RU2530228C1 - Device for technical protection of transmitted information - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: transmitting part of a device for technical protection of transmitted information includes a delta codec or an analogue-to-digital converter (ADC) and a half adder, and the receiving part of the above device includes a half adder and a delta codec or a digital-to-analogue converter (DAC), there in-series introduced as to inputs-outputs is a data entry control panel and a control unit; the transmitting part additionally includes the first, the second and the third switches, a data set shaper, the second half adder, the first and the second sensors of pseudorandom numbers (PRN), and the receiving part additionally includes a delta codec, the first, the second and the third switches, a data set converter, the second half adder, and the first and the second PRN sensors.

EFFECT: increasing a protection degree of information against unauthorised access at its transmission via communication radio channels.

3 cl, 5 dwg

Description

The invention relates to communication systems, namely, to terminal devices of confidential communication, and is intended for use in confidential communication systems of state, corporate and financial structures to protect against interception of information transmitted through communication channels or entering false information into a communication channel.

A secret telephone communication device is known, comprising two Walsh transform units, two Walsh inverse transform units, an encoder, a handset, a telephone and a communication line [1, 2].

The disadvantage of this device is that it is designed only for work on a physical communication line and cannot be used to protect the transmitted information via radio channels.

The closest in technical essence to the proposed invention is a secret communication device described in [3].

This device contains an amplifier, an analog-to-digital converter (ADC), an adder modulo two, a code sequence generator, a digital-to-analog converter (DAC), an adder, a controlled key, a clock and a threshold block, and on the receiving side it contains a low-pass filter ( Low-pass filter), ADC, modulo two adder, code sequence generator, DAC, narrow-band filter and clock synchronizer.

The disadvantage of this device is the difficulty in its implementation and the lack of cryptographic stability of the transmitted information over the air.

The aim of the invention is to increase the degree of protection of information from unauthorized access during its transmission via radio channels.

This goal is achieved by the fact that in the device of technical protection of the transmitted information, containing in the transmitting part a delta codec or analog-to-digital converter (ADC) and an adder modulo two, and in the receiving part an adder modulo two and a delta decoder or digital-to-analog converter (DAC), a data set panel and a control unit are connected in series at the inputs and outputs, the first, second and third switches, an information packetizer, and a second adder modulo are additionally introduced in the transmitting part two, first and second pseudorandom number sensors (PSS), while the output of the delta codec is connected to the first input of the first switch, the output of which is connected to the input of the packetizer information, the output of which is connected to the first input of the first adder modulo two, the output of which is connected to the first input of the second switch, the output of which is connected to the input of the second adder modulo two, the output of which is connected to the first input of the third switch, the second input of which is connected to the output of the second switch, the first and second the outputs of the first PSC sensor are connected respectively to the second input of the first adder modulo two and to the second input of the second switch, the first and second outputs of the second PSC sensor are connected respectively to the second input of the second adder modulo two and to the third input of the third switch of the transmitting part, the output of which is the channel output of the device, the signal output of which is the output of the second PSC sensor, the input of the delta codec and the second input of the first switch are respectively the inputs of the speech signal device data, and in the receiving part, delta decodes, first, second and third switches, an information packet converter, a second adder modulo two, a first and second PSC sensors are additionally introduced, while the output of the third switch is connected to the first input of the second adder modulo two the output of which is connected to the first input of the second switch, the output of which is connected to the first input of the first adder modulo, the output of which is connected to the input of the information packet converter, the output of which is connected to the input of the first of the first switch, the first output of which is connected to the input of the delta decode, the first and second outputs of the first PSC sensor are connected respectively to the second input of the first adder modulo two and to the second input of the second switch, the first and second outputs of the second PSC sensor are connected respectively to the second input of the second modulo two adders and to the second input of the third switch, the first input of which is the channel input of the receiving part of the device, the signal input of which is the second input of the second adder mod two, the output of the delta decode and the second output of the first switch of the receiving part are respectively the outputs of the speech signal and the device data, the first, second, third, fourth, fifth and sixth control outputs of the control unit are connected to the control inputs of the third switch, first and second sensors, respectively PSCH transmitting part, the third switch, the first and second sensors PSCH receiving part of the device.

Comparative analysis with the prototype shows that the proposed device for the technical protection of the transmitted information is characterized by the presence of new units: a data set console and a control unit, in the transmitting part of the delta codec, three switches, an information packetizer, a second adder modulo two and two PSC sensors, the receiving part of the delta decode, three switches, a packet information converter, a second adder modulo two and two PSC sensors, as well as a new set of blocks that were not detected di considered analogues and contributes to the solution of the problem is to increase the protect information from unauthorized access during the transmission by radio communication, achieved through masking not only the information to be transmitted, but also the mode and frequency range, in which transmission is performed.

