RU177965U1 - UNIFIED REQUEST SIGNAL PROCESSING DEVICE - Google Patents

Abstract

The utility model relates to the field of radio engineering, in particular to devices for secondary processing of recognition signals of an airborne radar station, and can be used in aircraft interrogators of radar recognition systems "Password" and "MK XII." The technical result is to reduce the overall dimensions of the device, its unification and increased reliability. The unified identification signal processing device comprises a request signal encoder and response signal decoder “Password”, a response signal analyzer, a control and switching module, request signal encoder and response signal decoder “MK XII”, an overhead information processing module, combined in the signal processing unit, and the interface unit, including a serial trunk interface, matching schemes with persecuted the digital duplex interface. The utility model allows to process interrogator signals in the “Password” radar recognition system, as well as in the “MK XII” radar recognition system, and is capable of interacting with the MCC on the serial serial interface and with radar on the digital duplex interface, while remaining compatible with the interrogators used. 2 ill.

Description

The unified signal processing device of the interrogator relates to the field of radio engineering, in particular to the secondary processing devices for the recognition signals of the airborne radar station, and can be used in aircraft interrogators of radar recognition systems "Password" and "MK XII".

The closest in technical essence, the functions performed and the design is the pulse block of the interrogator 230401 (GB2.222.113), developed at JSC ʺ NPO Radioelectronics named after IN AND. Shimkoʺ (Kazan), designed to process state recognition signals in the “Password” system when used as part of aircraft interrogators and adopted as a prototype. The block diagram of the interrogator pulse block is shown in FIG. one.

The prototype device is made in the form of a separate unit containing printed circuit boards interconnected by wired installation. On the printed circuit boards there is a request signal encoder 1 and a response signal decoder 2 of the Password radar recognition system, a switching and control module 3, a response signal analyzer (APOS) 4, a switching and limiting analyzer 5, a suppression circuit 6, a decoder channel switch 7 , a circuit for generating a trigger signal of an encryption-decrypting device (SDU) 8, a circuit for generating codes of temporary automatic attenuation adjustment (VARO) 9, wherein the encoder 1 is connected to a switching and ogre circuit 5, with the switching and control module 3 and with the suppression forming circuit 6, the decoder 2 is connected to the channel switch of the decoder 7, with the switching and control module 3 and APOS 4, the switching and control module 3 is also connected to the triggering formation circuit of the SDU 8, with APOS 4, and with the VARO 9 code generation scheme.

The prototype works as follows.

Synchronization pulses I, III of the radar identification system (RLS) “Password” from the airborne radar station (radar) are sent to the interrogator pulse block for switching circuit and limit 5, after which they are fed to encoder circuit 1. Encryptor 1 generates a request signal of modes I, III “Password” radar recognition system, in accordance with the control signals received from the controls through the switching and control module 3. In addition, the encoder starts the suppression pulse generation circuit 6, which I feed camping in the onboard equipment, as well as impulses permission form. Synchronization pulses of the II mode of the radar recognition system “Password” also enter the block through the switching circuit and restrictions 5 into the signal generation circuit of the SDU 8 trigger, controlled by the switching and control module 3. Pulses of the response code flag are received from the SDU to the decoder 2. Also, in the decoder 2 through the switch channel 7 receives the response signals "Impulse f2" and "Impulse f3". The decoder 2 is controlled from the switching module of the operating and control modes 3. After analysis, the decoder 2 generates the corresponding decryption pulses, which enter APOS 4, where recognition pulses are generated after the evaluation. To control the attenuators of the receiver in the interrogator pulse block, the VARO 9 code generation circuit is used, which is controlled by the switching and control module 3 by the VARO control signals.

Such a signal processing device has significant disadvantages:

- signal processing circuits are implemented on discrete logic elements, which complicates the change of operation algorithms and does not significantly reduce weight and size characteristics;

- the device is intended for use only in aircraft interrogators of the radar recognition system "Password";

- there is no digital exchange interface with the on-board digital computer complex (BTsVK), which involves the use of only manual control, or requires an external interface unit;

- there is no digital interface for exchanging with radar, which limits the applicability of the unit in modern radar.

- wired installation between the boards is used, which reduces the reliability of the unit and increases the likelihood of an error during installation;

The main task to which the claimed utility model is directed is the creation of a unified interrogator signal processing device capable of processing interrogator signals in the “Password” radar system, as well as in the “MK XII” radar system, which is capable of interacting with the BCVK via the main serial interface and with Radar on a digital duplex interface, while remaining compatible with the interrogators used.

