RU2191403C1 - Friend-or-foe identification system - Google Patents

Abstract

FIELD: radio engineering, determination of nationality of mobile objects and their identification. SUBSTANCE: friend-or-foe identification system has interrogator positioned on ground and responder located on mobile object, elements and proper couplings which make it possible for interrogator to form random interrogation signal and for responder to form return signal to received interrogation signal alone. EFFECT: increased efficiency of given friend-or-foe identification system thanks to stability of interrogation and reduced time of emission of information on nationality of object. 2 dwg

Description

 The invention relates to radio engineering and can be used to determine the nationality of mobile objects (for example, aircraft) and their identification.

 A known friend-or-foe identification system [1], including a requestor, a synchronization device, and a transponder, the requestor also includes a pulse generator, a digital counter, a code computing device, a subtractor, and a response signal receiver, the output of which is through a decoder the response signal is connected to the second input of the subtractor, the synchronization device includes a phase synchronizer, the input of which is connected to the second output of the pulse generator, and synchronization a digital code torus, the input of which is connected to the second output of the digital counter, and the transponder consists of series-connected pulse generator, digital counter, code computing device, adder, encoder, and response signal transmitter.

 However, this system has such a disadvantage as low secrecy of the objects on which the transponder is installed, due to the fact that signals for identification are transmitted continuously. The continuous emission of information from objects about their affiliation is an important unmasking sign that the enemy can use when hitting them with missiles with a homing head to the radiation source [2].

 The aim of the present invention is to increase the efficiency of the recognition system "friend or foe" by imitating the query and reducing the time of radiation information about the ownership of the object.

 This goal is achieved by the fact that in the known recognition system "friend or foe", including a requestor, a synchronization device and a responder, moreover, the requestor includes a series-connected pulse generator, digital counter, a code computing device, a subtractor, and a response signal receiver, the output of which through the decoder of the response signal is connected to the second input of the subtracting device, the synchronization device includes a phase synchronizer, the input of which is connected to the second output m of a pulse generator, and a digital code synchronizer, the input of which is connected to the second output of the digital counter, and the transponder consists of series-connected pulse generator, digital counter, code computing device, adder, encoder and response signal transmitter, are additionally sequentially introduced into the interrogator circuit connected register of the request number, the first electronic key, the encoder of the request number, transmitter, antenna switch, antenna, as well as a clock generator, cat through the second electronic key is connected to the clock counter and the second input of the request number encoder, the second output of the antenna switch is connected to the input of the response signal receiver, the output of the clock counter is connected to the second input of the second electronic key, the output of the first electronic key through the first delay line is connected to the second input of the first electronic key, the third output of the pulse generator through the second delay line is connected to the first input of the request number register, and through the circuit coincides and - with the third input of the first electronic key and the third input of the request number encoder, the output of the match circuit through the third delay line is connected to the second input of the clock counter and the third input of the electronic key, the output of the code computing device through the encryption block is connected to the second input of the request number register, and a buffer register, a third electronic key, a password register, an adder modulo two and a coincidence counter, as well as therefore, the connected antenna switch, the receiver of the request signal, the decoder of the request number, the register of the request number, the output of which is connected to the second input of the adder modulo two, the output of the third electronic key through the fourth delay line is connected to the second input of the third electronic key, and also a clock generator, which through the fourth electronic key is connected to the input of the clock counter, the second input of the password register and the second input of the request number register, the code output will calculate The second device through a second cipher block is connected to the input of the buffer register, the output of the coincidence counter is connected to the second input of the response signal transmitter, the second output of the request signal receiver is connected to the third input of the third electronic key, the second input of the fourth electronic key, the second input of the clock counter and the second input coincidence counter, the output of the pulse generator through the fifth delay line is connected to the second input of the buffer register, the output of the response signal transmitter is connected nen with the second input of the antenna switch.

 A comparative analysis with the prototype showed that the distinguishing features of the proposed device increase the efficiency of the system due to imitation-stable query and a significant reduction in the time of radiation of information about the ownership of the object, which indicates the "novelty" of the technical solution.

