the output signal of the first RAM 15-5 supplied to the first address input of the ROM 15-7, and the column number is set by the output signal of the second RAM 15-6 supplied to the second address input of the ROM 15 -7) enters element by element through the OR 15-8 element to the address input of the third RAM 15-9, determining, in turn, the address of the permutation element recorded in this RAM by the information inputs of the permutation element, which is fed to the input of the converter 15-3 from the output via K circuits consistent co yes in parallel.

 The transformations in RAM 15-5, 15-6, 15-9 and ROM 15-7 on the first step of the τ-pulse are illustrated by the example of a Latin square of order M = 6 (Fig. 5).

 The row permutation, as already mentioned, is specified by the substitution A, the column permutation is the substitution B, and the renaming of the elements is the substitution C.

 Address 1 of the first RAM 15-5 (see the top line of substitution A) corresponds to the number 6 recorded in its memory (see the bottom line of the substitution A), and address 1 of the second RAM 15-6 corresponds to 4 (see substitution B). In accordance with these values (6 and 4) of the signals supplied to the address inputs of the ROM 15-7, at the intersection of the 6th row and the 4th column of the Latin square (Fig. 5a) we find the number 3 (see also Fig. 5c, the result of converting the Latin square into rows and columns, the intersection of the first row and the first column). A signal with this value (3) is supplied from the output of the ROM 15-7 to the address input of the third RAM 15-9. According to the substitution C, the address 3 (upper line) corresponds to the value 2 (lower line of the substitution C). A signal with this value (2 - after rearranging rows, columns and re-designation of elements, see also the intersection of the first row and the first column in Fig. 5d) is fed to the input of the converter 15-3.

 With the second clock at the input of counter 15-1 (cyclogram 4.4), address 2 in substitution A corresponds to the number 2, address 1 in setting B (which does not change until counter 15-1 recounts all M clock pulses) - still 4. From FIG. 5a, at the intersection of the 2nd row and the 4th column, we find the value 1, and at address 1 from the substitution C, the value 3 (see also the intersection of the 2nd row and the first column in Fig. 5d); a signal with this value (3) is supplied to the input of the converter 15-3.

 Similarly, with the third clock signal (address 3 in substitution A, the signal at the address input of RAM 15-5), a signal with a value of 1, etc., is supplied to the input of the converter 15-3. until the 6th clock, until the remaining values (6, 5, 4) of the first column are enumerated (see Fig. 4d).

 In the converter 15-3, which is set to its initial (zero) state by the pulse front (difference from 1 to 0), supplied to its installation input from the fourth output of the control unit 15-11 (cyclogram 9), and synchronized by pulses supplied to its clock the input from the second output of block 15-11 (cyclogram 4.4), modified (by rearranging rows, columns, renaming elements), a column of PK-ary numbers is converted from serial to parallel. That is, not the entire column of M numbers that goes to the input of the converter 15-3 is converted to parallel code, but only the first P numbers (in the example in Fig. 5d, it is assumed that out of 6 column elements only the first 4 elements are used), corresponding to the size of the alphabet, which is chosen from one or another consideration in the communication system.

From the output of the converter 15-3 P numbers (2≤P≤M) in parallel code via PK circuits go to the address inputs of the P-channel multiplexer 14, which is, for example, P multiplexers (switches) from M to 1, to information inputs via M circuits are supplied with a grid of M reference frequencies formed in the sensor 6, for example, by dividing one reference frequency F _op. .

Depending on the state PK of the address inputs of the multiplexer 14, the signals from the output of the reference frequency sensor 7 are switched to certain outputs of the P-channel multiplexer 14 and fed via P circuits to the information inputs of the switch 6 from P to 1, controlled by D address circuits (P = 2 ^D ) signals from the output of the sensor 1 information. From the selected information inputs of the multiplexer 14, the signals appear at its output only if there is a reference pulse cutoff frequency (transition from 0 to 1) supplied from the fourth output of the control unit 5-11 at the gate input of the multiplexer 14 and the input of the sensor 7 (sequence 9); the same signal controls the start of the PMCH generator 2.

 The choice of the reference frequency in the switch 6 depending on the value of the information signal of the sensor 1 (modulation rule) is determined by the rule for selecting numbers from the matrix column (1) formed by block 15, for example, as already noted, the information line 0 (or A) can be associated with the first line matrix (1) (and therefore the corresponding set of reference frequencies of the sensor 7), information sign 1 (or B) - the second row of the matrix (1), etc. Therefore, if, for example, the symbol J is transmitted, J = 0, 1, ..., P-1 at the first τ-cycle according to the signal of the information sensor 1 supplied to the address input of the switch 6, the reference frequency of the sensor 7 is allocated at its output, corresponding to the number a (J + 1) 1 in the first column of matrix (1) (without loss of generality, we can assume, for example, that the number a (J + 1) 1 and the number of the corresponding reference frequency coincide).

 In accordance with the signal (reference frequency of the sensor 7) received at the input of the generator 2 PMP signals, the latter generates a vibration that is amplified by power and emitted by the antenna in the output unit 3.

