RU2191481C2 - Device for automatic establishing secret telephone communications - Google Patents

Abstract

FIELD: telephone communications; transmission of secret messages over channel-switching telephone network. SUBSTANCE: device provides for synchronizing scrambling equipment before communication channel is allocated to subscribers. Device has telephone sets, scrambling pieces of equipment, exchange unit, generator unit, voice-signal switchboard, telephone circuit switchboard, and OR gate. EFFECT: reduced delay time before secret talk can be started. 6 dwg

Description

 The invention relates to techniques for telephone communications and can be used to transmit secret telephone messages over a switched circuit network.

 A known method for automatically establishing a connection between telephone network subscribers is based on the transmission of the communication request signal by the calling subscriber, receipt of the communication permission signal from the PBX, transmission of the number of the called subscriber by the calling subscriber, analysis of the telephone exchange of this number in order to determine the transmission route of the number to the telephone exchange the called subscriber, establishing a connection between the PBX of the calling and called subscribers, analyzing the status of the called subscriber on the PBX, if the called subscriber is idle - transfer the signal “Make a call” (PST), and the caller - a signal “Control a call” (CPV), the path of the transmission of information and the removal of signals CPV and PV when the called subscriber receives a PV signal (picking up his handset) [1, 2, 3, 4]. This common connection setup procedure is used to organize open (unclassified) negotiations.

 The disadvantage of the described method lies in the complexity of its use for organizing a secret telephone communication mode, which is associated with the need for PBX operators to conduct official negotiations on the establishment of this mode with subsequent manual connection of classified equipment on the called and calling sides.

 A known method of organizing classified communications, carried out by the subscribers themselves, implemented in [5]. In this way, when picking up the handset, a bypass path for secrecy equipment is created, and the telephone is connected directly to the telephone network. Subscribers establish a connection in the generally accepted manner described above, after which they negotiate in open form or using negotiation tables to establish a closed mode of operation. At the end of these negotiations, they press a special button. At the same time, secret equipment is included in the conversation path, this equipment is synchronized on both sides, after which secret negotiations become possible.

 The disadvantage of this method is the long time to establish a connection, as well as the need for official negotiations and manual operations.

 Closest to the proposed method and therefore selected as a prototype is a method for automatically establishing a connection for conducting secret telephone conversations, implemented in [6]. According to this method, as in the above methods [1-5], a connection is established between the telephone exchanges of the calling and called subscribers by the number of the called subscriber in a well-known way, the state of the called subscriber is analyzed, when it is idle, the PV signal is transmitted to the called subscriber, and the CPV signal is transmitted to the called subscriber, if the called subscriber receives the PV signal (picks up the telephone receiver), the communication channel is switched off, while the PV and CPV signals are removed, the privacy equipment is synchronized, a notification signal is sent to both subscribers suschestvlenii synchronization process (signal "Wait"), which is removed after the synchronization of encryption equipment. Removing the signal "Wait" is an invitation to conduct telephone conversations.

 The described method allows you to fully automate the procedure for establishing a connection and to exclude official (open) negotiations.

 The main disadvantage of this method is the large delay in starting negotiations. In fact, in a public telephone network, negotiation is possible immediately after the called party picks up the telephone receiver.

 In the described method, after picking up the handset, the called subscriber sends a “Wait” signal (tone, musical phrase ...) to the phones of both subscribers during the synchronization time of the secret equipment. The indicated time can be significant both because of a poor communication channel, and because of the need to transfer a large amount of sync data exchanged between privacy devices, which in turn is determined by high requirements for the cryptographic strength of information security.

 In addition, in the public telephone network, when the called subscriber picks up the handset, the subscribers receive CPV and PV signals (425 Hz tone frequency). In the prototype method, a “Wait” signal is issued to subscribers other than the CPV and PV signal. Changing the type of signals and their sequence in the known method introduces operational inconvenience, requires retraining of maintenance personnel, which are significant disadvantages.

