RU84135U1 - IDENTIFICATION SYSTEM USING THE FREQUENCY SIGN OF A RADAR STATION - Google Patents

Abstract

An identification system using the frequency feature of a radar station, consisting of a radar interrogator, a radar station, a combined antenna system located on an identifying object, a radar transponder located on an identifiable object, a radar interrogator, consisting of a synchronizer of the interrogator, an encoder-decoder of the interrogator, and a transceiver , frequency-code converter, radar station, consisting of a radar synchronizer a station, a radar transceiver, a pairing device, a single indication system, a radar transponder, consisting of a transponder transponder, a transponder encoder, a decider, a frequency analyzer, a transponder antenna, a frequency analyzer antenna, the outputs of the radar station synchronizer are connected to the radar transceiver , with interface, with a single display system, with the interrogator synchronizer, the outputs of the transceiver are glad the location station is connected to a combined antenna system, to a pairing device, to a frequency-to-code converter, the output of the pairing device is connected to a single indication system, the frequency-to-converter converter output is connected to the interrogator transceiver, the interrogator synchronizer outputs are connected to the frequency-code converter, with the the decoding device of the interrogator, with the transceiver of the interrogator, the outputs of the encoder-decoding device are connected to the transceiver of the interrogator, to the interface

Description

The utility model relates to the field of radio engineering and can be used to determine the state of an object (target) according to the principle of "friend or foe".

Known autonomous recognition system with an active response (ASOAO) [1], which is installed on interacting "their" objects. This system is characterized by the presence of a special request channel with its own operating frequency.

ASOAO includes a radar interrogator (RE) and a radar transponder (RO), while the work of the RE is carried out in conjunction with a radar station (radar) that irradiates an identifiable target.

One of the main requirements for state recognition systems is to provide a resolution in angular coordinates corresponding to the resolution of the radar, together with which the recognition system works.

The disadvantage of ASAO is the difficulty of providing resolution in angular coordinates, equal to the resolution of the radar, associated with the difficulty of creating additional highly directional antenna systems of RP and their installation on aircraft.

The objective of this utility model is to simplify the provision of resolving power in angular coordinates equal to the resolving power of the radar irradiating the target with which the recognition system works, by using the frequency feature of the radar.

To solve this problem, an identification system using the radar frequency feature is proposed, which differs from ASOAO: 1) the absence of highly directional antenna systems of the RE, 2) the presence of a combined

antenna system (CAC), 3) the presence in the RE of the frequency-to-code converter (PCC) 4) the presence of additional devices in the RO, such as: a frequency analyzer (AH), an antenna of a frequency analyzer (AAC), a resolver (RU).

The proposed identification system allows to simplify the provision of resolving power in angular coordinates equal to the resolving power of the radar irradiating the target.

To explain the described system in figure 1 shows a structural diagram.

The proposed system is installed on interacting objects, while on the identification object 1 is installed RE 2, which includes: the interrogator synchronizer (SZ) 3, PCC 4, the encoding and decoding device of the interrogator (KDUZ) 5, the transceiver of the interrogator (PRM-PRDZ) 6. RZ 2 works in conjunction with radar 7, which includes: a pairing device (US) 8, a single indication system (SEI) 9, a transceiver (PRM-PRD) 10, a synchronizer (C) 11. RZ and radar work through combined antenna system (CAC) 12. To an identifiable object 15 PO 16 is tuned, which includes: transponder transceiver (PRM-PRDO) 17, transponder antenna (AO) 13, АЧ 18, ААЧ 14, РУ 19, encoder-decoder of the transponder (KDUO) 20, transponder synchronizer (CO) 21.

The proposed system works as follows.

