FR2732470A1 - Anti=missile countermeasure system for military radar protection - Google Patents

Abstract

The system has a ground radar separate from the radar to protect the radar, searching in the elevation region 40-70 degrees for an anti-Radiation Missile Target. If the target is found, then a missile is launched to intercept the anti-radiation missile. The missile has a radar transmitter (16) and radome to emit signals to mimic the ground radar being protected. The launched missile is designed to intercept the anti-radiation missile, and fire a warhead to destroy it.

Description

OBJECTIVE DEFENSE DEVICE, ESPECIALLY
AGAINST ANTI-RADAR MISSILES
The present invention relates to a defense device against Ics missiles guided by Ic radiation dc the objective to be reached. Such missiles are said to be autoguidagc by passive pursuit or "homing". DC typc missiles are particularly dangerous for radars installed on land or on ships, but can also be used against planes or helicopters with radars. If, for example, the target radar is a short-range radar, rotating for example one turn per second, the anti-radar missile will probably be directed by the secondary lobes of this radar.

 It is known to take various measures to defend these radars.

 The use of anti-missile missiles seems to be the most efficient solution, but also the most difficult to implement and therefore the most storytelling. Indeed, this system requires to detect, track and intercept anti-radar missiles. These missiles can be very powerful with high speeds and accelerations, great possibilities of maneuver and avoidance. Furthermore, the trajectories of anti-radar missiles can vary from the trajectory rasantc at ground or sea level to the vertical trajectory where the missile plunges on the radar. The plunging trajectory presents for an anti-radar missile the advantage on the rasantc trajectory of "seeing" only the radar. A missile having a grazing trajectory "sees" the radar and its image reflected on the ground or on the surfacc of the sea Anti-missile missiles must either be guided from the ground or be able to guide themselves. We can also combine these two techniques.

 The use of electronic countermeasures for example in the form of temporary stop of the radar, misc on the road from another neighboring radar or the flashing of two or more radars is of low effectiveness against sophisticated missiles. Once the radar has been identified, the anti-radar missile keeps its position in memory and in case of extinction of the radar sc directs towards it for example using an inertial unit. countermeasures requires significant resources: means of detection to allow the missile to be identified, including in the shadow zone of the radar to be protected, coordination means, as well as radar redundancy, are necessary.

 The use of known type lures is not very effective against sophisticated missiles. The known type of decoy is a projectile comprising a radar simulator associated with a transmitting antenna. This decoy therefore emits electromagnetic radiation imitating the electromagnetic radiation emitted by the antenna of the radar to be protected. The lure is launched in a direction often close to the perpendicular to the trajectory of the anti-radar missile. Indeed, the decoy having no means of destroying the missile must draw it away from the radar to be protected. A sophisticated missile can detect a significant transverse movement of the target and thus discriminate the real target from the lure.

 The device according to the invention constitutes a safe and relatively easy means to implement to protect radar devices.

 The device according to the invention comprises a projectile fired in the direction of the anti-radar missile. It has an antenna emitting a signal identiquc to the amplitude close to that which would be received from the radar at the location where sc finds the projectile. Thus the missile nc can not distinguish the objective of the projectile sc directed on the projectile whose radiation is higher in level which further comprises means for destroying said missile when the latter is close to it.

The main object of the invention is a device for defending an objective emitting electromagnetic radiation which is rustic in character against missiles guided towards this objective by said electromagnetic radiation, said device comprising means for detecting the direction of the anti-missile. radar, a projectile launched in the direction of said missile, emitting electromagnetic radiation imitating the electromagnetic radiation of the objective to be defended, received at the place where the projectile is located. AT
The invention will be understood by means of the description below and the appended figures given as nonlimiting examples, among which:
- Figure 1 is an overview of a system implementing the invention;
- Figure 2 is a front view of an alternative embodiment of the projectile contained in the spectrum object of the invention;
- Figure 3 is a front view of another alternative embodiment of the projectile contained in the spectrum object of the invention.

 In Figure 1 we can see an example of an anti-radar missile defense system.

 This system includes a target designation device 1 and a shooting device 2.