 Another drawback is manifested in the organization of accounting for the time of negotiations. In an existing network, time counters are turned on when the called party picks up the handset.

 When using the prototype method, such inclusion of counters leads to unreasonable expenses for subscribers, since the latter are forced to pay for the synchronization time of the security equipment during which negotiations are impossible, and, in addition, in the case of failed synchronization of the security devices, payment is also made, although the exchange of information did not take place.

 The objective of the proposed method is to reduce the delay time to start conducting classified negotiations.

 The technical result achieved by the proposed method consists in synchronizing the security equipment until the communication channel is provided to the subscribers (until the called party picks up the handset), which further increases the accuracy of taking into account the duration of negotiations.

 An additional technical result is to maintain the generally accepted order of signals.

 The features of the proposed method, common with the prototype method, are the use of transmitting a call signal to the called subscriber, and a call control signal to the caller, as well as the operation of establishing a connection between the telephone exchanges of the calling and called subscribers by the number of the latter followed by state analysis of the called subscriber and when it is unoccupied, by notifying the caller about this, by disconnecting the communication channel between the PBX and synchronizing the privacy equipment through the disconnected communication channel zee.

 The features of the proposed method, which differ from the features of the prototype method, are the operation of transmitting the call signal to the called subscriber, and the call control signal after the synchronization operation of the security equipment and canceling these signals after the called call signal is received by the called subscriber and subsequent exchange with the caller of the signals "Remove the control call" (SKPV).

In FIG. 1 presents a functional diagram of a device that implements the method,
figure 2 is a timing diagram of the operation of the device,
figure 3 is a functional diagram of a channel selector,
figure 4 is a functional diagram of a digital analyzer,
figure 5 is a functional diagram of the apparatus of classification,
figure 6 is a functional diagram of the pairing unit.

A device that implements a method of establishing a connection contains the following blocks:
1 - telephone sets
2 - block subscriber kits,
3 - exchange unit,
4 - generator block,
5 - switch sound signals
6 - elements OR
7 - telephone circuit switch,
8 - security devices,
9 - information inputs and outputs of the device,
10 - control channel of the device,
11 - communication bus.

 Blocks 2-7 of the proposed device form a hub of channels (K1 and K2 in Fig. 2), and the entire device as a whole is an example of the implementation of the proposed method when working through a digital telephone exchange with information channels for transmitting speech signals and a control channel (D-channel) , which exchanges the interaction signals between the proposed device and the PBX in the process of establishing and destroying the connection.

 The device has the following connections. The outputs of the telephone sets 1 through the block of subscriber sets 2 are connected to the corresponding first inputs of the switch of the telephone circuits 7, the first outputs of which are connected through the elements of OR 6 to the inputs of the corresponding telephone sets 1, and the second inputs and outputs are connected to the first information outputs of the security devices 8, the second information inputs and outputs of which are the input-output 9 of the device.

 The control channel 10 of the device is connected to the main input-output of the exchange unit 3, connected by additional inputs and outputs to the additional outputs-inputs of the respective privacy devices 8, and by the communication bus 11 to the subscriber kit unit 2, the telephone circuit switch 7, the generator unit 4 and the switch 5 sound signals. In this case, the group of inputs of the switch 5 is connected to the group of outputs of the block of generators 4, and the outputs of the switch 5 are connected to the second inputs of the corresponding elements OR 6.

Block subscriber kits 2 contains the following nodes:
21 - subscription kits,
22 - switch subscriber kits,
23 - digit analyzer.

 Subscriber kit 21 is designed to supply power to telephone sets, register MTT is on and MTT is up (MTT is a handset), transmit a speech signal from a telephone to a telephone circuit switch, and transmit dialing pulses to a switch of 22 subscriber sets .

