RU1840870C - Radar transponder beacon - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention is intended for use in a secondary radar system. The transponder beacon includes a three-channel interrogation signal receiver and an interrogation code and interrogator feature decoder connected to said receiver, a response signal former with a transmitter, wherein between the decoder and the response signal former there is a commutator switch for switching response triggering, interrogation pulse counters on each reception channel and each interrogator number, as well as an analyser of the number of interrogation pulses, wherein one input of the commutator switch is connected to the output of the decoder, the output of the commutator switch is connected to inputs of the counters, outputs of the counters are connected to the input of the analyser, the output of which is connected to the input of the response signal former.

EFFECT: enabling mutual orientation in a group of more than two mobile carriers equipped with radar transponder beacons.

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Description

The proposed radar beacon-responder (beacon-responder) is intended for use in a radar system with an active response when placing radar interrogators and beacon-responders on mobile carriers to ensure their mutual orientation during group operations, in particular for use on anti-submarine defense helicopters, when search, tracking and attack of a submarine (PL) by a group of helicopters equipped with equipment for detecting submarines and equipment for mutual orientation, the latter consisting on each carrier s radar and beacon of the respondent. Search, tracking and attack of submarines by a group of helicopters provide for determining the location of submarines with one or two carriers, their mutual orientation with other helicopters of the group and the alternate withdrawal to certain points in space to maintain electromagnetic contact with the submarine and track it, or withdrawal to the point of discharge of weapons.

The accuracy of the mutual orientation, in particular, the determination of the angular coordinates, has a significant effect on the errors of the carrier output to the next point in space and, therefore, on the solution of the general tactical problem.

In radar systems with an active response, the accuracy of determining the angular coordinates of responder beacons in the range of ranges is limited by the presence of side and back lobes of the radiation patterns of the radar interrogators, since when the interrogator approaches the transponder, the latter produces response signals when not only the main lobe of the radiation pattern of the radar the interrogator, but with the side and back lobes, while the exact determination of the angular coordinates of the defendant cannot be ensured without compensation, or query exceptions by the side and back lobes, since the symmetry of the radiation pattern is violated at the energy level of the side and back lobes and a significant error in determining the angular coordinates is possible both due to asymmetry and due to the possible determination of the azimuth from the side or back lobe.

When the interrogator approaches the defendant at a certain range in the opposed device, the interrogator’s main channel receives signal signals from the main and side lobes of the radar antenna pattern, and through the additional channel, due to the difference in sensitivity, only from the main lobe, while response signals generator produces two types of response signals that are emitted by the transmitter of the responder into space and subsequently received by the request indicator chick and are distinguished by its operator, visually highlighting the response signals to the request with the main lobe.

The device has, in our opinion, the following disadvantages:

- it is not possible to accurately determine the angular coordinates of the transponders in a group of more than two carriers equipped with radar and transponder beacons, at ranges at which the transponders are irradiated with side (and back) lobes of the radar antenna patterns, i.e. mutual orientation is not ensured at these ranges, since when the interrogator is working with two or more transponders, the interrogator’s response signals are displayed on the interrogator’s indicator and the main and side lobes of the radar antennas, which makes it very difficult, and can eliminate the ability to visually highlight response signals to queries with the main lobe and determine the angular coordinates of the responders; when the respondent operates with two or more interrogators at these ranges, the response signals are emitted when the transponder is irradiated with both the main and side lobes of all interrogators, i.e. during a time significantly exceeding the time of irradiation with only the main lobe, which significantly reduces the throughput of the defendant, and with an increase in the number of interrogators, it can generally exclude the possibility of answering requests only with the main lobe of the radiation patterns of their radar antennas;

- it is not possible to use automation of the measurement of the coordinates of the defendants to increase the speed and accuracy of their determination during mutual orientation in a group of carriers.