 At the second and subsequent τ-pulses (sequence 2), up to the H-th (H ≤ M) τ-pulse, when the formation of the PMP signal (the duration of which T = Hτ) is completed, on each τ-clock address of the first RAM 15- 5, specifying the permutation of the Latin square strings written in ROM 15-7, run through the values 1, 2, ..., M due to a packet of clock pulses supplied to the counting input of the first counter 15-4 from the second output of block 15-11 (cyclogram 4.4 or cumulative cyclogram 4 of all clock pulses generated at the second output of block 15-11), and the address of the second RAM 15-6, specifying The er of the column of the Latin square increases for a τ-cycle per unit (sequentially taking the values 2, 3, ..., H) by pulses supplied to the counting input of the second counter 15-10 from the fourth output of block 15-11 (sequence 9). Otherwise, the process of forming and generating an element of the PMP signal (reading from a ROM 15-7 a modified column of M numbers, re-designating its elements in the third RAM 15-9, converting to parallel code in block 15-9, selecting P reference frequencies of the sensor 7 in P-channel multiplexer 14, the allocation of one reference frequency in the switch 6, the generation and emission of the element of the PMP signal in blocks 2 and 3) is similar to the operations described above at the first τ-pulse.

 Moreover, if the symbol J, J = 0, 1, ..., H-1 is transmitted, at the second τ-cycle, the reference frequency of the sensor 7 is sequentially allocated at the output of the information from sensor information 1 to the address of the switch 6, corresponding to the number a (J + 1) 2 of the matrix (1), etc. to a (J + 1) H, i.e., as in the first measure, the transmission of the symbol J corresponds to the selection of the (J + 1) th row of matrix (1).

 A constant value of the control signal at the address input of the switch 6 for the duration of the PMP signal (selection of the reference frequencies of the sensor 7 corresponding to the same row of the matrix (1)) is provided by timing T (cyclogram 1) of the information sensor 1 with signals from the third output of the generator 3 , which are also served as controllers at the first input of the driver 15 (first input of the control unit 15-11).

 On the receiving side (Fig. 4), clock generators 11, 12 pseudo-random permutations, a reference frequency sensor 13, a P-channel multiplexer 16 and a 17 pseudo-random Latin square pulse former, as well as operations of column-wise matrix generation (1) at the output of the former 17 and the grid the reference frequencies at the output of the P-channel multiplexer 16 are identical to similar blocks 4, 5, 7, 14 and 15 and the operations on the transmitting side.

 For the duration T (Т = НT = Hτ) of a sequential multi-frequency signal, a matrix similar to (1) is formed on the receiving side, and, since the information symbol (transmitted row of the FW matrix) is unknown, on each τ-step (element) of the PMP signal in All P values of the current column are used as reference for filters 9-1, ...., 9-P: for filter 9 - 1 - the value of a1R, filter 9-2 - the value of a2R, ..., filter 9-P - the value aPR, R = 1, 2, ..., H.

 The signal received by the antenna is amplified, pre-filtered in the input unit 8 and fed to the inputs of tunable filters 9-1,. . ., 9-P IF signals, to the other inputs of which the output of the P-channel multiplexer 16 receives the reference signals of the sensor 13, synchronized with the reference signals of the sensor 7 at the output of the P-channel multiplexer 14 on the transmitting side, the first filter 9-1 on each τ-cycle is sequentially tuned exactly to the frequency that is determined by the first row of the matrix column (1) produced by the former 17 (15), the second filter 9-2 is tuned to the frequency determined by the second row of the matrix column (1), etc. .

The decision block 10, the inputs of which receive signals from the outputs of all tunable filters 9-1,. . . , 9-P, will select the largest signal of that filter whose reference frequencies (matrix row (1)) coincide with the reference frequencies (matrix row (1)) selected for H τ-cycles by switch 6 on the transmitting side. The code (number) of the channel in which the maximum signal value is reached is output to the decision block 10
In our example (the symbol J is transmitted (PMF signal, the frequencies of the elements of which are determined by the (J + 1) -th row of the matrix (1)), filter 9- (J + 1), to which reference frequency oscillations corresponding to the values are transmitted sequentially in time lines a (J + 1) 1, a (J + 1) 2 ... a (J + 1) H, for H τ -tacts (duration of the PMP signal) will accumulate the maximum voltage and the decision block 10, where the filter with with the largest signal, it will highlight the transmitted character (the number of the (J + 1) th line), which will go to the recipient of the information (or to the input of the decoder, if on the transmitting side it produced s encoding messages).

 To conclude the description of the system’s operation, we note that the conditional reception of the IFP signals is carried out essentially from the second information symbol, since the moment the system is turned on on the transmitting side (the receiving side, as a rule, works in standby (on) mode) can occur between T-pulses, when the operation "Read" is made from RAM, on which information is not yet recorded.