 An example of the implementation of the main nodes of the subscriber set is shown in Fig. 5 and 6 of the prototype [6]. In addition to these nodes, the MTT stacked and MTT lifted signal selectors are included in the subscriber kit. The functional diagram of one of these selectors is shown in FIG. 3 and contains the following nodes: trigger 211, delay element 212, key 213, and address selector 214.

 The switch 22 of the subscriber sets is designed to connect one of the M input channels (subscriber sets) to one of the N output channels (M> N) at the addresses of the incoming and outgoing channels. An example of the implementation of switch 22 is given in [1, p. 37, Fig. 3.6].

 Digit analyzer 23 is designed to highlight the digits of the dialed number and issue a binary code of this digit on the communication bus 11. Figure 4 shows the functional diagram of the digit analyzer, built on the basis of a device for receiving pulses of a decade-long dialing [7]. The composition and purpose of the nodes of the analyzer figures will be described in more detail later.

 Generator 4 is designed to generate and issue sound signals “Ready”, “Busy”, “Make a call”, “Control a call”, “Wait” with parameters according to GOST 7153-85 according to the codes of these signals received via bus 11. Implementation example generator 24 is given in [1, p. 74, fig. 4.12].

 The group of outputs of the generator 4 of the audio signals has the number of outputs L equal to the number of used audio signals.

 The audio signal switch 5 provides switching of the L incoming channels to M outgoing channels, and the telephone circuit switch 7 provides M incoming to N outgoing codes by the addresses of these channels coming via the communication bus 11. An example of the implementation of the switches is given in [1, p. 37, Fig. 3.6].

 The exchange unit 3 is designed to control the blocks of the proposed device, transmit and receive interaction signals between the blocks of the device and the exchange during the establishment and destruction of the connection.

 According to recommendation Q 921 [9], the signal exchange on the control channel (D-channel) is carried out by signal units (CE). In [1, p. 105-107, fig. 7.5], the CE exchange procedure, their structure and the structure of the signaling information transmitted as part of the CE are given. The exchange unit, according to the algorithm recorded in its memory, forms the CE structure and organizes their transmission and reception via control channels.

 An example of the implementation of an exchange unit based on the MP BIS KR 1810 VM 86 is given in [10, p. 243, Fig. 7.40]. The external devices of this example should be understood as two groups of devices, the first of which includes nearby peripheral devices: a subscriber set unit 2, an oscillator unit 4 and an audio signal switch 5, a telephone circuit switch 7, and the second - remote peripheral devices: security devices 8 and automatic telephone exchanges.

 The data highway (MD), the address highway (MA) and the control circuit of an example of an exchange unit form a communication bus 11 of the proposed device to which the near peripheral devices are connected. To connect remote peripheral devices to the communication bus, a signal converter has been introduced into the exchange unit 3, which transmits information from parallel to serial with encoding of binary elements into a bi-pulse signal, for example, at the interface C1-FL GOST 27232-87, and at the reception - tuning the clock frequency of reception to the boundaries of elementary signals, converting a bi-pulse signal to binary, registering binary elements and converting a serial code to parallel. The use of converters allows you to provide the required operating range, as well as reduce the number of exchange circuits and interfaces with PBXs and security devices. The outputs of the converters form the main control channel 10 for communication with the telephone exchange and additional control channels connecting the additional inputs and outputs of the exchange unit 3 and security devices 8.

 Secret devices 8 of the proposed device are intended for classifying information on the transmitting side and declassifying it on the receiving side, as well as for exchanging interaction signals with the device nodes via an additional control channel. Figure 5 presents the functional diagram of the apparatus of secrecy, containing the exchange unit 81, the pairing unit 82 and the secrecy unit 83, similar to the secrecy unit 2 of the prototype.

 The exchange unit 81 is similar to the exchange unit 3 and comprises an exchange controller 812 and a joint converter 811.

 The interface converter 811, under the control of the exchange controller 812, receives and transmits commands for interaction and conversion of the serial code at the interface C1-FL to parallel. The interaction signals from the exchange controller 812 enter the interface unit 82 via the exchange bus 84.