The aim of this proposal is to provide the possibility of mutual orientation in a group of more than two mobile carriers equipped with radar and radar beacons-transponders, in the range of ranges, due to the increased throughput of the defendants and the possibility of using automation of measuring their coordinates to increase speed and accuracy of location, by eliminating in defendants generating responses to requests with sidelobes.

This goal is achieved by automatically switching the start of the response signal generator in the responder beacon from requests through that channel of the request signal receiver through which requests are transmitted only by the main lobe of the radar antenna pattern, implemented by introducing into the structure of the responder beacon containing a three-channel receiver of request signals, moreover, the second and third channels have lower sensitivity than the main channel by 20-30 dB and 40-50 dB, respectively, the decryptor is connected to the receiver codes and attributes of interrogators, a response signal generator and a response transmitter connected to it, the following devices: switch for triggering responses, request pulse counters for each receive channel and each requestor and analyzer for the number of request pulses, with one switch input connected to the decoder output, and one output of the switch is connected to the inputs of the counters, the outputs of all the counters are connected to the input of the analyzer, the output of the analyzer is connected to the second input of the switch, and the second output q switch connected to the input of the driver response signals.

In FIG. 1 is a structural diagram of a transponder beacon.

In FIG. 2 presents graphs explaining the work.

The proposed transponder beacon contains:

- receiver of interrogation signals (CCD) - 1;

- decoder of interrogation codes and attributes of interrogators (ДЗКПЗ) - 2;

- switch switch launch responses (KPZO) - 3;

- request impulse counters (SZI) - 4;

- analyzer of the number of interrogation pulses (AChI) - 5;

- response signal shaper (FOS) - 6;

- transmitter response signals (PIC) - 7.

The operation of such a device is based on the phenomenon of the difference in the number of pulses in the packet of interrogation signals when the defendant is irradiated only with the main lobe of the antenna pattern of the radar of the interrogator from the number of pulses when irradiated with the main and side lobes for a time corresponding to one period of the radar antenna review - for the set values of the antenna review period and the repetition period of the interrogation signals.

In the figure of FIG. 2 on the ordinate axis, the range between the interrogator and the respondent is delayed (decreases down), on the abscissa axis, the number of interrogation pulses in the packet is delayed (increases to the right).

The graph shows the curves characterizing the change in the number of interrogation pulses in the packet irradiating the transponder, and switching reception from more sensitive channels to less. At the maximum detection range of the responder by the interrogator, the number of interrogation pulses in the burst is minimal and is determined by the irradiation of the transponder with only the main beam of the antenna pattern of the radar interrogator (item 8); as the interrogator approaches the transponder, the number of pulses in the packet increases (which is due to the expansion of the main lobe of the radar antenna pattern at lower energy levels and reaches a certain maximum value; with a further approximation, the transponder is irradiated with both main and side lobes, while the number of pulses increases like an avalanche (pos. 9, pos. 10, 11.) The use of this phenomenon is ensured by the presence in the receiver of interrogation signals of three reception channels with different gradations Sensitivity - limiting in the main channel, reduced by 20-30 dB - in the second channel and reduced by 40-50 dB in the third receiving channel.

When the interrogator approaches the responder, the interrogation signals initially pass only through the main channel (pos. 8-9), then after approaching through the main and second channel (pos. 8-10), and with further approximation, through the main, second and third channels reception (pos. 8-11), are decoded and transmitted to the counters for each reception channel and each interrogator separately, the number of interrogation pulses is calculated for a time interval corresponding to one radar antenna survey, the received number is compared with pre-established value criteria the minimum and maximum value of the number corresponding to the respondent’s request only with the main lobe of the radar antenna radiation pattern, and the response can be switched to the request through the receiving channel through which the number of pulses that met the criterion passed in the previous pulse counting interval. The switching points are indicated on the graph pos. 12 - switching point from the main channel to the second channel, and pos. 13 - from the second channel to the third channel.