 As most of the radars to be protected have a shadow cone towards the zenith where there is no detection, the defense system of these radars itself includes a radar 12 comprising an antenna 3. Limitation of coverage relative to the horizontal plane called the site of the radars to be protected generally varies from 400 to 700. The coverage with respect to the vertical 4 of the radar 12 is adapted to the radar to be protected so that any anti-radar missile, whatever its trajectory either detected, either by the radar to be protected, or by the i2 radar. The radar 12 must cover a cone of axis 4 vcrtical ct of half anglc at the apex omax of axis 8, corresponding to the area not covered by the radar to defend. The main lobc 6 of radar 12 detects the position of the anti-radar missile. The lobes 5 and 7 drawn in dotted lines show the extreme positions of the main lob of the radar 12. The main lobe 5 of the radar 12 is in the vertical position. The main lobe 7 of the radar 12 is located at the edge of the radar cover cone 12. Its axis 8 is made with the vertical 4 the angle zamax In the area covered by the radar 12, the latter must be able to track the anti-missile radar in order to identify the threat and ensure that it is the target of the radar. The radar 12 performs the objective designation by giving the distance, the site and the deposit 9.

 Advantageously, the radar 12 comprises such a device is often called monopulse gods planar radar. Advantageously, the antenna 3 emits multiple radar beams, for example ten. Thus, the angular resolution of the radar 12 is improved, while ensuring the coverage of the shadow cone of the radar to be protected. These radar beams are focused for example by dielectric lenses. Another embodiment of the invention comprises a network antenna 3 rotating at deposit. In this case, the radar 12 includes phase shifters ensuring the electronic scanning on site. The elementary beam of the radar is for example 4. Thus the operation of the shadow cone of the radar to be protected by the radar 12 is rapid and gives sufficiently precise information on the anti-radar missile. Advantageously, the movement of the antenna 3 of the radar 12 is synchronized with the movement of the radar to be protected. Likewise, the emission of the electromagnetic signals from these radar gods is synchronized at different frequencies in the same band. Radar 12 has the same spectral and temporal characteristics as the radar to be protected. Thus, when the anti-radar missile locates a target it synchronizes its reception on the time intervals between the electromagnetic signals emitted by the radar. Having the emission of their electromagnetic signals synchronized, the missile indifferently takes the radar gods for target. In addition, this solution facilitates the resolution of the electromagnetic compatibility problems of the two radars. The data processing is carried out by computers 13. An anti-radar missile having been located by the radar 12 or by the radar to be protected, the computer 13 supplies the launching device 2 with a designation of objective, an activation signal of the projectile and its electronics. The launch is carried out in the direction of the anti-radar missile, the computer 13 having set the launcher 14 on the deposit 10 and the site of this missile. The launcher 14 is, for example, a mortar or a rocket launcher mounted on a carriage that can be rotated 360 "and in a site from horizontal to vertical 4. Advantageously, the computer 13 triggers the firing fully automatically.

 In Figure 2 we can see a mortar shell according to the invention. Said shell is intended for the launcher 14 of FIG. I, which in this case is a mortar.

By simulating the radar, this shell is intended to attract and destroy the anti-radar missile. The shell has an envelope 17 extended at the front by a radome 15 protecting a transmitting antenna 16. The antenna 16 transmits signals delivered by a radar simulator 18 towards the anti-radar missile.

 One embodiment of the invention comprises, as a radar simulator, a microwave signal generator controlled by a program adapted to the radar to be simulated and taking into account the movement of the shell. Advantageously, the shell comprises several switchable programs, so as to be able to imitate several types of radar. When the shell is assigned to the defense of a radar, the switching is carried out.

 Another embodiment of the invention illustrated in the same figure, comprises an antenna 21 receiving the electromagnetic radiation coming from the radar 12 of FIG. 1. The radar 12 rotating at the same angular speed as the radar to be protected, the antenna 21, like the antenna of the anti-radar missile, receives the main lobe of this radar only intermittently. The antenna 21 mainly picks up the secondary lobes of the radar 12. In this embodiment of the invention, the element 18 is reduced to an amplifier. By amplifying the signals picked up by the antenna 21 and by re-transmitting them by the antenna 16, it is ensured to obtain radiation identical to that of the radar by understanding the movement of the shell. In addition, this realization simulates any type of radar.

