SECONDARY RADAR ABLE TO DETECT TARGETS AT HIGH ELEVATION

Abstract

A radar is equipped with a main antenna having three radiation patterns, sum, difference and control, corresponding to the antenna, the radar comprises an auxiliary antennal device, composed of an antenna and of a rear radiating element which is situated at the rear of the antenna, fixed above the antenna and coupling means, the auxiliary antennal device: having three radiation patterns, sum, difference and control, the control pattern ensured for the direction opposite to the antenna by the rear radiating element; the antenna inclined to guarantee a maximum gain of its sum pattern in the elevational domain (60°-90°).

Claims

1. A secondary radar able to detect a target at high elevation in the silence cone, equipped with a main antenna having three radiation patterns, a sum pattern, a difference pattern and a pattern assigned to a control function, corresponding to the antenna, wherein the radar further comprises: an auxiliary antennal device, composed of an antenna, oriented forwards of the main antenna, and of a rear radiating element situated at the rear of the antenna, fixed above the antenna; and coupling means, the auxiliary antennal device: having three radiation patterns, a sum pattern, a difference pattern and a pattern assigned to a control function, the control pattern being ensured by the rear radiating element; being inclined so as to guarantee a maximum gain of its sum pattern in the elevational domain characterizing the silence cone; the control pattern ensured by the rear element exhibiting at 90° of elevation a gain equal to that of the sum pattern of the antenna of the auxiliary antennal device, and then a maximum gain beyond 90° of elevation, the coupling means ensuring the coupling of the three radiation patterns of the antenna with the three radiation patterns of the auxiliary antennal device.

2. The secondary radar according to claim 1, wherein the antenna of the auxiliary antennal device is of boom type.

3. The secondary radar according to claim 1, wherein the position of the sum pattern of the antenna of the auxiliary antennal device is adjusted in elevation and in gain with respect to the pattern of the main antenna by altering respectively the inclination of the antenna and the coefficient of coupling between these two antennas.

4. The secondary radar according to claim 1, wherein the steepness of the flanks of the sum pattern of the antenna of the auxiliary antennal device is adjusted by altering the number of elevational elements.

5. The secondary radar according to claim 1, wherein the position of the control pattern ensured by the rear element is adjusted in elevation by altering the inclination of the rear element in a vertical plane.

6. The secondary radar according to claim 1, wherein the main antenna is composed of an antenna of LVA type, with wide vertical aperture, and of a rear radiating element.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] Other characteristics and advantages of the invention will become apparent with the aid of the description which follows offered in relation to appended drawings which represent:

[0028] FIG. 1, already described, an exemplary basic pattern of the ATC radar antenna gain;

[0029] FIG. 2, a typical pattern, already described, of relative radiation in elevation of an LVA antenna;

[0030] FIG. 3, an exemplary current architecture of a secondary radar operating in S mode;

[0031] FIG. 4, the structure of the antenna of a radar according to the invention and its coupling to the said radar;

[0032] FIG. 5, an exemplary embodiment of an antenna according to the invention;

[0033] FIG. 6, the typical patterns of absolute radiation in elevation of the antennas making up an antenna according to the invention;

DETAILED DESCRIPTION

[0034] FIG. 3 presents an exemplary current architecture of a secondary surveillance radar operating in S mode, which radar will subsequently be called an SSR radar, conventionally consisting of: [0035] the SSR antenna 1, generally of LVA type, ensuring the radiation of the SSR/S Mode interrogations, at the frequency of 1 030 MHz and the capture of the responses, at the frequency of 1 090 MHz, arising from the transponders aboard aircraft, a standard revolving joint 2 possessing three RF wafers for the three pathways of the L band of the SSR function: the sum pathway Σ, the difference pathway Δ and the control pathway Ω; [0036] a, so-called MSSR, cabinet 3 including in particular two independent systems (just one being represented) ensuring a passive redundancy, each system implementing the various functions dedicated to the SSR/S Mode processing.

[0037] The MSSR cabinet 3 comprises an RF unit 31 for transferring the RF signals of the transmitter 33 to the Σ, Δ, Ω patterns of the antenna 1 and, reciprocally these patterns to the receiver 34. Each cabinet 3 comprises: [0038] spatio-temporal management 32 engendering the interrogations as a function of the tasks to be performed with the predicted targets present in the main lobe; [0039] a transmitter 33 converting into high-power RF signals the interrogations to be radiated by the antenna, at the frequency of 1 030 MHz; [0040] a receiver 34 demodulating the RF signals, at the frequency of 1 090 MHz, that are received by the antenna; [0041] signal processing 35 ensuring the detection and the decoding of the responses received in the main lobe of the antenna; [0042] an extractor 36 forming blips extracted on the basis of the elementary detections (responses), the extractor being a part of an assembly 37 for managing the antenna beam.