Thus, the claimed device for the technical protection of the transmitted information meets the criteria of the invention of "novelty." Comparison of the proposed solution with other technical solutions shows that the blocks newly introduced into the proposed device are realizable, well known to specialists in this field of technology and additional creativity, given the explanations below, for their reproduction is not required.

This solution is significantly different from the known solutions in the art. The claimed solution explicitly does not follow from the prior art and has an inventive step.

This allows us to conclude that the technical solution meets the criterion of "significant differences".

The inventive solution can be implemented using existing units and devices used in electro-radio engineering and computer engineering, and is industrially applicable.

In the drawings, Fig. 1 shows a structural electrical diagram of a device for technical protection of the transmitted information, Figs. 2 and 3 show structural diagrams of a first and a second PSS sensor of a transmitting part of a device, and Figs. 4 and 5 show structural electrical diagrams of a first and a second sensor, respectively PSCH receiving part of the device.

The device for technical protection of the transmitted information (Fig. 1) contains a transmitting part 1, consisting of a delta codec 2, a first switch 3, a shaper 4 of information packets, a first adder 5 modulo two, a second switch 6, a second adder 7 modulo two, the third the switch 8, the first sensor 9 of the PSC and the second sensor 10 of the PSC; the remote control 11 of the data set, the control unit 12, the receiving part 13, consisting of a delta decode 20, the first switch 19, the transformer 18 packets of information, the first adder 17 modulo two, the second switch 16, the second adder 15 modulo two, the third switch 14 , the first sensor 21 PSC and the second sensor 22 PSC.

The first PSC sensor 9 of the transmitting part 1 contains (FIG. 2) the first 23, second 24, third 25 and fourth 26 shift registers, the first eight-bit adder 27 modulo 256, the first byte converter 28, the second eight-bit adder 29 modulo 256, the second byte a converter 30, an eight-bit adder 31 modulo two and a third eight-bit adder 32 modulo 256.

The second MSC sensor 10 of the transmitting part 1 contains (Fig. 3) the first 33, the second 34 and the third 35 shift registers, the first eight-bit adder 36 modulo 256, the first byte converter 37, the second eight-bit adder 38 modulo 256, the second byte converter 39, an eight-bit adder 40 modulo two and a third eight-bit adder 41 modulo 256.

The first sensor 21 of the MSS of the receiving part 13 contains (Fig. 4) the first 42, second 43, third 44 and fourth 45 shift registers, the first eight-bit adder 46 modulo 256, the first byte converter 47, the second eight-bit adder 48 modulo 256, the second byte converter 49, an eight-bit adder 50 modulo two and a third eight-bit adder 51 modulo 256.

The second sensor 22 of the MSS of the receiving part 13 contains (Fig. 5) the first 52, the second 53 and the third 54 shift registers, the first eight-bit adder 55 modulo 256, the first byte converter 56, the second eight-bit adder 57 modulo 256, the second byte converter 58, an eight-bit adder 59 modulo two and a third eight-bit adder 60 modulo 256.

The output of the delta codec 2 is connected to the first input of the first switch 3 of the transmitting part 1, the output of which is connected to the input of the packetizer 4, the output of which is connected to the first input of the first adder 5 modulo two, the output of which is connected to the first input of the second switch 6, the output of which connected to the input of the second adder 7 modulo two, the output of which is connected to the first input of the third switch 8, the second input of which is connected to the output of the second switch 6.

The output of the first sensor 9 of the frequency converter is connected to the second input of the first adder 5 modulo two, the second output of the first sensor of the frequency converter is connected to the second input of the second switch 6, the output of the second sensor 10 of the frequency converter is connected to the second input of the second adder 7 modulo two, the second output of the second sensor 10 The frequency converter is connected to the third input of the third switch 8 of the transmitting part 1, the output of which is the channel output of the device, the signal output of which is the output of the second sensor 10 of the frequency converter, the input of the delta codec 2 and the second input of the first switch 3 are respectively of the speech signal and data input devices.

The output of the third switch 14 of the receiving part 13 is connected to the first input of the second adder 15 modulo two, the output of which is connected to the first input of the second switch 16, the output of which is connected to the first input of the first adder 17 modulo two, the output of which is connected to the input of the packetizer 18, the output of which is connected to the input of the first switch 19, the first output of which is connected to the input of the delta decode 20. The first and second outputs of the first PSC sensor 21 are connected respectively to the second input of the first adder 17 modulo two and a second input of the second switch. Moreover, the input of the third switch 14 and the second input of the second adder 15 modulo two are channel and signal inputs of the receiving part 13 of the device, and the output of the delta decode 20 and the second output of the first switch 19 are respectively the outputs of the speech signal and data of the receiving part 13 of the device.