 An analysis of the patent literature showed that prior to the filing date, there were no devices with the indicated set of essential features required to obtain a technical result, which meets the criterion of "inventive step".

 The evaluation of the system performance is given below.

The block diagram of the device is shown in FIG. 1. The numbers on the diagram indicate:
1, 9 - pulse generator (GI);
2, 10 - digital counter (CA);
3, 11 - code computing device (HLC);
4 - subtractive device (WU);
5 - decoder response signal (DOS);
6 - receiver response signal (Pr OS);
7 - phase synchronizer;
8 - digital code synchronizer;
12 - adder;
13 - encoding device (KU);
14 - transmitter response signal;
15 - synchronization device (CSS);
16, 17, 18, 23, 43 - delay line (LZ), respectively, 2nd, 1st, 4th, 3rd and 5th LZ;
19, 36 - request number register (RZCh);
20, 21, 22, 24 - electronic key (EC), respectively, 1st, 2nd, 4th and 3rd EC;
25 - request number encoder (KCH);
26 - transmitter;
27, 33 - antenna switch (AK);
28, 31 - counter clock pulses (STI);
29, 30 - clock generator (GTI);
32 - buffer register (BR);
34 - receiver request signal;
35 - request number decoder (DZCH);
37 - adder modulo two (SMD);
38 - password register (RP);
39 - hit counter (CC);
40 - the defendant;
41 - interrogator;
42 is a coincidence diagram (Cx);
44, 45 - cipher block.

 Let us consider the operation of the system according to the block diagram shown in FIG. 1. First, it is necessary to synchronize the operation of the equipment of the interrogator and the respondent. Synchronization is carried out on Earth before an object (for example, an airplane) takes off, using a synchronization device (15). For this, the synchronizer output in phase (7) is connected to the pulse generator (9) by a wire communication channel, and the digital code synchronizer output (8) is connected to the second input of the digital counter (10).

 The device (7) can consist of a simple pulse amplifying circuit, which amplifies the pulses from the GI (1) and feeds them to the input of the GI (9), thereby ensuring in-phase operation (1) and (9). The digital code synchronizer (8) can consist of many simple DC amplifiers, one for each digit of the digital counter (2), which amplify the output signals (2) and then feed them to the DS (10), whereby the corresponding stages of the DS (10) ) will be in the same states as in the CA (2). By ensuring the synchronous operation of the interrogator and the responder, communication between devices (15) and (40) can be broken.

If the relative stability of the GI frequency (1) and (9) is taken to be 10 ^-7 (which can be achieved by well-known methods), and the pulse repetition rate is 1 pulse per second, then the difference between the generators (1) and (9) in phase by one the tenth cycle will occur after approximately 28 hours of continuous operation. Thus, during this period of time, digital counters (2) and (10) will show the same number, and GI (1) and (9) will work in phase.

 Information characterizing the state of the CA (2) and (10) is fed to the inputs of the code computing devices (3) and (11), respectively. KVU (3) and (11) are designed to perform a sequence of mathematical and logical operations, such that their output signals become a sequence of randomly changing numbers. These numbers in the interrogator (41) are fed to the first input of the subtracting device (4) and through the encryption block (44) to the second input of the RZCh (19). The pulse from the output of 3 GI (1), arriving through the LZ (16) to the first input of the RZCh (19), information with a parallel code can be rewritten in the KChZ (25), if EC (20) is open.

 After turning on the interrogator (41), the state of the EC (20) and (21) is ambiguous and it is saved only at the initial moment in time. If after turning on the interrogator (41), the EC (20) is open, then after the first cycle of information transfer from the RCH (19) to the RPC (25) by the pulse from the output of the EC (20) through the LZ (17), the EC (20) closes and will continue to be open only by a pulse from the output of the coincidence circuit (42) when the request signal is generated, and if EC (21) turns out to be open, then the pulses from the GTI (29) arrive at the STI (28). After the STI is overfilled (28), a pulse appears at its output, which enters the input 2 of the EC (21) and closes it. Thus, in the steady-state operation mode of the interrogator (41), the ECs (20 and 21) are closed, the generated request number is located in the RCH (19), which is periodically read out by the pulse from the third input of the ГИ (1), but it does not enter the КЗЧ (25) ( EC (20) is closed).

