RU2494550C2 - Transmitter with code division of channels with structural security of transmitted signals - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: transmitter with code division of channels, known from patent No2287904, further includes a frequency divider, a nonlinear masking sequence generator, a nonlinear orthogonal code generator, and each channel circuit includes an internal encoder and a channel signal spectrum generator and corresponding connections thereof in order to form a novel signal-code structure and implementing secure synchronisation in a communication system, which significantly increases structural security of transmitted signals.

EFFECT: high structural security of signals in advanced communication systems.

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Description

The invention relates to the field of radio communications and can find application in wireless access systems, land mobile and satellite communications with high structural secrecy of transmitted signals and noise immunity to intra-system and intersystem interference.

One of the main requirements for advanced communication systems is to ensure high structural secrecy of the transmitted signals, which prevents third parties from intercepting and controlling the transmitted information for criminal purposes.

Known systems of cellular, wireless and satellite communications with code division multiplexing, namely: a cellular mobile communication system of standard IS-95 based on multi-access technology with code division multiplexing CDMA (in foreign terminology - CDMA); Globalstar satellite communications system (USA), promising CDMA systems such as CDMA-450, CDMA-2000 and WCDMA and satellite: SAT-SDMA (South Korea), SW-CDMA (European Space Agency - ESA) [1 , 2], as well as the device [3], which do not fully meet this requirement, allow third parties to intercept and control the transmitted information due to the limited ensemble of signals used, their low structural secrecy, as well as the availability and availability of the synchronization signal.

Closest to the proposed invention is a device [3] (prototype), which includes N information channels, each of which includes a series-connected first encoder, a first interleaver, a first adder modulo two, and a first symbol multiplexer, the output of which is the first output of the information channels, a splitter, a second encoder, a second interleaver, a second adder modulo two and a second symbol multiplexer, the output of which is the second output of the information channels, series-connected address code generator, first decimator, second decimator, the output of which is connected to the second inputs of the first and second symbol compressors, the output of the first decimator is connected to the second inputs of the first and second adders modulo two, and the input of the address code generator is the first input of the information channel, the input of the separator is the second input of the information channel, and the third inputs of the first and second symbol compressors are combined and are the third input of information about the channel, the second output of the splitter is connected to the input of the first encoder, K of the call channels, each of which includes the first encoder, the first interleaver and the first adder modulo two, the output of which is the first output of the call channel, the splitter, the second encoder, the second an interleaver and a second adder modulo two, the output of which is the second output of the call channel, the address code generator and the decimator in series, the output of which is connected to the second inputs of the first and the second adders are modulo two, the input of the address code generator being the first input of the call channel, and the input of the splitter the second input of the call channel, the second output of the splitter connected to the input of the first encoder, J synchronization channels, each of which includes a serial encoder and a repeater characters, and the input of the encoder is the input of the synchronization channel, and the output of the symbol follower is the output of the synchronization channel and the pilot channel, and N + K + J + 1 is L, where L is the total number of transmitter channels, as well as the th generator, the output of which is connected to the input of the generator of synchronization codes and to the input of the generator of orthogonal codes, the generator of orthogonal M-ary codes, whose input is connected to the output of the clock generator, 2 (n + k) modulators, each of which has t information inputs, where n = N / m, ak = K / m, and M reference inputs, where M = 2 ^m , m is the base of the code of the signal used, and N and K are multiples of m, (n + k + J + 1) is the signal spectrum shaper, each of which includes in series connected the first adder modulo two, the second adder modulo two, smoothing a filter, a multiplier and an adder, the output of which is the output of the signal spectrum former, as well as a third adder modulo two, a fourth adder modulo two, a second smoothing filter, a second multiplier, the output of which is connected to the second input of the adder, the first input of the first adder modulo two is the first input of the signal spectrum shaper, the first input of the third adder modulo two is the second input of the signal spectrum shaper, second inputs of the second and fourth adder modulo two are combined and are the third input of the signal spectrum shaper, the second input of the first adder modulo two is the fourth input of the signal spectrum shaper, the second input of the third adder modulo two is the fifth input of the signal shaper, the second input of the first multiplier is the sixth input of the spectrum shaper signal, and the second input of the second multiplier is the seventh input of the signal spectrum shaper, all information channels are divided into n = N / m groups of m channels in each, the first output of each of m inform channel of each of n groups is connected to the corresponding of m inputs of the (2n-1) -th modulator, the second output of each of m information channels of each of n groups is connected to the corresponding of m inputs of the 2n-th modulator, output (2n-1) is of the nth modulator is connected to the first input of the nth signal shaper, and the output of the 2nth modulator is connected to the second input of the nth signal shaper, the output of the nth signal shaper is connected to the nth input of the channel signal adder, all call channels divided into k = K / m groups of m channels in each, per the output of each of m call channels of each of k groups is connected to the corresponding of m inputs of the (2n + 2k-1) -th modulator, the second output of each of m call channels of each of k groups is connected to the corresponding of m inputs (2n + 2k) -th modulator, the output of the (2n + 2k-1) -th modulator is connected to the first input of the (n + k) -th signal shaper, and the output of the (2n + 2k) -th modulator is connected to the second input (n + k) - signal shaper, the output of the (n + k) signal shaper is connected to the (n + k) input of the channel signal adder, the output of each of the J synchronization channels connection is connected to the first and second inputs of the corresponding from the (n + k + 1) th along the (n + k + J) th formers of the signal spectrum, the output of each of the (n + k + 1) th along the (n + k + The J) th signal spectrum conditioners are connected to the corresponding from the (n + k + 1) th (n + k + J) th inputs of the channel signal adder, the first and second inputs of the (n + k + J + l) th the signal spectrum shaper is combined and connected to the output of the pilot channel, and its output is connected to the (n + k + J + 1) -th input of the channel signal adder, each of the n outputs of the orthogonal code generator is connected to the third input corresponding to consisting of n signal spectrum shapers, each of the (n + k) outputs of the orthogonal code generator is connected to the third input of the corresponding of (n + k) signal spectrum shapers, each of the (n + k + 1) -th in (n + k + The J) th output of the orthogonal code generator is connected to the third input of the corresponding from the (n + k + 1) th (n + k + J) th signal conditioners, (n + k + J + 1) th output of the generator of orthogonal codes is connected to - the third input of the (n + k + J + 1) -th signal conditioners, the first output of the synchronization code generator is connected to the combined fourth moves of all signal spectrum shapers, and its second output is connected to the combined fifth inputs of all signal spectrum shapers, the first output of the carrier frequency generator is connected to the combined sixth inputs of all signal spectrum shapers, and its second output is connected to the combined seventh inputs of all signal spectrum shapers, each from the M outputs of the generator of orthogonal M-ary codes is connected to the corresponding of the M combined reference inputs of all modulators.