 The interface unit 82, under the control of the exchange controller, converts the commands received through the bus 84 into signals for controlling the operation modes of the privacy unit 83 and the inverse conversion of the signals issued by the privacy unit to commands.

 In FIG. 7 is a functional diagram of an interface unit 82, the operation of which will be described below.

 The establishment of the connection according to the proposed method and the operation of the device that implements it are illustrated by the time diagram shown in figure 2, in which TA1 and TA2 are telephone sets, K1 and K2 are channel switches, A1 and A2 are classified devices, ATS1 and ATS2 are digital automatic telephone exchanges of the calling and called subscribers, respectively.

 If you need to conduct telephone conversations, the caller (TA1) picks up the phone. The analyzer position of the tube in the subscriber kit 21 emits a signal "MTT raised", which is stored on the trigger 211 (figure 3). The exchange unit 3, according to the program recorded in its memory, polls the devices connected to the bus, issuing the addresses of these devices on it. The address selector 214 is activated and opens the key 213, connecting the trigger 211 to the communication bus 11. After polling the trigger 211, it is reset by the signal from the output of the delay element 212, and information about the picked up handset is transmitted by the exchange unit 3 as part of the CE via the control channel 10 to the exchange in the form of code of this signal and subscriber code. ATS1, when the station devices are idle, and also when there is a free secret device, issues a Ready signal code to the caller in the CE (if it is not possible to service the busy signal call code).

 Block 3 receives this signal and, via bus 11, issues codes of switched channels to switch 22, which connects the corresponding subscriber set 21 to one of the channels of the analyzer 23 account. After that, exchange block 3 sends 11 command code to generator block 4 to turn on the generator “Ready” signal, and to switch 5 - the output code of the generator block and the code of the telephone pair of the calling subscriber. The switch 5 connects the corresponding output of the block of generators 4 to this pair, the subscriber hears the tone "Ready" (figb) and dials the numbers of the called subscriber. The analyzer of the digit 23 from the signals arriving at its input generates a digit code and stores it (Fig.2c). The exchange unit 3 when polling the analyzer of the digit 23 takes the digit code and issues it to the PBX1. ATS1, having accepted the digit, issues a command code for the “Done” signal disconnection to the exchange unit 3, having received which the exchange unit 3 via the communication bus 11 issues the appropriate commands to the generator unit 4 and the audio switch 5, while the telephone stops ringing from the caller tone signal (Fig.2g). Similarly transmitted to the PBX and the remaining digits of the dialed number (fig.2d-2e). After dialing the last digit of the number (the number of digits of the number can be determined both in the processor of the exchange unit and in the exchange). ATS1 of the calling subscriber analyzes this number in order to develop a connection route and transmits a corresponding signaling message indicating the number of the called and called subscribers through inter-office communication channels, for example, via a common signaling channel [1, p. 107] towards the ATS2 of the called subscriber (Fig.2zh) .

 ATS2 of the called subscriber, having received a signal message with a call, analyzes the state of the called subscriber (in her memory there are cells where the status of the subscriber is noted) and the presence of a free classified apparatus. With an unoccupied subscriber and the presence of a free security device, the PBX issues a command to the exchange unit 3 to connect the security device to the telephone of the called subscriber (Fig.2z) and, in addition, to the side of the caller’s PBX1 — an alarm message about the connection that has taken place and the need to switch the channel , which, passing through the PBX participating in the connection, commutes the communication channels marked in the connection route, thereby creating a physical communication channel between the PBX (Fig.2i).

 After that, the PBX of the called subscriber connects the security device assigned to the connection to the formed communication channel.

 The PBX of the caller, having received a signaling message about the completed switch-off, also connects the privacy device to the communication channel and issues 3 command codes to the exchange unit 3 to connect the telephone of the calling subscriber to the privacy device, recording their numbers in memory, and also to turn on the signal generator "Wait "(fig.2k), notifying the caller about the completed connection.