 In the defendant (40) at the initial time, the state of EC (24) and (22) is not determined. However, after the first cycle of transmitting information from the BR (32) to the password register (38) through the open EC (24), the pulse from the output of the EC (24) through LZ (18) enters the second input of the EC (24) and closes it, and the EC ( 22) is closed by a pulse from the STI output (31), which appears after its overflow. It follows that in the steady-state operation mode of the responder (40), the ECs (24) and (22) are closed, in the BR (32) there is a number (password), similar to the number recorded in the RZCh (19) of the interrogator, which is periodically read by the pulse from the output GI (9) through LZ (43), but does not enter the password register (38) (EC (24) is closed).

 Information from the output of the HLC (11) in addition to input 1 of the BR (32) is fed to the input of the adder (12), the second input of which receives the signal "password" (a signal that determines the ownership of the object). The total signal from the output of the adder (12) is fed to the input of the control unit (13), which converts it into a pulse or frequency code and transmits to the first input of the response signal transmitter (14), but the signal received at the first input (14) is not radiated, since there is no permission that must go to input 2 of the response signal transmitter (14). Thus, the recognition system "friend or foe" is ready to transmit (receive) signals "Request".

 In the general case, the moment of transmitting the “Request” signal is determined by the operator or is determined automatically when an unidentified object appears in the interrogator coverage area.

 Upon receipt of the “Request” signal and the pulse from the output of the GI (1) at the inputs of the coincidence circuit (42), a pulse appears at its output, which is fed to the input 3 of the EC (20) and to the input 3 of the encoder of the request number (25), and through LZ (23) - to the input of 2 STI (28) and to the input of 3 EC (21). With this pulse, the ECs (20) and (21) are opened, and the elements of the STI (28) and KPC (25) are set to the initial state. The pulse from the output of 3 GI (1) through the LZ (16) is fed to the input of the RZCh (19) and reads the information from it through the open EC (20) to the RPS (25). By the signal from the output of the EC (20) through the LZ (17), the EC (20) is closed. The pulses from the GTI (29) through the open EC (21) are received at the input 1 of the STI (28) and the input 2 of the short circuit switch (25), allowing the transmission of the signal "Request". When STI overflows (28), an impulse appears at its output, which closes the EC (21). From the output of the CLC (25), the signal enters the transmitter (26) and then to the AK (27) and the antenna. The process for transmitting the Request signal has ended.

 The signal emitted by the interrogator antenna (41) is received by the transponder antenna (40) and, through the AK (33), is input to the receiver of the interrogation signal (34). From the output 1 of the receiver of the request signal (34), the signal goes to the input of the remote control device (35), and after decoding, to the register of the request number (36). Upon completion of the reception of the signal "Request" from the output 2 of the receiver of the request signal (34), a signal is input to input 3 EK (24), input 2 EK (22), input 2 STI (31) and input 2 counter hits (39). EC (24 and 22) are opened, and elements of the counter of coincidences (39) and STI (31) are set to the initial state.

 The pulse from the output of the GI (9), coming through the delay line (43) to the input 2 of the BR (32), information from the BR (32) through the open EC (24) is entered in the password register (38). By the signal from the output of the EC (24) through the LZ (18), the EC (24) is closed. The pulses from the GTI (30) through the open EC (22) arrive at the input 1 of the STI (31), the input 2 RP (38) and the input 2 RZCh (36). Information from the RZCh (36) and RP (38) synchronously arrives at the corresponding inputs of the adder modulo two (37), where the comparison occurs. The comparison results are sent to the input of the coincidence counter (39), when overflowing, a pulse appears at its output, which is fed to input 2 of the response signal transmitter (14) and allows the transmission of the response to the request. The response signal from the output of the response signal transmitter (14) through the AK (33) and the antenna is broadcast. The signal emitted by the antenna of the responder (40) is received by the antenna of the interrogator and through the AK (27) is fed to the input of the receiver of the response signal (6). From the output of the receiver, the signal enters the DOS (5) and then to the second input of the subtracting device (4), where the output of the HLC (3) is subtracted from the received signal. The result identifies the ownership of the object and its conditional number.