The aim of the present invention is to increase the structural secrecy of signals in promising communication systems.

This goal is achieved by the fact that in the known device including N information channels, each of which includes a first encoder, a first interleaver, a first adder modulo two, and a first symbol multiplexer, the output of which is the first output of an information channel, a separator connected in series , the second encoder, the second interleaver, the second adder modulo two and the second symbol compactor, the output of which is the second output of the information channel, sequentially connected an address code generator, a first decimator, a second decimator, the output of which is connected to the second inputs of the first and second symbol compressors, the output of the first decimator is connected to the second inputs of the first and second adders modulo two, and the input of the address code generator is the first input of the information channel, input the separator is the second input of the information channel, and the third inputs of the first and second symbol compressors are combined and are the third input of the information channel, the second output section The amplifier is connected to the input of the first encoder, K call channels, each of which includes a first encoder, a first interleaver and a first adder modulo two in series, the output of which is a first call channel output, a splitter, a second encoder, a second interleaver and a second adder module two, the output of which is the second output of the call channel, series-connected address code generator and decimator, the output of which is connected to the second inputs of the first and second adders mode I’ll remove two, and the input of the address code generator is the first input of the call channel, and the splitter input is the second input of the call channel, the second output of the splitter is connected to the input of the first encoder, J synchronization channels, each of which includes a coder and a repeater of characters, the encoder input is the input of the synchronization channel, and the output of the symbol repeater is the output of the synchronization channel and the pilot channel, and N + K + J + 1 is L, where L is the total number of transmitter channels, as well as a clock generator, the output of which one with the input of the generator of synchronization codes and with the input of the generator of orthogonal codes, the generator of orthogonal M-ary codes, the input of which is connected to the output of the clock generator, 2 (n + k) modulators, each of which has m information inputs, where n = N / m , ak = K / m, and M of the reference inputs, where M = 2 ^m , m is the code base of the signal used, and N and K are multiples of m, (n + k + J + 1) is a signal spectrum shaper, each of which includes sequentially connected first adder modulo two, second adder modulo two, smoothing filter, multiplier and sum the torus, the output of which is the output of the signal spectrum former, as well as the third adder modulo two, the fourth adder modulo two, the second smoothing filter, the second multiplier, the output of which is connected to the second input of the adder, the first input of the first adder modulo two the first input of the signal spectrum shaper, the first input of the third adder modulo two - the second input of the signal spectrum shaper, the second inputs of the second and fourth adders modulo two are the third input of the signal spectrum shaper, the second input of the first adder modulo two is the fourth input of the signal shaper, the second input of the third adder modulo two is the fifth input of the signal shaper, the second input of the first multiplier is the sixth input of the signal shaper, and the second input of the second multiplier - the seventh input of the signal spectrum shaper, all information channels are divided into n = N / m groups of m channels in each, the first output of each of the m information channels of each of n g UPP is connected to the corresponding of m inputs of the (2n-1) th modulator, the second output of each of the m information channels of each of the n groups is connected to the corresponding of m inputs of the 2n-th modulator, the output of the (2n-1) th modulator is connected to the first the input of the nth signal shaper, and the output of the 2nth modulator is connected to the second input of the nth signal shaper, the output of the nth signal shaper is connected to the nth input of the channel signal adder, all the calling channels are divided into k = K / m groups of m channels in each, the first output of each of m channels call of each of k groups is connected to the corresponding of m inputs of the (2n + 2k-1) -th modulator, the second output of each of m channels of call of each of k groups is connected to the corresponding of m inputs of the (2n + 2k-1) -th modulator, output ( 2n + 2k-1) -th modulator is connected to the first input of the (n + k) -th signal shaper, and the output of the (2n + 2k) -th modulator is connected to the second input of the (n + k) -th signal shaper, output the (n + k) -th signal spectrum shaper is connected to the (n + k) -th input of the channel signal adder, the output of each of the J synchronization channels is connected to the first and to each input of the corresponding from the (n + k + 1) th along the (n + k + J) th formers of the signal spectrum, the output of each of the (n + k + 1) th along the (n + k + J) th formers the signal spectrum is connected to the corresponding from the (n + k + 1) -th through the (n + k + J) -th inputs of the adder of channel signals, the first and second inputs of the (n + k + J + 1) -th signal shaper are combined and connected to the pilot channel output, and its output connected to the (n + k + J + 1) -th input of the channel signal adder, each of the n outputs of the orthogonal code generator is connected to the third input of the corresponding of n spec signal, each of the (n + k) outputs of the orthogonal code generator is connected to the third input of the corresponding from (n + k) signal spectrum conditioners, each of the (n + k + 1) -th in (n + k + J) -th the outputs of the orthogonal code generator is connected to the third input of the corresponding from the (n + k + 1) th (n + k + J) th signal conditioners, (n + k + J + 1) th output of the orthogonal code generator is connected to the third input of the (n + k + J + 1) th signal spectrum shapers, the first output of the synchronization code generator is connected to the combined fourth inputs of all the special shapers krata of the signal, and its second output is connected to the combined fifth inputs of all the signal spectrum shapers, the first output of the carrier frequency generator is connected to the combined sixth inputs of all the signal shapers, and its second output is connected to the combined seventh inputs of all signal spectrum shapers, each of M the outputs of the generator of orthogonal M-ary codes is connected to the corresponding of the M combined reference inputs of all modulators, the following changes are made to the device circuit:

the following are excluded from it: pilot channel, 2 (n + k) modulators, (n + k + J + 1) signal spectrum shapers, orthogonal M-ary code generator, synchronization code generator, orthogonal code generator and their corresponding communications,

and in the device circuit are additionally introduced:

a frequency divider, the input of which is connected to the output of the clock generator, a nonlinear masking sequence generator, the input of which is connected to the output of the clock generator, a nonlinear orthogonal code generator, the first input of which is connected to the output of the clock generator, L internal encoders, where L = N + K + J , each of which includes the first and second encoders, the first input of the first encoder being the first input of the internal encoder, and the first input of the second encoder the second input of the internal encoder, the second inputs of the first and of the encoders are combined and are the third input of the internal encoder, the third inputs of the first and second encoders are combined and the fourth input of the internal encoder, the fourth inputs of the first and second encoders are combined and are the fifth input of the internal encoder, L channel signal shapers, each of which includes series-connected the first adder modulo two, the second adder modulo two, a smoothing filter, the first phase modulator, adder and bandpass filter, the output of which is the output of the the spectrum signal channel, as well as the third adder modulo two, the fourth adder modulo two, the second smoothing filter and the second phase modulator, the output of which is connected to the second input of the adder, the first input of the first adder modulo two being the first input of the spectrum former channel signal, the first input of the third adder modulo two is the second input of the channel signal spectrum former, the second inputs of the second and fourth adders modulo two are combined and are the third input the channel signal spectrum shaper house, the second input of the first adder modulo two is the fourth input of the channel signal spectrum shaper, the second input of the third adder modulo two is the fifth input of the channel signal shaper, the second input of the first phase modulator is the sixth input of the signal spectrum shaper, and the second the input of the second phase modulator is the seventh input of the spectrum shaper of the channel signal,

and the following relationships were established:

the output of the l-th channel signal spectrum shaper is connected to the l-th input of the channel signal adder, where l takes values from 1 to L, the first output of the nth information channel is connected to the first input of the nth internal encoder, and the second output of the nth information channel - with the second input of the n-th internal encoder, where n takes values from l to N, the first output of the k-th call channel is connected to the first input of the k-th internal encoder, and the second output of the k-th call channel with the second input k-th internal encoder, where k takes values from N + 1 to N + K, output j- -th synchronization channel is connected to the first and second inputs of the j-th internal encoder, where j takes values from N + K + 1 to N + K + J, the first output of the l-th internal encoder is connected to the first input of the l-th channel signal shaper and the second output of the l-th internal encoder is connected to the second input of the l-th channel signal spectrum shaper, the third inputs of all channel signal shapers are combined and connected to the first output of the nonlinear masking sequence generator, the fourth input of the l-th signal spectrum shaper to the channel is connected to the l-th output of the non-linear orthogonal code generator, the fifth input of the l-th channel signal shaper is connected to the (L-l + 1) -th output of the non-linear orthogonal code generator, the sixth inputs of all channel shaper are combined and connected to the first the output of the carrier frequency generator, the seventh inputs of all the formers of the spectrum of the channel signal are combined and connected to the second output of the carrier frequency generator, the third inputs of all internal encoders are combined and connected to the output of the frequency divider, the second the output of the non-linear masking sequence generator is connected to the second input of the non-linear orthogonal code generator and the combined fourth inputs of all internal encoders, the fifth inputs of all internal encoders are combined and connected to the (L + 1) -th output of the non-linear orthogonal code generator, the output of the channel signal adder is the output devices.