The input-output of the remote control 11 of the data set is connected to the input-output of the control unit 12, the first, second, third, fourth, fifth and sixth control outputs of which are connected to the control inputs of the third switch 8, the first 9 and second 10 sensors of the frequency converter of the transmitting part 1, the third switch 14, the first 21 and second 22 sensors PSC receiving part 13 of the device.

The output of the second shift register 24 of the first PSC sensor 9 of the transmitting part 1 is connected to its input and to the input of the first eight-bit adder 27 modulo 256, the output of which is connected to the input of the first byte converter 28, the output of which is connected to the input of the second eight-bit adder 29 modulo 256, the output of which is connected to the input of the second byte converter 30, the output of which is connected to the input of the eight-bit adder 31 modulo two, the output of which is connected to the input of the eighth bit of the first shift register 23, the first bit of which is connected to the control input of the eight-bit adder 31 modulo two, the outputs of the second and eighth bits of the first shift register 23 are connected respectively to the first and second inputs of the third eight-bit adder 32 modulo 256, the output of which is connected to the control input of the first eight-bit adder 27 modulo 256.

The output of the third shift register 25 through the fourth shift register 26 is connected to the second bit of the first shift register 23, the output of the sixth bit of which is connected to the control input of the second eight-bit adder 29 modulo 256, and the input of the third shift register 25 of the first sensor 9 PSC is the boot input of the initial information the first sensor 9, the ring input of which is the input of the third category of the fourth shift register 26.

The output of the third shift register 35 of the second PSC sensor 10 of the transmitting part 1 is connected to its input and to the input of the first eight-bit adder 36 modulo 256, the output of which is connected to the input of the first byte converter 37, the output of which is connected to the input of the second eight-bit adder 38 modulo 256, the output of which is connected to the input of the second byte converter 39, the output of which is connected to the input of the eight-bit adder 40 modulo two, the output of which is connected to the input of the eighth bit of the second register shift and 34, the output of the first discharge of which is connected to the control input of an eight-bit adder 40 modulo two. The outputs of the second and eighth bits of the second shift register 34 are connected respectively to the first and second inputs of the third eight-bit adder 41 modulo 256, the output of which is connected to the control input of the first eight-bit adder 36 modulo 256, the input-output of the first shift register 33 is connected to the input-output the second bit of the second shift register 34, the output of the sixth bit of which is connected to the control input of the second eight-bit adder 38 modulo 256, and the input of the first shift register 33 is boot input information of the second sensor 10 of the transmitting part 1, the calling input of which is the control input of the first shift register 33.

The output of the second shift register 43 of the first sensor 21 of the MSS of the receiving part 13 is connected to its input and to the input of the first eight-bit adder 46 modulo 256, the output of which is connected to the input of the first byte converter 47, the output of which is connected to the input of the second eight-bit adder 48 modulo 256, the output of which is connected to the input of the second byte converter 49, the output of which is connected to the input of the eight-bit adder 50 modulo two, the output of which is connected to the input of the eighth bit of the first shift register 42 the output of the first discharge of which is connected to the control input of an eight-bit adder 50 modulo two.

The outputs of the second and eighth bits of the first shift register 42 are connected respectively to the first and second inputs of the third eight-bit adder 51 modulo 256, the output of which is connected to the control input of the first eight-bit adder 46 modulo 256, the output of the third shift register 44 through the fourth shift register 45 is connected to the second bit of the first shift register 42, the output of the sixth bit of which is connected to the control input of the second eight-bit adder 48 modulo 256, and the input of the third shift register 44 is boot input source information of the first sensor 21 of the receiving part 13, the ring input of which is the input of the third category of the fourth shift register 45.

The output of the third shift register 54 of the second sensor 22 of the MSS of the receiving part 13 is connected to its input and to the input of the first eight-bit adder 55 modulo 256, the output of which is connected to the input of the first byte converter 56, the output of which is connected to the input of the second eight-bit adder 57 modulo 256, the output of which is connected to the input of the second byte converter 58, the output of which is connected to the input of the eight-bit adder 59 modulo two, the output of which is connected to the input of the eighth bit of the second shift register 53, the output of the first bit of which is connected to the control input of the eight-bit adder 59 modulo two, the outputs of the second and eighth bits of the second shift register 53 are connected respectively to the first and second inputs of the third eight-bit adder 60 modulo 256, the output of which is connected to the control input of the first eight-bit adder 55 modulo 256, the input-output of the first shift register 52 is connected to the input-output of the second bit of the second shift register 53, the output of the sixth bit of which is connected to the control input in the eight-bit adder 57 modulo 256, and the input of the first shift register 52 of the second PSC sensor 22 is the boot input of the initial information of the second PSC sensor 22 of the receiving part 13, the ring input of which is the control input of the first shift register 52.