 Responding to these commands, the exchange unit 3 via the communication bus 11 generates dial-up channel codes to the telephone circuit switch 7, carrying out the corresponding switching of the telephone and security apparatus 8.

 After that, the exchange unit 3 via the communication bus 11 issues the “Wait” signal code for the signal sensor enable command to the generator block 4, and the output code of the generator block and the code of the telephone pair of the calling subscriber to the sound switch 5. As a result of this, the “Wait” signal sensor is connected to the telephone pair of the calling subscriber (Fig. 2l) and the subscriber hears the corresponding tone or musical phrase. In principle, it is possible to use the "Wait" signal sensor, which is part of the RPU 2-7 of the prototype device, issuing the appropriate command codes to the security device exchange unit via an additional control channel. In Fig. 2m, this possibility is indicated by a dotted line. The timing diagrams presented in figa-2i detail the common operation of the prototype and the proposed method to establish a connection between the telephone exchanges of the calling and called subscribers by the number of the latter. After the communication channel is switched off, the telephone exchanges of the calling and called subscribers send 10 the command code "Start synchronization" to the exchange unit 3 (Fig. 2n). The exchange unit 3 transfers it to the secret device 8 through its exchange unit. The latter selects this command and gives the signal “Start synchronization”, starting the synchronization process of the security equipment (see Fig. 2 of the prototype, where the synchronizing input is the input of the OR element 2-1). The process of synchronizing encoders and decoders is discussed in detail in the prototype and therefore is not considered here. As a result of the exchange of synchronizing information, the privacy devices of the called and calling parties enter into synchronism and give the signal "Synchronization is completed" (fig.2o). In the prototype, this signal corresponds to the signal at the output of the OR element 2-6-7 of FIG. 11. This signal through the exchange unit of the privacy device enters the exchange unit 3. On the calling side, the exchange unit 3, having selected this signal, removes the “Wait” signal, issuing the corresponding signals through the communication bus 11 to the generator unit 4 and the audio signal switch 5. After that, he issues via the communication bus 11 to the indicated blocks, respectively, the signal code "Control the call", the exit code of the generator block 4 and the code of the calling telephone. At the same time, a tonal signal "Control of a call" is sent to the telephone circuit of the device (Fig.2p). On the called side, the exchange unit 3, having received the signal "Synchronization is completed", issues a signal signal "Make a call", the output code of the generator and the code of the called telephone set through the communication bus 11 to the generator unit 4 and the audio switch 5, respectively, resulting in a telephone the circuit of the device is given the tone "Make a call" (Fig. 2P). The called subscriber picks up the handset, while the analyzer of the position of the handset in the subscriber set is triggered. The exchange unit 3 in the process of polling the analyzers emits a signal "MTT raised", as mentioned earlier, cancels the signal "Make a call", issuing the appropriate command codes on bus 11. After that, he issues the command code “Remove call control” (SKPV) to the security device, through which a constant combination sensor is connected to the communication channel. In the prototype, practically these solutions for transmitting the SQWS signal are available. So, for example, in the transmitting speech-converting device (RPU) 2-2 (Fig. 8 of the prototype) there is a sync sensor 2-2-7, which can be used for these circuits: block the operation of the distributor 2-2-5, for example, turn off its output, In this case, the sync sensor 2-2-7 will be constantly connected to the communication channel.

 On the receiving side in the receiving RPU 2-7 (Fig. 9) of the prototype there is a synchro-analyzer 2-7-2, the output signal of which can be used to extract the signals "There are CKPV" and "Cancel CKPV". These signals are allocated in the interface unit 82 (Fig.6) from the signals of the aforementioned analyzer 2-7-2 of the secret block of the prototype. The signal "There is SKPV" (Fig.2u) on the side of the calling subscriber from the output of the interface unit 82 via the communication bus 84 through the joint converter 811 (Fig.5) through the additional control channel enters the exchange unit 3, which, having detected this signal, cancels the signal KPV (fig.2f), issuing over the communication bus 71 codes of the corresponding commands to the block of generators 4 and the switch sound signals 5.