Distinctive features of the proposed device are new elements introduced into the transmitter circuit, namely: L internal encoders, L channel signal spectrum shapers, a frequency divider, a nonlinear masking sequence generator, a nonlinear orthogonal code generator and the corresponding connections between them, due to which it was possible to significantly increase structural secrecy transmitted signals due to the formation of a new signal-code structure and the implementation of hidden synchronization in a communication system.

Since the totality of the elements introduced and their relationship to the filing date of the application in the patent and scientific literature are not found, the proposed technical solution corresponds to the "inventive step".

The structural diagram of the inventive device is presented in figure 1. In order to simplify the scheme, Fig. 1 shows only one n-th (n = 1) information channel (IR), one k-th (k = 1) call channel (KB) and one j-th synchronization channel (CC) ( j = J), as well as elements that ensure the functioning of the device and allow to explain the operation of the device as a whole. In figure 1 is indicated:

1, 9, 23, 28, 31, 34, 35 - encoder (CD);

2, 10, 24.29 - interleaver (PM);

3, 11, 25, 30, 13, 18, 14, 19 - adders modulo two (C2);

4, 12 - seal characters (CSS);

5, 22 - separator (P);

6, 26 - address code generator (GCA);

7, 8, 27 - decimator (P);

15, 20 - smoothing filter (CgF);

16, 21 - phase modulator (FM);

17 - adder (Sum);

32 - character repeater (PS);

33 - band-pass filter (PF);

36, 37, 38 - internal encoder (VK);

39, 40, 41 - channel signal spectrum former (FSSK);

42 - adder channel signals (SCS);

43 - carrier frequency generator (LFO);

44 - clock generator (TG);

45 - frequency divider (DC);

46-generator non-linear masking sequence (GNMP);

47 - generator of nonlinear orthogonal codes (SOCC);

IR (n, n = 1) - information converter (PI) of the first

information channel;

KB (k, k = 1) - PI of the first call channel;

KS (j, j = J) - PI of the last synchronization channel.

Transmitter operation. The operation of the transmitter will consider the structural diagram, which is shown in figure 1.

When considering the operation of the transmitter, we will proceed from the following:

1. The algorithm of the converters information channels (IR, KB, KS) of the claimed device and the prototype device is the same.

2. The load on the transmitter channels is determined by the current schedule and is controlled by standard means of the base station, for example, such as a convolver, which are not considered in this device.

3. The total number of transmitter channels is L = N + K + J, where N is the number of information channels; K is the number of call channels; J is the number of synchronization channels. To understand the nature of the information processing in the transmitter, it is sufficient to consider the processing of information in one IR, in one KB and in one CS.

4. The period of the nonlinear masking sequence T _mp generated by GNMP (46) corresponds to a multiple of the periods of sequences generated by SOCC (47) T _gok , i.e. N _mp = 2 ⁱ T _gok , where i = 1, 2, 3 ... 5. In the claimed transmitter in an explicit form, the channel of the pilot signal is absent. In fact, the functions of the pilot channel are performed by one of the available L channels of the device. This channel is selected by the network operator (administrator) and functions are assigned to it to solve the network synchronization problem. Let these functions be assigned to one of the transmitter synchronization channels (CS (j, j = J)).

Then the signal at the output of the FSSK (41) in quadrature components can be represented as

$$S\left(t\right)=P_{\mathrm{one}}{P}_{m}cos\left({\omega }_{0}t\right)+P_2{P}_{m}sin\left({\omega }_{0}t\right),\left(\mathrm{one}\right)$$

where P ₁ and P ₂ are orthogonal sequences that enter the 4 and 5 inputs of the FSSK (41);

P _m is a masking sequence supplied to the 3 input of the FSSK (41).

If on the receiving side this signal is squared, then expression (1) takes the form

$$S^2\left(t\right)=P_{\mathrm{one}}^2{P}_m^{2}co{s}^2\left({\omega }_{0}t\right)+P_2^2{P}_m^{2}si{n}^2\left({\omega }_{0}t\right)+2P_{\mathrm{one}}{P}_2{P}_m^{2}cos\left({\omega }_{0}t\right)sin\left({\omega }_{0}t\right).\left(2\right)$$

Given that when squaring the sequences P ₁ , P ₂ and P _m equal 1, and 2cosαsinα = sin2α, then expression (2) will have the form

S ² (t) = cos ² (ω ₀ t) + sin ² (ω ₀ t) + P ₁ P ₂ 2cos (ω ₀ t) sin (ω ₀ t) = 1 + P ₃ sin (2ω ₀ t).

Thus, after the transformations, we have a double carrier modulated by the P ₃ sequence and a constant component. After filtering the signal with a band-pass filter, only the P ₃ sequence will remain at its output, which is the pilot signal, and the selected channel performs the function of the pilot signal channel.