The first 9 and second 10 PSCH sensors of the transmitting part 1 of the technical protection device of the transmitted information are designed to generate pseudorandom sequences (PSP) according to a certain algorithm used to overlay information transmitted through the communication channel in order to hide its true content. A similar purpose are the first 21 and second 22 sensors PSC frequency receiving part 13 of the device.

The first shift register 23 of the first PSC sensor 9 of the transmitting part 1 includes eight eight-bit binary cells and is intended to record eight bytes (64 bits) of the source information. The second shift register 34 of the second PSC sensor 10 has a similar purpose.

The second shift register 24 of the first PSC sensor 9 includes thirty-two eight-bit binary cells and is designed to record thirty-two bytes (256 bits) generated from sixteen bytes (128 bits) of the algorithm key.

The third shift register 25 of the first sensor 8 PSC includes three eight-bit binary cells with non-volatile memory and is designed to record three bytes (24 bits) of source information.

The fourth shift register 26 of the first sensor 8 PSC includes three eight-bit binary cells and is designed to record three bytes (24 bits) of information.

The first shift register 33 of the second sensor 10 PSC has one twelve-digit binary cell and is designed to record three bytes (24 bits) of information.

The second shift register 34 of the second PSC sensor 10 includes eight eight-bit binary cells and is intended to record eight bytes (64 bits) of the source information.

The third shift register 35 of the second PSC sensor 10 includes thirty-two eight-bit binary cells and is designed to record thirty-two bytes (256 bits) of information generated from sixteen bytes (128 bits) of the algorithm key for the second PSC sensor 10.

For the operation of the first sensor 8 of the MSS of the transmitting part 1, a time stamp of three bytes (24 bits) is supplied to its input, which is converted to the original information for the first shift register 23, eight bytes (64 bits).

For the second sensor 10 of the transmitting part to operate, a time stamp of twelve bits is supplied to its input, which is converted to the original information for the second register 34, with a volume of eight bytes (64 bits).

The first 8 and second 10 PSC sensors are algorithmically not connected with each other and operate independently. In this case, the first PSC sensor is intended for technical masking of the transmitted information, and the second PSC sensor 10 is designed to select the operating mode of the radio station and for additional masking of the transmitted information.

The device of technical protection of the transmitted information provides the making and receiving of a call, establishing a connection and works as follows.

After the operator selects the appropriate operating mode by installing on the remote control 11 a data set of the corresponding channel on the radio station or turning on the power, the following occurs.

The operation of the device is based on protection by masking information transmitted via digital communication channels formed by VHF radio stations. In this case, the analogue speech signal from the user terminal is fed to the input of the delta codec or analog-to-digital converter (ADC), from the output of which the digitized information signal through the first input of the first switch is fed to the input of the information packetizer, in which the digitized information signal is converted into blocks of information packets. From the output of the information packet generator 4, the information packet blocks arrive at the first input of the first adder 5 modulo two, where they are bit-wise summed modulo two with a pseudorandom sequence (PSP) continuously generated by the first 9 PSP sensor of the transmitting part of the technical protection device in accordance with the adopted algorithm his works. The mixed masked information received at the output of the first adder 5 modulo two is fed through the second switch 6 to the first input of the second adder 7 modulo two, the pseudorandom sequence arriving at the second input of the output of the second 10 PSC sensor. In the second adder 7, the mixed masked information is bitwise modulo-two summed up with the SRP generated by the second 10 PSH sensor, and as a result, the output of the second adder 7 modulo two produces double-masked information, which, through the third switch 8, enters the communication channel through the radio modulator.

Thus, at the output of the second adder 7 modulo two, a binary encoded signal is generated in the form of a sum modulo two of the original speech signal and a code sequence in the form of a block PSCH.