 After this, the exchange unit 3 issues to the security device 8 the command code "Give SKPV", which through an additional control channel through the exchange unit 81 and the interface unit 82 (Fig. 5) enters the security unit 83, while in the communication channel towards the called subscriber the signal SKPV (Fig. 2x) is transmitted, having received which the interface unit 82 stops issuing the signal SKPV in the direction of the caller (Fig. 2c). On the caller side, the coupler 82 emits a “UPCW Cancel” signal and stops transmitting the UPCW signal. After this, telephone conversations are possible.

 The destruction of the connection is as follows. After the negotiations one of the subscribers or both hang up. The tube position analyzer highlights this point. In the next polling cycle of the analyzer, the exchange unit 3 emits the “MTT laid down” signal, issues command codes to the telephone circuit switch, disconnecting the telephone set 1 from the secret device 8, and also transmits a signal message to the PBX indicating the number of the disconnected subscriber. The PBX, having received this message, notes in its memory the number of the released secrecy apparatus and transmits along the connection route a signal message with the command about the destruction and the signal “End” to the subscriber who did not hang up. Upon receipt of this message, the terminal exchange issues a signal message to the exchange unit 3 with the signal code "End". Message block 3, having received this message, issues appropriate commands to the generator block 4 and switch 5 of sound signals via communication bus 11, while the “End call” signal sensor is connected to the subscriber’s telephone circuit, upon hearing which the subscriber hangs up. The tube position analyzer detects this moment and fixes it. In the next polling cycle, the exchange unit 3 emits a “MTT stacked” signal and issues command codes to cancel the “Hang up” signal, as well as to disconnect the telephone from the secret device.

 In order to better understand the operation of the device, let us consider in detail the operation of the analyzer of the digit 23 and the interface unit 82.

The digit analyzer 23 contains the following nodes:
231 - account channel,
232 - front analyzer,
233 - counter fronts,
234 key block
235 - address selector,
236 - trigger
237 - delay element,
238 - pause counter.

 The analyzer figures works as follows. The signals from the output of the telephone set 1 through the subscriber set 21 and the switch 22 enter the channel of the account 231, which, in accordance with [7], contains a 10-day dialing receiver, an integrator and a pulse shaper and generates rectangular pulses, the number of which corresponds to the dialed number.

 The edge analyzer 232 identifies the leading and trailing edges of these pulses. The edge counter 233 on the trailing edges counts the number of pulses in a digit and generates a binary code of this number. With decade-long dialing, the pulse duration is approximately 40 ms, and the intervals between pulses are approximately 60 ms. A sign of a pause between digits is the presence of an interval between the end of one digit and the beginning of another, approximately equal to 180 ms. The pause counter 238 is started by the trailing edge and is reset by the rising edge and gives a sign of the presence of a pause between the digits of the number after the trailing edge of the last pulse arrives. The pause sign is stored on the trigger 236. When the analyzer receives the address of the digit and read signal via the communication bus 11, the address selector 235 is activated, which opens the key block 234, from the output of which the digit code with the sign of pause is sent to the communication bus 11. Reset counters 233 and 238 , as well as the trigger 236 is carried out by the signal from the output of the selector 235, delayed in element 237.

 Examples of implementation of the address selector are given in [8, p. 56-59].

The interface unit 82 contains the following nodes:
821 - transmitter of the command "There is SKPV",
822 - transmitter command "Synchronization is complete",
823 - receiver of the command "Give SKPV",
824 - receiver of the command "Start synchronization",
825 is the first counter,
826 is the second counter,
827 is the first trigger
828 - the element "And",
829 - the element "OR",
830 is the second trigger.

 The interface unit operates as follows.