It should be noted that the sequences P ₁ , P ₂ and P ₃ are sequences belonging to one ensemble of signals.

The work of the information channel. Consider the work of the first IR (n = 1). The first PI input of the first information channel (IR (n, n = 1)) receives information about the subscriber's address, and the second receives information that must be transferred to another subscriber. The information received at the 1 and 2 inputs of the PI is a stream of binary characters. The stream of binary symbols arriving at the second input of the PI of the first IR is converted into two streams by separator (5) to create in-phase I and quadrature Q components (conventionally, even symbols follow in one stream and odd ones in the other). From the first output of the splitter (5), the first stream enters the input of the encoder (9), and from the second output the second stream enters the input of the encoder (1). The streams of binary characters in the encoders (1) and (9) are encoded with redundant code in order to enable error correction at the receiving side. From the output of the encoder (1), the information goes to the input of the interleaver (2), and from the output of the encoder (9) to the input of the interleaver (10). In the interleavers (2) and (10), the encoded information is “mixed” in such a way as to exclude the possibility of grouping errors on the receiving side. From the output of the interleaver (2), the information enters the first input of the adder modulo two (3), and from the output of the interleaver (10) - to the first input of the adder modulo two (11). The stream of binary characters containing information about the address of the called subscriber, from the first input of the PI goes to the input of the GCA (6), which generates the address of the called subscriber and sends it to the input of the decimator (7). Information from the output of the decimator (7) goes to the second inputs of the adders modulo two (3) and (11) and to the input of the decimator (8). In adders modulo two (3) and (11) into the information flows arriving at their first inputs, with the help of decimator (7) information about the subscriber’s address coming from the CCA (6) is “mixed”. From the output of the adder modulo two (3) the information stream containing already a sign of the subscriber’s address goes to the first input of the symbol seal (4), and from the output of the adder modulo two (11) to the first input of the symbol seal (12). In the symbol seals (4) and (12), using the information supplied to their second inputs from the output of the decimator (8), “mixing” into the information stream with the subscriber’s address provides additional information that goes to their third inputs to control the level of the emitted transmitter power subscriber. Information from the output of the symbol seal (4) is fed to the first output of the PI, and information from the output of the symbol seal (12) is fed to the second output of the PI.

The stream of binary symbols from the first and second outputs of the PI of the first IR is supplied respectively to the first and second inputs of the VC (36) of the first IR. The internal encoder includes the first (34) and second (35) encoders and provides additional protection of the transmitted information from interference and signal fading. The stream of binary characters from the first input of the VK (36) goes to the first input of the first encoder (34), and the binary stream of the characters from the second input of the VK (36) goes to the first input of the second encoder (35). The third input of the VK (36), and, consequently, the second inputs of the encoders (34) and (35) receive clock pulses from the output of the frequency divider (45), which provide information input into the VK. The frequency of clock pulses from the output of the PM (45) corresponds to the flow rate of binary symbols coming from the first and second outputs of the PI of the first IR to the first and second inputs of the VC (36). From the second GNMP output (46), the fourth input of the VC (36), and, consequently, the third inputs of the encoders (34) and (35), as well as the second input of the GNOC (47) receive clock pulses that carry out cyclic synchronization of the VC (36) and GNOC synchronization (47). The pulse repetition rate of the cyclic synchronization pulses is determined by the period of the nonlinear masking sequence. The fifth input of the VK (36), and, consequently, the fourth inputs of the encoders (34) and (35) receive clock pulses from the (L + 1) -th output of the GNOC (47), which provide the output of information from the VK (36) . The repetition rate of these clock pulses is determined by the period of the sequence generated by SOCC (47).

Information from the first output of the VK (36) is fed to the first input of the FSSK (39) of the first PC, and from the second output of the VK (36) to the second input of the FSSK (39) of the first IR.

Information from the first input of the FSSK (39) is fed to the first input of the adder modulo two (13), and from the second input of the FSSK (39) to the first input of the adder modulo two (18). Non-linear orthogonal orthogonal code sequences from GNOC (47) are supplied to the second inputs C2 (13) and (18) through the fourth and fifth inputs of the FSSK (39), and a non-linear orthogonal code sequence from the first output of the GNOC (47) is fed to the fourth input of the FSSK (39) ), and to the fifth input of the FSSK (39), a nonlinear orthogonal code sequence from the Lth output of the SOCC (47). Information from the output of C2 (13) is fed to the first input of C2 (14), and information from the output of C2 (18) is fed to the first input of C2 (19). To the second inputs C2 (14) and (19) of the FSSK (39), through its third input, a non-linear masking sequence is supplied from the first GNMP output (46).

In C2 (13) and (18), nonlinear orthogonal code sequences are modulated by a stream of binary symbols arriving at the first and second inputs of the FSSK (39) from VK (36), respectively, and in C2 (14) and (19), nonlinear masking is added sequences with modulated nonlinear orthogonal sequences.