 Thus, the use on the transmitting and receiving sides of the proposed communication system of new units — M-channel multiplexers and frequency-time pseudo-random Latin square shapers — eliminates the main drawback of prototype and analogue systems — the ability to simulate an information symbol, say, by shifting the PMP signal elements by the same frequency value, since the modulation by the message symbol of the initial pseudo-random permutation, which determines the order of the frequencies of the elements of the PMP signal, is carried out in the inventive system not according to a determinate rule that does not change from an information symbol to a symbol, as in the prototype and analogues, but stochastically - each possible value of the information signal is matched (generated) by its own pseudo-random permutation - a Latin square string, in which strings are pseudorandomly represented columns and renamed elements, and modulation consists in choosing a pseudo-random permutation corresponding to the currently transmitted information symbol ; when transmitting the next information symbol, a new set of pseudo-random permutations is formed and again a permutation corresponding to the new information symbol, etc., is selected from it, i.e. there is no functional (deterministic) connection between permutations both within a set and between sets of permutations, which excludes imitation of an information symbol.

 An additional advantage of the claimed system is the low consumption of pseudorandom numbers. Suppose that P = H = M, i.e. the size of the matrix (1) coincides with the size of the Latin square recorded in ROM 15-7. Then the consumption of pseudo-random numbers in the proposed system (3M) is substantially less (M • M) if the matrix (1) were formed, say, by simply filling in the rows (or columns) with pseudo-random numbers.

 The technical implementation of the proposed communication system does not cause fundamental difficulties, since all the blocks introduced into the system can be performed on a domestic element base, for example, on 564 series chips: counters - on 564 IE10 chips, multiplexers - 564 LS2, RAM - 564 RU2; in the latter case, 537 series chips can be used, allowing you to immediately record K-bit words.

Claims (2)

 1. A communication system comprising, on the transmitting side, an information sensor, a reference frequency sensor, a switch, a series-connected clock and a pseudo-random permutation generator, as well as series-connected multiple signals and an output power amplification unit, while the third output of the clock is connected to the input of the information sensor, on the receiving side there is a reference frequency sensor, serially connected clock generator and pseudo generator random permutations, as well as series-connected input pre-filtering unit, tunable filter unit and decision unit, while the third output of the clock generator is connected to the second inputs of the tunable filter unit and an additional input to the decision unit, characterized in that a P-channel is introduced on the transmitting side a multiplexer and a shaper of a time-frequency pseudo-random Latin square, and the information inputs of the P-channel multiplexer are connected to the outputs of the sensor reference frequencies, and the outputs are connected to the information inputs of the switch, the address inputs and output of which are connected to the outputs of the information sensor and the first input of the sequential multi-frequency signal generator, the first, second, third and fourth inputs of the frequency-time pseudo-random Latin square shaper are connected respectively to the third, second , the first outputs of the clock generator and the outputs of the pseudorandom permutation generator, and the first, second and third outputs are connected respectively to the second at the input of the pseudo-random permutation generator, the address inputs and the combined gating input of the P-channel multiplexer, the input of the reference frequency sensor and the second input of the sequential multi-frequency signal generator, and on the receiving side the P-channel multiplexer and the frequency-time pseudo-random Latin square generator, and the information inputs P -channel multiplexer connected to the outputs of the reference frequency sensor, and the outputs are connected to the third inputs of the tunable filter unit, the first, second, the third and fourth inputs of the frequency-time pseudo-random latin square generator are connected respectively to the third, second, first outputs of the clock generator and the outputs of the pseudo-random permutation generator, and the first, second and third outputs are connected respectively to the second input of the pseudo-random permutation generator, address inputs of the P-channel the multiplexer and the combined gate input of the P-channel multiplexer and the input of the reference frequency sensor.  2. The system according to claim 1, characterized in that the frequency-time pseudo-random Latin square shaper consists of a control unit, first and second counters, first, second and third random access memory, read-only memory, first and second keys, a serial code converter in parallel to the OR element, with the first and third inputs, the first and third outputs of the frequency-time pseudo-random Latin square shaper are the first and third inputs, the first and the fourth outputs of the control unit, the combined installation input of the first counter and the second input of the control unit are the second input of the frequency-time pseudo-random Latin square shaper, the fourth inputs and second outputs of which are the combined information inputs of the first, second and third random access memory devices and the outputs of the serial code converter in parallel, while the outputs of the first counter are connected to the address inputs of the first operational memory the device and through series-connected the first key, the second key and the OR element to the address inputs of the third random access memory, the outputs of the second counter are connected to the address inputs of the second random access memory and the inputs of the second key, the outputs of the first random access memory are connected to the first address inputs of the constant storage device, the second address inputs and outputs of which are connected respectively with the outputs of the second random access memory and the second inputs of the OR element, the second, third, fourth, fifth, sixth and seventh outputs of the control unit are connected respectively to the combined counting input of the first counter and the clock input of the serial code to parallel converter, the combined control input of the first key and the first control input of the first random access memory devices, combined by the counting input of the second counter, controlling the input of the permanent storage device and the installation input of the serial converter code in parallel, the combined control input of the second key and the first control input of the second random access memory, the combined installation input of the second counter and the second control inputs of the first, second and third random access memory and the first control input of the third random access memory, the outputs of which are connected to the inputs serial to parallel converter.

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