[0043] Conventionally, the MSSR cabinet 3 can also include the redundant resources common to the primary and secondary processings, in particular: [0044] the association and the tracking of the primary and secondary blips inside a scan management assembly 38; [0045] the management of the offsets and of the supervision in particular.

[0046] The cabinet also comprises the redundant interfaces 39 with the client links. The ancillary functions allow management of the radar by the client by exhibiting the supervision, the blip offsets and tracks and the parametrizations of the primary PSR, secondary SSR/S Mode and offset functions.

[0047] In S mode mainly the dynamic management of aircraft is controlled by: [0048] the management of the beam 37, as regards the activities related to the azimuthal beam, which are traversed by an arrowed line 30 in FIG. 3 including in particular the spatio-temporal management 32 and the extraction of the blips 36; [0049] the management of the scan 38 as regards the activities related to the antenna revolution which are traversed by an arrowed line 300 in FIG. 3, including in particular the tracking and the prediction of the activities at the next beam scan for each aircraft.

[0050] FIG. 4 presents the structure of the antenna of an ATC radar according to the invention and of its coupling to the radar. Advantageously, according to the invention an adaptation kit is added to the existing architecture of an ATC radar, of the type of the architecture presented by FIG. 3 for example, making it possible to ensure the tracking in the silence cone of all the secondary targets whatever the protocol. More particularly this kit is applied to the aerial. It could be supplemented with a software part applied to the means for extracting the blips 36.

[0051] The kit comprises at least one boom antenna 41 (comprising few elements, typically from 1 to 3 radiating elements height-wise), which may be of small dimension width-wise, for example 2 to 4 metres, a rear radiating element 42 and coupling means 43. The boom antenna 41 is coupled to the SSR antenna 1 (of standard LVA type) on the same existing access ports by the coupling means 43.

[0052] No modification is necessary at the level: [0053] either of the aerial (mechanisms, revolving joint, motor . . . ); [0054] or of the transmission and reception chain.

[0055] The invention is therefore simple and economical to implement.

[0056] FIG. 5 presents, as a supplement to FIG. 4, an exemplary embodiment of the antennal assembly of a radar according to the invention, through a perspective view. This assembly is composed: [0057] of the SSR antenna 1 and of its rear radiating element 12, forming the main antenna; [0058] of the boom antenna 41 and its rear radiating element 42, forming the auxiliary antennal device; [0059] the rear radiating elements 12, 42 being assigned to a control function as will be described subsequently.

[0060] The boom antenna 41 is fixed above the SSR antenna 1, with the same orientation, more precisely oriented forwards of the SSR antenna 1, it is inclined with respect to that of the SSR antenna 1.

[0061] The SSR antenna 1 is conventionally composed of an array of radiating bars 51. This antenna 1, of LVA type, may be a standard antenna of the ATC market for SSR surveillance, operating with three radiation patterns: sum, difference and control.

[0062] A radiating element 12, situated at the rear of the frontal panel consisting of the radiating bars, makes it possible to perform a control function for the SSR mode/S Mode, in particular as regards the geographical situation of the transponders picked up.

[0063] The boom antenna 41 is for example a boom antenna often employed as IFF antenna for military radars therefore possessing the same types of radiation pattern as the main antenna 1 of LVA type: sum, difference and control.

[0064] Preferably it comprises at least two elevational elements so that the zero gain value is close to its main lobe, by causing a steepening of the flanks on either side of the main lobe as illustrated by the sum pattern 63 of the boom antenna 41 presented in FIG. 6, described subsequently. This steepening of the flanks is dependent on the number of elevational antenna elements.

[0065] The antenna 41 is inclined in a vertical plane so as to orient its maximum gain in the silence cone and to guarantee a minimization of its gain both just above 90° of elevation and also below 40°.

[0066] It also comprises a radiating element 42 situated at the rear, dedicated to its control pattern Ω 66 illustrated by FIG. 6, also inclined in elevation, so as to exhibit a maximum gain beyond 90° of elevation. Moreover, the reciprocal inclinations of the boom antenna 41 and of the radiating element 42 are such that their gains are close for 90° of elevation. Thus this makes it possible to block the transponders which are not in the azimuthal direction of the boom antenna 41 and so makes it possible to avoid having parasitic responses in the back of the antenna.