Information from the output of C2 (14) through CgF (15) goes to the first input of the FM (16), and the output of C2 (19) through CgF (20) goes to the first input of the FM (21). The second inputs of the FM (16) and (21) through the sixth and seventh inputs of the FSSK (39) from the first and second outputs of the LFO (43) are respectively supplied with the quadrature (cosine (7) and sine (Q)) components of the carrier frequency. From the output of the FM (16), the information goes to the first input of the Sum (17), and from the output of the FM (21) to the second input of the Sum (17), which provides linear addition of quadrature components. Information from the output of Sum (17) through the PF (33), which is the output of the FSSK (39), is fed to the first input of the SCS (42).

In the rest (LF) IR, a similar transformation of information occurs.

Call channel operation. Consider the work of the first KB (k = 1). The first PI input of the first call channel (KB (k, k = 1)) receives information about the subscriber's address, and the second receives information from which the call signal is generated. The information received at the 1 and 2 inputs of the KB PI is a stream of binary characters. The stream of binary symbols arriving at the second input of the PI KB, the separator (22) is converted into two streams to create in-phase I and quadrature Q components (conditionally, even symbols follow in one stream and odd ones in the other). From the first output of the splitter (22), the first stream goes to the input of the encoder (28), and from the second output of the splitter (22) the second stream goes to the input of the encoder (23). The streams of binary symbols in encoders (23) and (28) are encoded with redundant code in order to provide the possibility of error correction at the receiving side.

From the output of the encoder (23), the information enters the input of the interleaver (24), and from the output of the encoder (28) - to the input of the interleaver (29). In interleavers (24) and (29), the encoded information is “mixed” in such a way as to exclude the possibility of grouping errors on the receiving side. From the output of the interleaver (24), the information enters the first input of the adder modulo two (25), and from the output of the interleaver (29) - to the first input of the adder modulo two (30). The stream of binary characters containing information about the address of the called subscriber, from the first input of the PI KB is fed to the input GCA (26), which generates the address of the called subscriber and sends it to the input of the decimator (27). Information from the output of the decimator (27) enters the second inputs of the adders modulo two (25) and (30). In adders modulo two (25) and (30) in the information flows arriving at their first inputs, with the help of decimator (27) information about the subscriber’s address coming from the GCA (26) is “mixed”. From the output of the adder modulo two (25), an information stream containing already a sign of the subscriber address is fed to the first output of the PI KB, and from the output of the adder modulo two (30) to the second output of the PI KV. The stream of binary symbols from the first and second outputs of the PI of the first KB is supplied respectively to the first and second inputs of the VK (37) of the first KB, and the information from the first and second outputs of the VK (37) of the first KB is supplied respectively to the first and second inputs of the FSSK (40) of the first KB, and information from the output of the FSSK (40) of the first KB is fed to the (N + 1) -th input of the SCS (42). The information processing in VK (37) of the first KB and in FSSK (40) of the first KB is similar to the process considered in VK (36) and FSSK (39) of the first IR, except that the fourth input of FSSK (40) of the first KB is connected to The (N + 1) -th output of the GNOC (47), and the fifth input of the FSSK (40) of the first KB is connected to the (LN) -th output of the GNOC (47).

In the remaining call channels, a similar conversion of information occurs.

The operation of the synchronization channel. Consider the work of the last CS (j = J). The input of the synchronization channel PI (CS (j, j = J)) receives service information, which is a stream of binary symbols. This information from the input of the channel enters the input of the encoder (31), in which it is redundantly encoded in order to provide the possibility of correcting errors on the receiving side.

From the output of the encoder (31), the information is fed to the input of the symbol follower (32), which ensures that the value of the binary symbol stream velocity at the output of the PI KS is increased to the bit rate of the binary symbols at the output of the PI IR and PI KV. From the output of the symbol follower (32), the stream of binary symbols goes to the output of the PI KS, and from the output of the PI KS it is fed simultaneously to the first and second inputs of the VK (38) J-th CS, and the information from the first and second output of the VK (38) J- of the FSSK (41) of the J-th CS, respectively, is fed to the first and second inputs of the FSSK (41) of the J-th CS, and the information from the output of the FSSK (41) of the J-th CS is fed to the (N + K + J) -th input of the SCS (42).

The information processing process in VK (38) and FSSK (41) of the J-th COP is similar to the process considered in VK (36) and FSSK (39) of the first IR, except that the fourth input of FSSK (41) of the Jth The CS is connected to the Lth output of the GNOC (47), and the fifth input of the FSSK (40) of the Jth CS is connected to the first output of the GNOC (47).

In the remaining synchronization channels, a similar transformation of information occurs.

The signals from the outputs of all FSSK are linearly added to the SCS (42), from the output of which the signal is fed to a power amplifier (not shown).

A comparative assessment of the structural secrecy of the signals in the inventive device and prototype. The structural secrecy of signals is usually evaluated either by the size of the ensemble of signals of a given duration, or by the time required to reveal their structure. Given that the temporal characteristic of assessing the structural secrecy of signals is ambiguous, since, on the one hand, it depends on the technical capabilities of the diagnostic equipment at the time of the assessment, and on the other hand, on the size and ensemble of the evaluated signals, a comparative assessment of the structural secrecy of the signals used in the inventive device and prototype, we will carry out by comparing the size of the ensemble of signals used by them.