 According to the timing diagram of FIG. 2c, when the called subscriber picks up the handset, the exchange unit 3 issues the “SKPV” command to the secret device 8, which, through the receiver 823, sets the trigger 830 to state “1”, and the signal from this trigger enters the security unit 83, while toward the calling subscriber the combination of CKPW will be transmitted continuously, from the output of the classification block 83 (analyzer 2-7-2 of the prototype) it enters the first 825 counter, which is triggered when n consecutive pulses are received at its counting input, and can be implemented, for example, by shifting the register a decoder connected to the discharge register and analyzing n-bit sequence 111 ... 1. The signal from the output of the counter is transmitted to the transmitter 821 as the command "There is a CKPW", is read by the signals from the exchange unit 3, which are received via the bus 84 (Fig.2u).

 The signal from the output of the first 825 counter triggers the first 827 trigger, and the And 828 element opens and the clock frequency ft enters the second 826 counter, which is reset by the signal from the output of the first 825 counter.

The exchange block 3 of the calling party, having accepted the command “There is SKPV”, issues the command “Give SKPV” to the security block (Fig. 2f), while the second 830 trigger will be set to state “1” and the combination of SKPV will arrive towards the called subscriber (FIG. .2x). The first 825 counter will highlight the command “There is SKPV” and through the OR element will reset the second 830 trigger, thereby stopping the transmission of the SKPV signal to the caller (Fig.2c). On the calling side, the first 825 counter will stop issuing the “There is SKPV” command, the second 826 counter will work, highlighting the “Cancel SKVV” signal, which resets the first 827 trigger, and the second 830 trigger is reset through the OR element 829, also stopping the transmission towards the called subscriber signal SKPV (Fig.2sh)
Transmitters 821 and 822 and receivers 823 and 824 can be performed similarly to the signal selector shown in Fig.3.

 Thus, the proposed method and device for its implementation provide synchronization of security devices until the communication channel is provided to subscribers (until the called party lifts the handset), which reduces the delay in providing the communication channel for the synchronization time compared to the delay in the prototype method and device. However, it should be noted that some delay still remains due to the exchange of SQW signals.

, (1)
где
x - корень уравнения
S=1+gp^rs^r+1, (2)
находящийся методом последовательных приближений, положив сначала х₀=1, тогда x₁=f(х₀) и так далее х_v=f(х_v-1)
При приведенных выше параметрах р, g, r, N в качестве корня достаточно взять x₄= 1,0528 Тогда вероятность правильного приема сигнала СКПВ в соответствии с выражением (1) составит P_N=0,9996.Compare the known and proposed methods for the time delay in the start of negotiations. Modern equipment should work with the quality of the communication channel, measured by the probability of distortion of the binary signal up to Roche = 0.1. Let a 24-bit combination be transmitted as an SQWF signal. The decision to isolate the CPSR signal is made if two combinations of these combinations are received with a length N of the CPSR signal equal to 10 combinations. Let Roche = 5 • 10 ^-2 . Then the probability of correct reception is defined as the probability of a series of successes of length r = 2, in the Bernoulli test sequence, length N = 10, with success probabilities p = 1-Roche = 0.95 and failure g = Roche = 0.05 according to the formula [11 ]

, (1)
Where
x is the root of the equation
S = 1 + gp ^r s ^{r + 1} , (2)
found by the method of successive approximations, setting first x ₀ = 1, then x ₁ = f (x ₀ ) and so on x _v = f (x _v-1 )
With the above parameters p, g, r, N, it is sufficient to take x ₄ = 1.0528 as the root. Then, the probability of the correct reception of the SQW signal in accordance with expression (1) will be P _N = 0.9996.

According to GOST 29147-89 [12, 13], the length of the synchro-packet of the security device must be at least 64 bits. Let the clock package be transmitted with a recurrent signal of length (1 + N) bits, where N is the number of checks for recurrence. We assume that the probability of separating two combinations from noise in a row is equal to the probability of extracting a recurrent signal from noise, then
1 + N = 64 + 48 = 112 bits.