On the receiving side, the combined signal transmitted through the communication channel is fed to the input of the third switch 14 of the receiving part. From the output of the third switch 14, the signal is supplied to the first input of the second adder 15 modulo two, to the second input of which a signal is supplied in the form of SRP from the output of the second 22 RPS sensor. In the second adder 15 modulo two, the first pickup occurs from the masked source signal superimposed on it in the transmitting part of the SRP by the second sensor 10. From the output of the second adder 15 modulo two, masked information through the second switch 16 is fed to the first input of the first adder 17 modulo two, to the second input of which, from the output of the first 21 PSC sensors, a signal is supplied in the form of a CAP. In the first adder 17, the second removal from the masked source signal of the SRP superimposed on it in the transmitting part by the first 9 PSH sensor occurs and the block of information packets of the original speech signal is restored. From the output of the first adder 17 modulo two restored block of information packets is fed to the input of the Converter 18 information packets, in which the block is converted information packets into a digitized speech signal. Next, the digitized speech signal from the output of the converter 18 of the information packet through the first output of the first switch 19 is fed to the input of the delta decode 20 (or digital-to-analog converter), in which the digitized speech signal is converted into an analog speech signal, which is then fed to the user terminal.

Data is transmitted and received in the device in a similar way, except that the data goes directly to the first switch 3 (during transmission) and the first switch 19 (during reception), bypassing the steps of signal conversion by delta codec 2 and delta decode 20.

To ensure the synchronous operation of the first PSC sensors of the transmitting part of the transmitting radio station and the receiving part of the receiving radio station, the state of the fourth register of the PSC sensor of the transmitting radio station increases by one at certain intervals and is transmitted to the communication channel as part of the sync package. When the tangents are released at the transmitting radio station, the state of the fourth register is stored in the memory of the third register, which has a non-volatile memory.

To set the initial value of the third shift register (n bits), the numerical axis of 2 ⁿ bits is divided into 2 ^m intervals of 2 ^k values (n = m + k). The number of each of 2 ^m intervals can be used as an individual address of a radio station when it is operating in a radio network. The number of subscribers in the radio network is not more than 2 ^m .

When the radio station reaches the boundary of the allotted interval in the fourth shift register (third shift register), its operation is blocked, after which it must be assigned a new individual address.

The second shift register is used to record the working key of the algorithm, which is the same for all radio stations in the network.

The algorithm of work is as follows.

When transmitting from non-volatile memory, sixteen bytes (128 bits) of the original key and a checksum designed to verify the accuracy of the reading are loaded (taken into account).

If the calculated checksum does not coincide with the read information or all downloaded sixteen bytes of the key are 0 (or 1), the device is blocked. In this case, a warning signal is generated for the operator.

In order to continue working on the selected channel, you must turn off the power and turn it on again. After the appearance of a similar effect when you turn it on again, operation on this channel should be prohibited.

If the calculated checksum matches the read one and the loaded sixteen bytes of the source key are not equal to 0 (or 1), then the second shift register 24 of the first 9 PSC sensor of transmitting part 1 is filled from the source key, and the third register 35 of the second sensor 10 is also filled from the source key PSH.

The value of the third shift register 25 is overwritten in the fourth shift register 26. The value of the first shift register 23 is generated from the fourth register 26 in accordance with the adopted algorithm. After that, the value of the third shift register 25 is increased by one and the operation of the first 9 PSC sensors is suspended until the transition to the information transfer mode.

Then the registers of the second sensor 10 PSC begin to work. In this case, the value of the first shift register 33 is formed based on the bits of the individual number of the radio station, which includes the technical protection device of the transmitted information. The value of the second shift register 34 is generated from the value of the first shift register 33 according to the adopted algorithm. In this case, the second 10 PSN sensor after thirty-two cycles produces eight-byte PSNs, and each received PSN serves as the basis for receiving the next PSN and this happens continuously until the radio station enters the synchronous frequency mode.

To organize a frequency-synchronized operation mode, the radio operator sets the address (number) of the called subscriber or a circular call from the keypad and presses the circular / address call button or presses the tangent of the intercom. After this, the process of mutual synchronization of the second PSC sensors of the transmitting (calling) radio station and the radio station in standby mode begins, the address of which coincides with the address of the called subscriber (in case of an address call) or all radio stations of the radio network in standby mode (in a circular call) .

After pressing the circular / address call button, the third switch 8 of the transmitting part 1 switches to the third contact, the lower twelve bits of information are read from the second shift register 34 of the second 10 PSN sensors and written to the first shift register 33. In the first shift register 33, the incoming twelve bits are encoded by the Reed-Mahler code (31, 6) and codewords are generated. The resulting codewords (31, 6) form the first service codeogram (CK1), which is transmitted in a ringing cycle.

After the end of the ringing cycle, the transmitting radio station, together with the device, goes into synchronous frequency mode and operates in accordance with the time diagram. At the same time, the operator's reception indicator goes off and the communication indicator lights up.

The time diagram includes a call cycle and several information cycles of a certain duration, for example 5.28 s. At the same time, the information cycle includes a service group interval (SGI), a service pause (SP) of 10 ms duration, as well as several information intervals of the same duration (10 ms each). During the information interval, frequency tuning and transmission of the information packet occurs.