As can be seen in figure 1, C 11 synchronizes the operation of the elements of the radar, PRM-PRD 10 generates a radar signal (S _radar ) at a frequency f _obn , which is emitted through the CAC 12. The reflected signal from the target 15 (S _OTP ) arrives through the CAC 12, PRM-PRD 10 and CSS 8 at the input of SEI 9. SEI 9 displays the mark from the target radiated. After the detection of target 15, C 11 gives a start-up pulse of the RE, which is fed to the input of the SZ 3. The SZ 3 synchronizes the operation of the elements of the RE 2. CDCU 5 encodes a request signal (S _ccd ), which

through PRM-PRDZ 6 and САС 12 is transmitted to the RO 16 at a frequency f _ref . PChK 4 removes information about the frequency f _obn from PRM-PRD 10 and converts it into a radar frequency characteristic (S _pc ) (defined code), which through PRM-PRDZ 6 and САС 12 is also transmitted to PO 16 at a frequency f _ref . At PO 16, under the control of the signals from the output of CO 21, S _cduz and S _cells enter through AO 13 and PRM-PRDO 17 to KDUO 20 and RU 19 respectively. KDUO 20 processes the S _cfd and generates a coded response signal (S _sp ), which is fed to the switchgear 19. At ACH 18, a signal from the irradiating radar 7 at a frequency f _obn. , ACh 14 determines a given frequency, and outputs information on it in the form of a code (S _Ah) on the PV 19. EN 19 compares S and S _{pchk av} and if the two match enables transmission through _holes S CSTR PRDO 17 and ARC 13 at frequency f _open Thus, only those objects that are within the radar radiation pattern (BF) will respond to the interrogation signal, while all objects that are within the RP radar but not within the radar beam will not give a response signal. After NAC 12 and Rx-Tx 6 S enters the _holes 5. KDUZ KDUZ Sotv 5 decodes and outputs the pulse identification guaranteed through CSS 8 SNH 9.

Possible applications cover all objects where installation of state identification systems is required.

Thus, the proposed identification system can significantly simplify the provision of resolution in angular coordinates equal to the resolution of the radar, since for this purpose no additional highly directional antenna systems of the interrogator are required in this system. Also, this system allows you to save all the advantages of ASOAO.

Literature:

1. Radar - the information basis of the combat operations of multifunctional aircraft / A.R. under the editorship of A.I. Kanaschenkova, V.I. Merkulova. - M .: Radio engineering, 2006. S.623-624.

Claims (1)

An identification system using the frequency feature of a radar station, consisting of a radar interrogator, a radar station, a combined antenna system located on an identifying object, a radar transponder located on an identifiable object, a radar interrogator, consisting of a synchronizer of the interrogator, an encoder-decoder of the interrogator, and a transceiver , frequency-code converter, radar station, consisting of a radar synchronizer a station, a radar transceiver, a pairing device, a single indication system, a radar transponder, consisting of a transponder transponder, a transponder encoder, a decider, a frequency analyzer, a transponder antenna, a frequency analyzer antenna, the outputs of the radar station synchronizer are connected to the radar transceiver , with interface, with a single display system, with the interrogator synchronizer, the outputs of the transceiver are glad the location station is connected to a combined antenna system, to a pairing device, to a frequency-to-code converter, the output of the pairing device is connected to a single display system, the output of the frequency-to-converter converter is connected to the interrogator transceiver, the interrogator's outputs are connected to the frequency-code converter, with the coding the decoding device of the interrogator, with the transceiver of the interrogator, the outputs of the encoder-decoding device are connected to the transceiver of the interrogator, to the interface I, the outputs of the transceiver of the interrogator are connected to a combined antenna system, to the encoder-decoder of the interrogator, the outputs of the combined antenna of the system are connected to the transceiver of the interrogator, to the radar transceiver, through a radio channel from the antenna of the transponder and the antenna of the frequency analyzer, the output of the antenna of the transponder is connected to the transceiver of the transponder, through a radio channel with a combined antenna system, the outputs of the transponder of the transponder are connected to the encoder-decoder of the transponder ICA, with a resolver, with a transponder antenna, the output of the transponder encoder-decoder is connected to the resolver, the transponder synchronizer outputs are connected to the transponder encoder-decoder, with the transponder transceiver, with the resolver, with the frequency analyzer, the output of the frequency analyzer antenna is connected to frequency analyzer, the output of the frequency analyzer is connected to the deciding device, the output of the deciding device is connected to the transceiver of the transponder.