 In FIG. 2 shows the encryption block (elements 44 and 45) of the identification system. This element is a switching device with m inputs and m outputs. If a binary number of the type "10101010101" is fed to the input of the encryption block (see Fig. 2), then we will get another number "00111110010" at the output. Thus, the encryption block provides additional uncertainty in the formation of the interrogation signal.

To assess the effectiveness of the proposed system, we take as the indicator the probability of the formation of the correct request (answer) by the enemy in a single attempt R. When evaluating, we will proceed from the assumption that the enemy knows everything about the system except the state of the central clock (2) and (10), the clock speed of the GI (1) and (9), the structure of encryption pads (44) and (45) and the algorithm of work (3) and (11). Taking into account the degree of uncertainty in which the adversary is located, the probability of guessing each character m values of the sequence is 0.5. Then the probability of the formation of the correct answer by the adversary in a single attempt is
P = 1/2 ^m .

 Choosing the value of m, you can provide any desired value of the indicator P. By organizing a request-response process of information exchange between the interrogator and the respondent, this reduces the time of radiation of electromagnetic energy, which eliminates the defeat of objects equipped with a defendant, missiles with homing missiles to the source of electromagnetic radiation.

Literature
1. USA 3750163, 1973

 2. Paly A. I. Electronic warfare. - M .: Military Publishing House, 1981 (p. 132-140).

Claims (1)

 A friend or foe identification system, including a requestor, which includes a pulse generator, a digital counter, a code computing device, a subtractor, and a response signal receiver, the output of which is connected to the second input of the subtractor through a response decoder, and a transponder including a series-connected pulse generator, a digital counter, a code computing device, an adder, an encoding device and a response signal transmitter, wherein the phase synchronizer amplifies the pulses from the interrogator pulse generator and feeds them to the input of the transponder pulse generator, and the digital code synchronizer amplifies the output signals of the interrogator digital counter and then feeds them to the transponder's counter, characterized in that the interrogator additionally includes series-connected request number register , the first electronic key, a request number encoder, a transmitter, an antenna switch, an antenna, and also a clock generator, which, through a second electronic the th key is connected to the clock pulse counter and the second input of the request number encoder, the second output of the antenna switch is connected to the input of the response signal receiver, the output of the clock pulse counter is connected to the second input of the second electronic key, the output of the first electronic key through the first delay line is connected to the second input of the first electronic key, the third output of the pulse generator through the second delay line is connected to the first input of the request number register, and through the coincidence circuit - with the third input of the first the electronic key and the third input of the request number encoder, the output of the match circuit through the third delay line is connected to the second input of the clock counter and the third input of the second electronic key, the output of the code computing device through the encryption block is connected to the second input of the request number register, and the transponder is additionally input a buffer register, a third electronic key, a password register, an adder modulo two and a counter of coincidences, as well as series-connected in series an antenna switch, a request signal receiver, a request number decoder, a request number register, the output of which is connected to the second input of the adder modulo two, the output of the third electronic key through the fourth delay line is connected to the second input of the third electronic key, and also a clock generator, which the fourth electronic key is connected to the input of the clock counter, the second input of the password register and the second input of the request number register, the output of the code computing device through the second encryption block is connected to the input of the buffer register, the output of the coincidence counter is connected to the second input of the response signal transmitter, the second output of the request signal receiver is connected to the third input of the third electronic key, the second input of the fourth electronic key, the second input of the clock counter and the second input of the coincidence counter, the fourth electronic switch closes the pulses from the output of the clock counter, the output of the pulse generator through the fifth delay line is connected to the second buffer input of the register, the output response signal transmitter - the second input of the antenna switch.

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