[0067] The coupling means 43 carry out the coupling of the three patterns, sum Σ, difference Δ and control Ω, of the boom antenna, with a coupling coefficient typically equal to 25 dB (to be adjusted according to the value of the maximum gain of the pattern 63 of the sum pathway of the boom antenna 41), with the three patterns, sum Σ, difference Δ and control Ω, of the SSR antenna 1, with the aim of guaranteeing a maximum gain of the sum pattern in the silence cone of the order of 20 dB below the sum gain plateau of the SSR antenna (plateau extending from 20° to 40° of elevation as illustrated by FIG. 6).

[0068] FIG. 6, already cited, illustrates, in a system of axes where the abscissae represent the angles of elevation and the ordinates the absolute antenna gains, the elevational radiation patterns of the antennas described hereinabove for the sum pathway 61 of the SSR antenna 1, for the control pathway 62 of the SSR antenna 1, for the sum pathway 63 of the boom antenna 41, and for the control pathway 66 of the rear radiating element 42 of the auxiliary antennal device.

[0069] As shown by these patterns, an objective is to ensure a minimum gain of the order of 35 to 40 dB below the maximum even at 90° of elevation (aircraft at high elevation necessarily being close together distance-wise, the antenna gain required for their detection is markedly smaller than that for long-range aircraft, typically 35 to 40 dB). This objective is obtained by inclining the boom antenna 41, the effect of this being to translate its elevational patterns, and in particular its sum pattern (translation along the abscissa axis). The value of the coefficient of coupling between the boom antenna 41 and the SSR antenna 1, by altering the gain, makes it possible moreover to adjust the patterns along the ordinate axis. The adjusting of the position of the patterns is thus supplemented by a translation along the ordinate axis.

[0070] The value of the coupling coefficient is thus defined, both: [0071] to avoid pollution of the SSR antenna 1 by the boom antenna 41, i.e. for example more than 25 dB of gain disparity below 40° of elevation: [0072] with very low induced losses transmission-wise and detection-wise; [0073] and almost no beam modification azimuth-wise; [0074] to avoid polluting by “garbling” the close targets at lower elevation below 40° (typical of an airport radar) when detecting targets at high elevation.

[0075] The zone 64 of gain equivalence of the sum pathways between the SSR antenna 1 and the boom antenna 41 is typically situated around 55° of elevation. Beyond this value of elevation, the gain 63 of the boom antenna takes over from the gain 61 of the SSR antenna 1 to ensure the desired minimum gain for the sum pathway up to the zenith. It may be verified that the level transmitted on the pattern of the sum pathway 63 of the boom antenna 41 is much greater than the level of the pattern of the control pathway 62 of the SSR antenna 1 guaranteeing that targets at high elevation of 60° to more than 90° respond to the interrogations of the radar. The control pathway 62 associated with the rear element 12 of the SSR antenna 1 conventionally allows the blocking of the transponders receiving interrogations through the leaks of the sum radiation pattern 61 of the antenna for elevations of 90° to 180°.

[0076] Preferably the sum radiation pattern 63 of the boom antenna must not be too wide so as not to disturb the radiation pattern 61 of the main antenna outside of the silence cone. The control pathway 66 associated with the radiating element 42, situated at the rear of the boom antenna 41, makes it possible to avoid receiving target responses beyond the elevation at 90°, flagged by a dash 65 in FIG. 6. The adjustment of the position elevation-wise of the control pattern 66 with respect to the control pattern 62 of the SSR antenna 1 is made by translation along the abscissa axis, by altering the inclination of the rear radiating element 42.

[0077] The signals transmitted by the radar via the rear element 42 thus allow the blocking of the transponder of a target when the main antenna 1 is in the direction opposite to the azimuth of this target. The radiation pattern and the orientation of this radiating element 42 are adapted for this purpose, in particular an optimal setting ought to make it possible to block the transponder onwards of 91°.

[0078] Around the zone 64 of equivalence of the gains of the sum pathways of the SSR antenna 1 and of the boom antenna 41, the phase-wise uncontrolled recombining of the signals may induce detection losses over a span of the order of +/−5°, i.e. from +50° to +60°, elevation-wise in the example of this FIG. 6. To limit these induced effects, it may be useful to ensure the phasing of the signals transmitted at 1 030 MHz by the two sum patterns 61 and 63.