The calculations carried out according to the formula of AF Kozlov given in [14] for Roche = 5 • 10 ² show that in order to isolate a recurrent clock signal with a length of 112 bits, with a probability P _N = 0.9996 it is necessary to transmit a clock signal with a length of about 10,000 bits, which is more than 40 times the length of the CKPV signal

At a speed of 2400 bit / s, transmitting an SQW signal of 240 bits in length will take 0.1 s (one way), which is almost invisible to the subscriber. At the same time, hearing noise on the prototype method in the phone after the called party picks up the phone during a sync transmission time exceeding 4s (with Roche = 5 • 10 ^-2 ) is clearly unacceptable. If the quality of the communication channel is worse, for example, Roche = 1 • 10 ^-1 , this time will be very long.

 Thus, the above calculations and examples of the implementation of the method allow us to judge the feasibility of the technical result, which consists in reducing the delay time at the beginning of negotiations.

 In addition, since the communication signal is provided almost immediately after the called subscriber picks up the handset, the accuracy of recording the duration of negotiations increases.

Sources of information
1. "Electronic-digital switching systems." M. "Radio and Communications", 1985

 2. RF application 95102238 from 02.17.95, N 04 M 3/00 "Method for automatically establishing a connection of telephone subscribers and a device for its implementation."

 3. Copyright certificate of the USSR 1633511, N 04 M 3/22. "A method of establishing a connection on a telephone network."

 4. RF patent 2030838, N 04 M 3/22. "A method of automatic switching in a communication network and a system for its implementation."

 5. Certificate 8194 for the utility model "Confidential Communication Device" dated 10.16.98.

 6. Certificate 7568 for the utility model "Confidential Communication Device" dated 08.16.98

 7. Copyright certificate 1286087, M. cl. N 04 M 3/00 "Device for receiving impulses of ten-day dialing."

 8. Novikov Yu.V., Kalashnikov O.A., Gulyaev S.E. "Development of interface devices" ECOM, M., 1997

 9. CCITT Blue Book, Volume IV, no. VI.10. "Digital subscriber signaling system 1 (CAC1), data link level. Recommendations Q920-Q921.

 10. Microprocessors. T.1 ed. L.N. Presnukhina, M., Higher School, 1986

 11. V. Feller "Introduction to probability theory and its applications", "Mir", Moscow, 1967, pp. 326-327.

 12. A. V. Spesivtsev, V. A. Wagner, A. Yu. Krutikov, V. V. Seregin, V. A. Sidorov. "Protection of information in personal computers." M., "Radio and Communications", WESTA, 1992

 13. GOST 28147-89. "Information processing systems. Cryptographic protection. Cryptographic transformation algorithm."

 14. Kalmykov B.P., Rachkauskas R.S. "On the question of group phasing using a recursive sequence," FEV. Ser. TPN, issue 3, 15, 1968

Claims (1)

 A device for automatically establishing a connection for conducting secret negotiations, containing telephone sets and classified devices, characterized in that a subscriber unit unit, an exchange unit, a generator unit, an audio signal switch, a telephone circuit switch and OR elements are inserted into it, while the block of subscriber sets are connected to the corresponding first inputs of the telephone circuit switch, the first outputs of which are connected via OR elements to the corresponding inputs telephones, and the second inputs and outputs of the telephone circuit switch to the first information outputs of the security devices, the second information inputs and outputs of which are connected to the outputs of the device, the control channel of which is connected to the main input and output of the exchange unit connected with additional inputs outputs to the additional outputs-inputs of the respective security devices, and the communication bus to the block of subscriber sets, the telephone circuit switch, the generator block and the sound switch output signals, while the group of inputs of the latter is connected to the group of outputs of the generator block, and the outputs are connected to the second inputs of the corresponding OR elements.

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