After the end of the ringing cycle, the radio station transmits in accordance with the time diagram, starting with the information signal cycle, with:

at the service pauses of the information cycle, clock and cycle synchronization signals are transmitted;

the third switch 8 switches to the third contact;

the lower twelve bits of the second shift register 34 of the second PSC sensor 10 are recorded in the first shift register 33;

twelve bits of the first shift register 33 of the second MSC sensor 10 are encoded by the Reed-Mahler code (31, 6). The resulting codewords (31, 6) form SK1, which is transmitted on the GIS interval;

the value of the second shift register 34 is erased and a new value of the second shift register 34 is generated from the first shift register 33;

the third switch 8 switches to the second contact at the information intervals and to the third contact at the intervals SP and SGI;

every 5.28 s the radio operates in synchronous mode.

If the synchronous frequency mode of operation is not established, that is, during operation, a response code is not received or during operation, a confirmation from the subscriber from the receiving side is not received, then the calling subscriber must again switch to standby mode and retry the call.

The synchronous frequency mode of operation is the “standby” state of the device from which it can transmit (by pressing the tangent by the radio operator) or receive (after pressing the tangent by another subscriber on the receiving side).

In the “standby” state of reception, the radio station can stay for approximately 30 minutes (the time is controlled by the built-in timer from the moment of the end of the last personal operation for transmission or from the moment of the end of the last reception of information from another radio station), after which the radio switches to standby mode.

If the called radio at the time of transmission of SK1 described above is turned on and is in standby mode, then the following occurs.

If the codegram CK1 is received and both Reed-Mahler codewords are correctly decoded (31, 6), then the twelve bits received are written into the first shift register 33 of the second PSC frequency sensor 10 (in this case, the reception indicator goes off and the communication indicator lights up). The value of the second shift register 34 is generated from the value of the first shift register 33. After filling in the second shift register 34, the second MSS sensor of the called radio station starts to work in synchronization with the second MSS sensor of the called radio station in information cycles.

The second PSC sensor 22, after thirty-two cycles, produces an eight-byte PSC. Each received PSC serves as the basis for the next PSC.

Every 5.28 s, on the GIS interval, the operation of the second PSH sensor 22 of the receiving radio station corresponds to the operation of the second PSH sensor 10 of the transmitting radio station. At the same time, in the second PSC sensors, the lower twelve bits of the second shift register (34 and 53) are recorded in the first shift register (33 and 52), the value of the second register (34 and 53) is deleted and a new value is formed from the first shift register (33 and 52) second register (34 and 53) shift.

In the set frequency-synchronous mode (in the “standby” state), it is possible to transmit masked speech (through the first input of the first switch 2 of the transmitting part 1) or data (through the second input of the first switch 2 of the transmitting part 1).

The transmission of service information for mutual synchronization of the first 9 PSCH sensor of the transmitting radio station and the first sensor 21 of the PSCH receiving radio station is as follows.

After pressing the tangents, the second switch (5 and 16) switches to the second contact. The third switch (8 and 14) switches to the first contact (in information intervals).

At the service pauses of the information cycle, clock and cycle synchronization signals are transmitted. In this case, the third switch (8 and 14) is disconnected from all contacts.

On the SGI interval, a service codogram (SK1) is transmitted, while the third switch (8 and 14) switches to the third contact.

The value of the third shift register (25 and 44) of the first (9 and 21) PSN sensor is overwritten in the fourth (26 and 45) shift register. Twenty-four bits of the fourth (26 and 45) shift register are encoded by the Reed-Mahler code (31, 6). The resulting four codewords (31, 6) form two service codeograms (CK2), the structure of the time diagram of which includes, for example, 192 bits, of which 16 bits comprise frequency tuning, 63 bits of the M-sequence, three words of 31 bits and 10 bits protection. The received codewords are transmitted to the receiving radio station in information intervals. In this case, the first two codewords of the first CK2 contain the lower twelve bits of the fourth register, and the first two words of the second CK2 contain the upper twelve bits of the fourth shift register.

The value of the first register is formed from the fourth register, the current value of the third register is increased by one.

The first MSS sensor after 32 cycles generates an eight-byte MSS for masking speech or data. Each received PSC serves as the basis for the next PSC.

After the tangent is released, the device and the radio station return to the “standby” state of the frequency-synchronous operation mode. At the same time, the operation of the first PSC sensors stops, synchronization signals are not transmitted in the service pauses. The second PSC sensor continues to operate.

After the next pressing of the tangent, the operation of the technical protection device of the transmitted information is repeated.