When assessing the structural secrecy of the prototype, we will proceed from the following facts:

1. The prototype device uses only one pair of synchronization codes implemented on the basis of a linear code sequence. Squaring the received signal into a square on the receiving side allows you to:

eliminate transmitted orthogonal sequences of synchronization codes in the received signal;

get a new code sequence belonging to the ensemble of synchronization codes transmitted by the transmitter, and the power of this code sequence is equal to the sum of the powers per each group channel.

2. To reveal the structure of any linear code sequence of length M = 2 ^{m, it is} sufficient to correctly determine 2m elements of this sequence, where m is the bit depth of the register.

3. The phase spectrum of the sequence of orthogonal codes in all channels except the pilot channel will be inverted under the influence of the transmitted information, and the phase spectrum of the pilot signal will be constant due to the lack of modulation. This makes it possible to extract the orthogonal code sequence of the pilot signal, and then determine the entire ensemble of orthogonal codes.

4. In each channel there is only one orthogonal code sequence from the ensemble of linear sequences A generated by the orthogonal code generator.

In view of the above, the number of operations for revealing the structure of the synchronization code with the bit width of the register of the generator of synchronization codes m = 7 and the size of the ensemble of linear code sequences A = 18 (with m = 7, the maximum size of the ensemble of linear sequences is 18 [4, p.30]) will make

A2m = 18 _* 2 _* 7 = 252,

and to reveal the structure of orthogonal codes with a bit width of the register of the generator of orthogonal codes m = 7 and the size of the ensemble of linear code sequences A = 18, it will be A2m = 18 _* 2 _* 7 = 252 operations.

Then, the total number of operations for revealing the structure of the signals used in the prototype device will be equal to the sum of operations necessary for revealing the sequence structure of the synchronization code and for revealing the sequence structure of orthogonal codes, and will be 504 operations.

When assessing the structural secrecy of the claimed device, we will proceed from the following facts:

1. Squaring the received signal into a square on the receiving side will eliminate the non-linear masking sequence and highlight the entire ensemble of non-linear orthogonal codes. Considering that in the claimed device all channels are equal, the transmitter power is distributed evenly across all channels (orthogonal codes), all channels contain information modulation of orthogonal non-linear code sequences, to uniquely identify any code sequence (for low power attributable to each of them ) is possible only through selection (by brute force method), which requires significant time costs.

2. Each channel contains two non-linear orthogonal code sequences from an ensemble of non-linear sequences A generated by a non-linear orthogonal code generator.

3. To reveal the structure of any nonlinear code sequence of length M = 2 ^m, it is necessary to determine all 2 ^m elements of this sequence, where m is the bit depth of the register.

4. The size of the ensemble of nonlinear code sequences A depends on the bit depth of the register m and is determined by the expression [4, p.29]

$$A=2^{2^{2m-\mathrm{one}}-m}.$$

In view of the above, the number of operations for revealing the structure of two non-linear sequences of the orthogonal code of one channel with a bit width of the register of the generator of non-linear orthogonal codes m = 7 and the size of the ensemble of each non-linear code sequence in the channel A = 2 ⁵⁷ (for m = 7 the maximum size of the ensemble of non-linear sequences is 2 ⁵⁷ [4, p.30]) will be A _{1 *} A _{2 *} 2 ^m = 2 ⁵⁷ * 2 ^{57 *} 2 ⁷ = 2 ¹²¹ .

When assessing the number of operations for revealing the structure of a nonlinear masking sequence, it should be borne in mind that it must first be distinguished in some way and that in each quadrature channel its length exceeds the length of the nonlinear orthogonal code sequence by 2 ⁱ times, where i = 1, 2 , 3, ....

Let i = 3. In this case, the number of operations for revealing the structure of a nonlinear masking sequence as compared to the number of operations necessary for revealing the structure of two nonlinear sequences of the orthogonal code will additionally increase 2 ⁱ times (in our case, 8 times)

Comparing the numerical values of the required operations to disclose the signal structure of the prototype and the claimed device, we can make an unambiguous conclusion that the task of disclosing the signal structure of the claimed transmitter is very problematic.

Methods of creation and technical implementation options for the generator of orthogonal nonlinear code sequences (40) and the generator of nonlinear masking sequences (41) are presented in [4, 5].

Information sources

1. New standards for broadband radio communications based on W-CDMA technology. M .: International Center for Scientific and Technical Information, 1999, (pp. 38-58).

2. Vijay K. Garg. IS-95 CDMA and cdma2000 Cellular / PCS Systems Implementation. Pretice Hall, PTR, 2000.

3. Patent for the invention No. 2287904, priority of the invention 04.02.2005, published: 20.11.2006, Bull. No. 32 (prototype).

4. Interference immunity of radio systems with complex signals / Ed. G.I. Tuzova. - M .: Radio and communications, 1985 .-- 264 p.

5. Beltyukov V.V., Sivov V.A. Orthogonal signals based on full code rings and their correlation properties. - Radio engineering and electronics, 1982, v. 27, No. 9, p. 1733-1738.