Description of the operation of the device: interrogation signals received at the input of CCD 1 are converted, amplified, detected, normalized by amplitude and duration, and fed to remote sensing array 2. In remote sensing array 2, the interrogation signals are decoded, while the interrogation signals from different interrogators are separated. The decoded request signals are fed to one of the inputs of the CAML 3, where for each number of the interrogator and for each reception channel they are transmitted to the counters in the SIS 4. The number of request pulses is calculated simultaneously and independently in each reception channel of each interrogator for a time interval corresponding to the period of one review interrogator radar antennas (for all interrogators in this group, the same antenna review periods are set). Counters are reset once during this interval. The resulting number is sent in code form to the AChI 5, where it is compared with the criterion stored in the memory - the numbers corresponding to the minimum and maximum values of the number of pulses in the packet of interrogation signals when the transponder is irradiated with only the main lobe of the antenna pattern of the radar interrogator. After comparing the calculated number of interrogation pulses with the set limits, the AECF gives permission to start the FOS 6 to the second input of the CPSO 3 through the corresponding reception channels. Thus, if the number of request pulses transmitted through the main reception channel in the specified time is less than the maximum allowable value, permission is issued to start FOS 6 through the main channel of CCD 1 for this interrogator. If the number of interrogation pulses transmitted through the main reception channel is greater than the maximum allowable value, the AECI 5 issues the permission to start FOS 6 through the second reception channel and the prohibition to start through the main and third reception channels to the next counting interval; if the number of interrogation pulses transmitted through the second reception channel exceeds the maximum permissible value, AECI 5 issues permission to start FOS 6 through the third reception channel and a ban on starting through the main and second reception channels.

If during the counting period the number of pulses through the third channel turns out to be less than the maximum permissible value, then for the next period of time the corresponding counting time is issued permission to start FOS 6 through a more sensitive receive channel (i.e., the second, etc.).

If during the calculation for the period of the review, the number of request pulses passes through all the reception channels less than the minimum allowable, AChI 5 issues permission to start FOS 6 through the main reception channel, and a ban on starting through the second and third channels.

Request pulses arriving through the CAPO 3 for each requestor on FOS 6, start it, FOS 6 generates a response code and starts POS 7, which generates response radio signals.

Thus, request pulses are counted independently and simultaneously for each channel and each interrogator, and commands are automatically generated to switch the start of FOS 6 through the corresponding receive channel.

The proposed device frees the operator of the interrogator from performing any manual operations to select the main lobe of the radiation pattern, provides the ability to automate the mutual orientation of the media, significantly increases the bandwidth of the response channel at short ranges and provides automatic exclusion of responses to requests by the side and back lobes of the antenna pattern Interrogator radar, the consequence of which is the possibility of increasing speed and accuracy of distribution of the coordinates of the defendants during mutual orientation in the group of mobile carriers, i.e. the achievement of the goal is determined.

The proposed device is implemented in prototypes of the search and sighting system "Octopus", developed in 1970-74, made in 1974. Calculations and simulation results of the device are given in the sketch-technical design of the ROC "Octopus", also protected with a positive rating.

The use of the proposed device when operating mobile carriers equally equipped with radar interrogators and radar beacons transponders allows for the complete automation of solving problems of mutual orientation in a group of up to six or more carriers in the range of 300 m - 30 km with an increase in throughput compared to the opposed device defendants 5-10 times, response times dozens of times, and location accuracy of at least 50%.

Claims (1)

A radar beacon-transponder containing a three-channel receiver of interrogation signals and a decoder of interrogation codes and attributes of interrogators connected to it, a response signal shaper with a transmitter, characterized in that, in order to increase the efficiency of the search-aiming system, a switch switch is installed between the decoder and the response shaper response triggers, request pulse counters for each receive channel and each requestor number, as well as an analyzer of the number of request pulses, with one input the switch is connected to the output of the decoder, the output of the switch is connected to the inputs of the counters, the outputs of all counters are connected to the input of the analyzer, the output of which is connected to the input of the response signal former.

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