The technical result achieved by the implementation of the proposed technical solution is to reduce the overall dimensions of the device, its unification and increased reliability.

The specified technical result is achieved by the fact that in the well-known impulse block of the interrogator, containing the encoder and decoder of the RLO "Password" system, an analyzer of the response signal sequence, a control and switching module, an additional encoder of interrogation signals and a decoder of response signals of the radar recognition system "MK XII" are additionally introduced, service information processing module and interface, including a serial trunk interface for communication with the on-board digital computer complex, digital dup an electronic interface for communication with the airborne radar station and a signal matching circuit, while the request signal encoder and response signal decoder “Password”, the request signal encoder and response signal decoder MK XII system, the response signal analyzer, the service information processing module and the control and switching module is combined into one signal processing unit and implemented on one programmable logic integrated circuit inside which all the blocks interact with each other, as well as with the interface through the control module, structurally the signal processing unit and the interface are located on printed circuit boards connected to each other and output connectors without wiring.

The analysis of the prior art cited by the applicant made it possible to establish that there are no analogs characterized by sets of features identical to all the features of the claimed unified signal processing device. Therefore, the claimed technical solution meets the conditions of patentability "novelty."

The search results for known solutions in the art in order to identify features that match the distinctive features of the prototype of the features of the claimed technical solution have shown that they do not follow explicitly from the prior art. From the prior art determined by the applicant, the influence of the transformations provided for by the essential features of the claimed technical solution on the achievement of the specified technical result is not known. Therefore, the claimed technical solution meets the condition of patentability "utility model".

In FIG. 2 presents a structural diagram of the inventive unified device for processing signal interrogator.

The unified recognition signal processing device comprises a request signal encoder 1 and a response signal decoder 2 of the Password radar recognition system, a response signal sequence analyzer 3, a control and switching module 4, a request signal encoder 5 and a response signal decoder 6 of the MK XII radar recognition system , an overhead information processing module 7, combined into a signal processing unit, and an interface unit including a serial trunk interface 8, consonant circuits signals 9 and digital duplex interface 10.

The proposed unified signal processing device operates as follows:

Through the signal matching circuit 9 of the interface node, the control and switching module 4 of the signal processing node receives control signals from the control bodies and clock pulses from the radar, according to which, in the encoder module 1, when operating in the “Password” radar system modes, or in the encoder module 5 when operating in the modes of the MK XII radar system, request codes and suppression and permission signals are generated that are output to the device via the signal level matching circuit 9. The password response signals of the RLO system identification are received in odule decoder system RLS "Password" 2 through the matching circuit 9 levels node interface unit and the control and switching signal processing unit 4. After decoding, the decoder 2 generates decryption pulses in the APOS 3. The response identification signals of the MK XII radar system are supplied to the descrambler module of the MK XII 6 radar system through the matching circuit 9 of the interface unit and the control and switching module of 4 signal processing units. After decoding, the decoder 6 generates decryption pulses in APOS 3. In APOS 3, identification pulses are generated that are transmitted to the radar via the control and switching module 4 of the signal processing unit and the signal matching circuit of the 9 interface node. In mode 2 of the RLO “Password” system, the control and switching module 4 of the signal processing unit generates the triggering pulses of the control gear, which are fed to the control gear via the signal matching circuit 9 of the interface unit. Signals from the SDU through the signal matching circuit 9 of the interface unit and the control and switching module 4 of the signal processing unit to the decoder 2 are used to indicate the response codes.

The control can also be carried out through the main serial interface 10 by commands from the BCVC, the signals received in the main serial interface are transmitted through the control and switching module 4 to the signal processing unit to the service information processing module 7. The exchange with the radar can take place via the digital duplex interface 8, the signals from which are supplied to the service information processing module 7 through the control and switching module 4.

Claims (1)

A unified requestor signal processing device comprising a request signal encoder and a response signal decoder "Password", a response signal analyzer (APOS), a control and switching module, further comprising a request signal encoder and a response signal decoder of the radar recognition system MK XII, service information processing module and interface, including a serial trunk interface for communication with an on-board digital computer complex, a digital duplex interface for communication with the on-board radar station and a signal matching circuit, while the request signal encoder and response signal decoder "Password", the request signal encoder and response signal decoder MK XII, APOS , the service information processing module and the control and switching module are combined into one signal processing unit and implemented on one programmable logic integrated circuit, in inside of which all the blocks interact with each other, as well as with the interface through the control module, structurally the signal processing unit and the interface are located on printed circuit boards connected to each other and output connectors without wiring.

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