A radio station that is in the “standby” state of a frequency-synchronous mode constantly analyzes the presence of service codograms (CK2) described above in the incoming signal. By receiving both SK2:

the second switch 16 of the receiving part 13 of the device switches to the second contact, the third switch 14 switches to the first contact (in information cycles);

the radio decodes four Reed-Mahler codewords (31, 6) that correspond to 24 bits of the fourth transmit shift register 26 and these 24 bits are written to its fourth shift register 45;

the value of the first shift register 42 is formed from the value of the fourth register 45.

After filling in the first shift register 42 of the first sensor 21, the PSC of the receiving part 13 of the called radio station starts to work in synchronization with the first sensor 9 of the PSC of the transmitting part 1 of the calling radio.

The first sensor 21 PSCH receiving part 13 after 32 cycles produces an eight-byte PSCH to mask the speech or data. Each received PSC serves as the basis for the next PSC.

If there are no service pause signals at the receiving radio station for approximately 10 seconds, the operation of the first sensor 21 of the MSS of the receiving part 13 is suspended. The radio station enters the “standby” state of the synchronous frequency mode of operation. After receiving new SK2, it begins to work according to the algorithm described above.

If the receiving radio station accepts in CK2 a value of 24 bits belonging to the range of this radio station, then it gives the operator a warning signal and, if the subscriber receives meaningful information, the operation of the entire radio network should be stopped.

If the radio station was in standby mode at the time of transmission, then it only receives SK1 (and does not receive SK2) on the SGI interval. After receiving SK1, the radio goes into a synchronous frequency mode of operation.

If it is necessary to make an address call to a subscriber working in the network, a preliminary exit of the entire network to the standby reception mode is required, which is carried out by pressing the standby reception button on each terminal.

After mutual synchronization of the first 9 and second 10 sensors of the MSS of the transmitting radio station, the first 21 and second 22 sensors of the MSS of the receiving radio station, the calling subscriber transmits voice information through the device for technical protection of the transmitted information (first switch 2 of the transmitting part 1 is in the first position) or data (first switch 3 of the transmitting part 1 is in the second position). In doing so, the following occurs.

In the information intervals, the second switch switches to the first contact (first input), the third switch switches to the second contact. In the GIS interval, the third switch switches to the third contact for transmitting SK1 (at this time, the operation of the first and second PSC sensors is suspended), and in the GV interval, the third switch is disconnected from all contacts. At the same time, clock and loop synchronization signals are output to the communication channel, and the operation of the first and second PSC sensors is suspended.

For each 10 ms interval of the information interval, the first MSS sensor generates several MSS (3 or 4), of which 176 bits are used to mask the information of this subinterval, and the remaining bits to mask the next 10 ms subinterval.

The incoming information is bit-wise summed modulo two with the received PSC according to the time diagram above.

At each 10-ms interval of the information interval, the second MSS sensor generates three MSS (192 bits), of which 176 bits are used to additionally mask information coming from the first contact of the second switch. This information is the transmitted information masked by the first MSS sensor. 8 bits from the remaining 16 (192-176 = 16) determine the operating frequency number for operation on the next sub-interval 10 ms of the information interval (used only in the frequency hopping mode), the last 8 bits are used only on the last (fifteenth) sub-interval of 10 ms of the information interval for determining the frequency number at which the next SP will be transmitted.

The procedures described above continue as information becomes available.

In the receiving radio station, as a result of the sequential superposition of the second frequency converter of the second frequency converter and the first frequency sensor of the first frequency converter on the information sequence, the information is masked.

The technical efficiency of the proposed device for the technical protection of the transmitted information is to increase the degree of protection of information from unauthorized access during its transmission via radio channels.

An increase in the degree of protection is achieved through the implementation in the device of a combined method based on the principles of crushing information and mixing it over the frequency range of the transmitted signal. The use of this method allows you to create complete uncertainty regarding the position in time of each frequency segment, thereby increasing the degree of closure of the system.

The advantage of the proposed method and operation algorithm used in the device is the comparative simplicity of its technical implementation, as well as low cost and small dimensions, which allows the device to be implemented as separate boards that can be directly integrated into the radio station.

Prototypes of the proposed device for the technical protection of the transmitted information were made and tested. The test results of the samples confirmed the correctness of the technical solutions, their performance in all operating modes and the performance of the functions provided in accordance with the specified requirements.