 The gods realizations of simulators generate a signal having the same spectral and temporal characteristics as the signal received from radar 12 at the point where the shell is located. As the shell approaches the anti-radar missile, the average level of emission of electromagnetic radiation from the shell becomes preponderant. Advantageously, the radar 12 and the radar to be protected are switched off for a few seconds after the launch of the shell, for example between 2 and 5 seconds after launch. In order to be able to continue transmitting, the bus comprising the radar simulator with amplifier is provided with electronic means making it possible to generate the signal during the stopping of the radar. We use, for example, devices comprising delay lines and programmed to operate during the period when the radars are stopped. The stopping of the radars facilitates the attachment of the passive seeker of the anti-radar missile on and the shell . The shell emits the same electromagnetic radiation as the radar and comes from the same direction. The passive self-director of this missile, being able to make only angular measurements, cannot differentiate the shell from a real radar. Thus, the anti-radar missile conducts its own interception.

 The anti-radar missile may pass near the shell without touching it. In such a case the anti-radar missile would resume its course towards the radar. To avoid this possibility, the shell is equipped with a device to destroy the missile. In the example illustrated, the shell is provided with an explosive charge 20 and a proximity rocket of the type of those which equip anti-missile missiles. In addition, the shell is equipped with a self-destruction system and orders its destruction after a certain flight time or on command.

 In Figure 3 we can see a rocket according to the invention. Said rocket is intended for the launcher 14 of FIG. 1 which, in this case, is a rocket launcher. The references used correspond to those used in FIG. 2 to designate the same elements.

 The rocket of FIG. 3 is equipped with a thruster 22.

 The principle of the invention is applicable to various types of ammunition, of various calibers. For example, the protection of an airplane against anti-aircraft missiles directed by the electromagnetic radiation of the various electronic equipment of the airplane is advantageously ensured by small caliber rockets.

 Lures fired in the direction of a missile guided by the thermal radiation of the objective and imitating this radiation do not depart from the scope of the present invention.

Claims (10)

CLAIMS I. Device for defending an objective emitting an electromagnetic radiation which is characteristic thereof against missiles guided towards this objective by said electromagnetic radiation, characterized in that said device comprises means for detecting the direction (ll) of the missile anti-radar, a projectile launched in the direction of said missile, emitting electromagnetic radiation imitating the electromagnetic radiation of the objective to be defended, received at the place where the projectile is located.  2. Device according to claim I, characterized in that the projectile launched towards the missile comprises means for the destruction of said missile.  3. Device according to claim I or 2, characterized in that the objective to be protected emitting electromagnetic radiation comprises a radar.  4. Device according to claim 1, 2 or 3, characterized in that said device comprises at least one radar (12) so as to constitute or supplement the radar coverage of the objective to be protected.  5. Device according to any one of claims I to 4, characterized in that said device comprises a computer (13).  6. Device according to any one of claims I to 5, characterized in that the projectile launched towards the missile is a shell.  7. Device according to any one of claims I to 5, characterized in that the projectile launched towards the missile is a rocket.  8. Device according to any one of the preceding claims, characterized in that the electromagnetic radiation emitted by the projectile is generated by a radar simulator (18) comprising a generator controlled by a program adapted to the radar to be simulated.  9. Device according to any one of claims 3 to 7, characterized in that the electromagnetic radiation emitted by the projectile is the radiation of the radar to be protected or of the radar (12) of said device received by an antenna (21) and amplified by an amplifier constituting a radar simulator (18).  10. Device according to claim 9, characterized in that the radar simulator (18) comprises dc storage means provided to maintain the emission of electromagnetic signals by the projectile in absence of the signal from radars.  He. Device according to Claim 10, characterized in that the storage means for maintaining the emission of the electromagnetic signals by the projectile in the absence of the signal coming from the radars comprises rctard lines.  12. Device according to any one of the preceding claims, characterized in that the computer (13) triggers the device according to the invention automatically.