Claims (1)

A code-division transmitter with high structural secrecy of the transmitted signals, which includes N information channels, each of which includes a first encoder, a first interleaver, a first adder modulo two and a first symbol multiplexer, the output of which is the first output of the information channel, serially connected splitter, second encoder, second interleaver, second adder modulo two and a second symbol compactor, the output of which is the second output information channel, series-connected address code generator, first decimator, second decimator, the output of which is connected to the second inputs of the first and second symbol compressors, the output of the first decimator is connected to the second inputs of the first and second adders modulo two, and the input of the address code generator is the first input information channel, the input of the separator is the second input of the information channel, and the third inputs of the first and second symbol compressors are combined and are the third input ohm of the information channel, the second output of the splitter is connected to the input of the first encoder, K call channels, each of which includes the first encoder, the first interleaver and the first adder modulo two, the output of which is the first output of the call channel, the splitter, the second encoder connected in series, the second interleaver and the second adder modulo two, the output of which is the second output of the call channel, series-connected address code generator and decimator, the output of which is connected to the second the input inputs of the first and second adders are modulo two, and the input of the address code generator is the first input of the call channel, and the input of the splitter is the second input of the call channel, the second output of the splitter is connected to the input of the first encoder, J synchronization channels, each of which includes a serial encoder and a symbol follower, wherein the encoder input is the input of the synchronization channel, and the output of the symbol follower is the output of the synchronization channel, as well as a clock generator, a carrier frequency generator, and a channel adder channels, characterized in that the total number of transmitter channels is L, where L = N + K + J, in the circuit of each ℓ-th channel, where ℓ takes values from ℓ to L, an internal encoder is added, which includes the first and the second encoders, the first input of the first encoder being the first input of the internal encoder, and the first input of the second encoder the second input of the internal encoder, the second inputs of the first and second encoders are combined and are the third input of the internal encoder, the third inputs of the first and second encoders are combined and are the fourth input house of the internal encoder, the fourth inputs of the first and second encoders are combined and are the fifth input of the internal encoder, a channel signal spectrum shaper that includes the first adder modulo two in series, the second adder modulo two, a smoothing filter, the first phase modulator, adder and bandpass filter , the output of which is the output of the channel signal spectrum shaper, as well as the third adder modulo two, the fourth adder modulo two, the second smoothing filter in series and a second phase modulator, the output of which is connected to the second input of the adder, the first input of the first adder modulo two is the first input of the channel signal spectrum former, the first input of the third adder modulo two is the second input of the channel signal spectrum former, the second inputs of the second and fourth adders modulo two are combined and are the third input of the channel signal spectrum former, the second input of the first adder modulo two is the fourth input of the channel signal spectrum former, the second the input of the third adder modulo two - by the fifth input of the channel signal spectrum former, the second input of the first phase modulator - the sixth input of the channel signal spectrum former, and the second input of the second phase modulator - by the seventh input of the channel signal spectrum former, and a frequency divider is additionally introduced into the transmitter circuit, the input of which is connected to the output of a clock generator, a generator of a nonlinear masking sequence, the input of which is connected to the output of a clock generator, a nonlinear orthogonal generator codes, the first input of which is connected to the output of the clock generator, while the output of the ℓ-th channel signal spectrum shaper is connected to the ℓth input of the channel signal adder, the first output of the k-th information channel is connected to the first input of the nth internal encoder, and the second output of the k-th information channel - with the second input of the j-th internal encoder, where n takes values from ℓ to N, the first output of the j-th call channel is connected to the first input of the k-th internal encoder, and the second output of the k-th channel call - with the second input of the k-th internal encoder, de k takes values from N + 1 to N + K, the output of the j-th synchronization channel is connected to the first and second inputs of the j-th internal encoder, where j takes values from N + K + 1 to N + K + J, the first output ℓ-th internal encoder is connected to the first input of the ℓ-th channel signal shaper, and the second output of the внутреннего-th internal encoder is connected to the second input of the ℓ-channel channel shaper, the third inputs of all channel signal shapers are combined and connected to the first output generator of non-linear masking sequence, from which under a nonlinear masking sequence is obtained, the fourth input of the ℓ-th channel signal spectrum generator is connected to the ℓth output of the nonlinear orthogonal code generator, the fifth input of the гоth channel signal spectrum former is connected to the (L-ℓ + 1) -th output of the non-linear orthogonal code generator , the sixth inputs of all channel signal spectrum formers are combined and connected to the first output of the carrier frequency generator, the seventh inputs of all channel signal spectrum formers are combined and connected to the second output of the carrier generator On the other hand, the third inputs of all internal encoders are combined and connected to the output of the frequency divider, the second output of the generator of a nonlinear masking sequence, from which clock pulses are supplied that perform cyclic synchronization, the pulse repetition rate being determined by the period of the nonlinear masking sequence, connected to the second input of the nonlinear orthogonal generator codes and with the combined fourth inputs of all internal encoders, the fifth inputs of all internal encoders are combined and connected s with the (L + 1) -th output of the non-linear orthogonal code generator, the output of the channel signal adder is the output of the device.