Information sources

1. T.I. Ivanova. Subscriber terminals and computer telephony. M .: Eco-Trends, 1999, p.186-201.

2. RU, RF patent No. 2032991, class. H04K 1/02, H04K 1/04, 1995.

3. RU, RF patent No. 2038701, class. H04K 1/02, 1995 (prototype).

Claims (3)

1. The device of technical protection of the transmitted information, containing in the transmitting part a delta codec or analog-to-digital converter (ADC) and an adder modulo two, and in the receiving part an adder modulo two and delta decodes or a digital-to-analog converter (DAC), characterized by the fact that a data set panel and a control unit are connected in series at the inputs and outputs, the first, second and third switches, an information packetizer, a second adder modulo two, are first introduced in the transmitting part and a second pseudo-random number sensor (PSS), while the output of the delta codec is connected to the first input of the first switch, the output of which is connected to the input of the packetizer of information, the output of which is connected to the first input of the first adder modulo two, the output of which is connected to the first input of the second a switch whose output is connected to the input of the second adder modulo two, the output of which is connected to the first input of the third switch, the second input of which is connected to the output of the second switch, the first and second outputs of the first of the second MSS sensor are connected respectively to the second input of the first adder modulo two and to the second input of the second switch, the first and second outputs of the second MSS sensor are connected respectively to the second input of the second adder modulo two and to the third input of the third switch of the transmitting part, the output of which is channel the output of the device, the signal output of which is the output of the second PSC sensor, the input of the delta codec and the second input of the first switch are respectively the inputs of the speech signal and data equipment, and in the receiving part, delta decodes, first, second and third switches, an information packet converter, a second adder modulo two, a first and second PSC sensors are additionally introduced, while the output of the third switch is connected to the first input of the second adder modulo two, the output of which is connected to the first input of the second switch, the output of which is connected to the first input of the first adder modulo two, the output of which is connected to the input of the information packet converter, the output of which is connected to the input of the first a mutator, the first output of which is connected to the input of the delta decode, the first and second outputs of the first PSC sensor are connected respectively to the second input of the first adder modulo two and to the second input of the second switch, the first and second outputs of the second PSC sensor are connected respectively to the second input of the second adder modulo two and to the second input of the third switch, the first input of which is the channel input of the receiving part of the device, the signal input of which is the second input of the second adder modulo two, the output of the delta decode and the second output of the first switch of the receiving part are respectively the outputs of the speech signal and data of the device, the first, second, third, fourth, fifth and sixth control outputs of the control unit are connected to the control inputs of the third switch, the first and second sensors of the frequency converter of the transmitting part , the third switch, the first and second sensors PSCH receiving part of the device. 2. The device according to claim 1, characterized in that the first sensor for the transmitting and receiving parts contains the first, second, third and fourth shift registers, the first, second and third eight-bit adders modulo 256, an eight-bit adder modulo two, the first and second byte converters, while the output of the second shift register is connected to its input and to the input of the first eight-bit adder modulo 256, the output of which is connected to the input of the first byte converter, the output of which is connected to the input of the second eight modular 256 adder, the output of which is connected to the input of the second byte converter, the output of which is connected to the input of the eight-bit adder modulo two, the output of which is connected to the input of the eighth bit of the first shift register, the output of the first bit of which is connected to the control input of the eight-bit adder modulo two , the outputs of the second and eighth bits of the first shift register are connected respectively to the first and second inputs of the third eight-bit adder modulo 256, the output of which is sub is connected to the control input of the first eight-bit adder modulo 256, the output of the third shift register through the fourth shift register is connected to the second bit of the first shift register, the output of the sixth bit of which is connected to the control input of the second eight-bit adder modulo 256, and the input of the third shift register is the boot input the initial information of the first PSC sensor, the calling input of which is the input of the third category of the fourth shift register. 3. The device according to claim 1, characterized in that the second MSS sensor of the transmitting and receiving parts comprises first, second and third shift registers, first, second and third eight-bit adders modulo 256, an eight-bit adder modulo two, the first and second byte converters wherein the output of the third shift register is connected to its input and to the input of the first eight-bit adder modulo 256, the output of which is connected to the input of the first byte converter, the output of which is connected to the input of the second eight-bit modulator 256, the output of which is connected to the input of the second byte converter, the output of which is connected to the input of the eight-bit adder modulo two, the output of which is connected to the input of the eighth bit of the second shift register, the output of the first bit of which is connected to the control input of the eight-bit adder modulo two, the outputs of the second and eighth bits of the second shift register are connected respectively to the first and second inputs of the third eight-bit adder modulo 256, the output of which is connected to to the branching input of the first eight-bit adder modulo 256, the input-output of the first shift register is connected to the input-output of the second bit of the second shift register, the output of the sixth bit of which is connected to the control input of the second eight-bit adder modulo 256, and the input of the first shift register is the boot input of the original information of the second PSC sensor, the calling input of which is the control input of the first shift register.

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