FR2781043A1 - METHOD AND DEVICE FOR JAMMING A GUIDED AMMUNITION IN THE FINAL PHASE - Google Patents

Abstract

The method then uses the operating mode of the munition (23) with final phase guidance, mode for which the munition (23) with final phase guidance only detects the maximum reflected laser energy (24). It is directed by means of a jammer (3) mounted on the target (25), with a laser (24 ') on a new flight path towards the target (25). This is done by the fact that the laser beam (24 ') is, in its succession of pulses and as well as in its wavelength, identical to a laser beam (21) having been emitted by a target laser illuminator (20), however by having a higher energy level. Thanks to the deviation of the munition (23) which adopts a new flight path, the ammunition (23) will pass off the target (25).

Description

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METHOD AND DEVICE FOR INTERFERING A
GUIDED AMMUNITION IN THE FINAL PHASE
The invention relates to a method of jamming a munition with final phase guidance, controlled by a laser guide ray coming from a laser radiation coming from a reflection or from a dispersion by the target, as well as a device of implementation of the method.

 Methods are known for attenuating the behavior on reflection by means of camouflage paint applied to target objects.

 Thus, DE-B 43 27 976 Cl describes a reflecting mass intended to produce an apparent target. Here, a missile looking for a target, sensitive to radiation, is deflected from an object to be protected, by means of a prepared dummy target which is coated with a reflective mass. However, in addition to the inflexibility of the process, that is to say that each target has an apparent target added to it, it is disadvantageous that, in general, when using a coating or camouflage paint, the reflectivity, especially on wet surfaces, is very high.

 Deployable camouflage devices are also known, as described in DE-A 41 19 U30 A1. They suppose to have a locally fixed site and only admit a local modification of the site at the cost of a high expense or complexity (assembly and disassembly).

 Another method of attenuating the behavior in reflection, this using nebulizing means, is indicated by DE-B 33 26 884 C2. The target object is then masked by smoke or fog, the emission of infrared radiation being prevented, so that the target object is undetectable for a sensor. It is disadvantageous that the use of nebulizing or smoke-producing means is often carried out at a time temporally too late to obtain a sufficient effect. The number of nebulizing means is

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 also limited in one vehicle. During use, these means also strongly depend on environmental conditions and can further reveal the proper position.

 The object of the invention is to indicate a method and a device for obtaining an effective and simpler camouflage of target objects, in the face of munitions directed in the final phase.

 This problem is solved by the fact: - that a jammer is automatically put into service on the target, after localization of the target by means of a laser beam belonging to a target laser illuminator, picks up this laser beam, generates a beam higher energy laser having the same pulse repetition rate and emits it directly on the ammunition, the ammunition being directed by the spatial offset of the jammer, to adopt another flight path towards the target targeted by the radiation.

- that the radiating emitter of the jammer is mounted on a lifting mast
Thanks to the solution found, the target object does not require any additional consumable product, such as nebulizing means. It is relatively independent of environmental influences and cannot be detected by its own passivity. In addition, it is possible to put on camouflage in a time-rapid manner.

 Advantageous embodiments are characterized by the fact that: the jammer laser beam is emitted with a maximum offset of one pulse relative to the laser beam of the target laser illuminator.

 - the jammer transmitter has a jamming effect on the ammunition, within the limits of a circle up to a radius of 100 m around the target.

 - the reflected laser beam is also used in order to generate the laser beam.

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 - jammer consisting of a detector unit fixed on the target and electrically connected to an evaluation and control unit, and at its outputs, via a cable, to a laser, is placed directly on a target , a radiating emitter of the jammer being arranged above or on the side of the target and the radiating emitter being connected to the laser of the jammer via a light guide fiber as well as a coupling optic.

 - the radiating emitter of the jammer is placed within the limits of a circle of 10 U m relative to the target.

- the link is established with the evaluation and control unit electrically connected via an interface, intended to allow a possibility of universal connection of the jammer
The local offset that there is between the radiating transmitter and the jammer then also generates protection for the jammer itself. Thanks to the method according to the invention, it is just as possible to localize the target laser illuminator, and thus to combat it effectively.

 The scrambling process will be explained in more detail below, using an embodiment shown in the drawing.

 In the drawing: Figure 1 shows a stationary embodiment of an arrangement of a jammer, Figure 2 shows another embodiment of the arrangement of a jammer on a moving target object, Figure 3 represents a general structure of the jammer, FIG. 4 represents a block diagram of the jammer.

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 As shown in the figure, the target 25 is marked, in a known manner, by means of a target laser illuminator (LZB) 20, which illuminates a target 25 selected by the radiation of an integrated laser. This marking is recorded by a munition 23 with final phase guidance which has been fired for example from an artillery mount 22, the recording being made by means of the laser scattering radiation 24. The recording is carried out by means of detectors, not shown in detail, mounted on the munition 23, which capture the reflection of the laser radiation 24 (marking) having been reflected by the targets 25. The munition 23 with final phase guidance flies by self-control in a known manner, by means of reflected laser energy 24, pointing towards the target 25 illuminated by the radiation. Known phase 23 guided munitions as described in DE-B-29 18 858 are equipped with a target finder head placed in front of a detector fixed on the ammunition 23. The detector then determines the spatial orientation of the laser beam 24 sensed as well as the angle between the laser beam 24 and the axis of the missile of the ammunition 23. This is done so that the target search head comprising the detector, detects according to the reflection on the target 25, an area about 2 # Sr (solid angle), this based on the maximum of the laser energy 24.

 By using this operating mode of the munition 23 with final phase guidance, a jammer 1 is spatially offset on the target 25, with ISr (steradian) radiation, for example as a stationary device inside a park. vehicles or a motor vehicle-combat unit.

When receiving significant laser radiation 21 from the target illuminator 20, there is immediately activation of the jammer 1 automatically according to the evaluation of the signals received.

It is then necessary for the jammer 1 to produce using a jamming laser 5 in the standby state and

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 with a rapidity of a few seconds, a laser beam 24 ′ pulsating in a manner corresponding to the laser signal 21 received or received. The laser energy 24 'radiated from the jammer 1 is then notably greater than the laser energy 24 having been reflected by the target 25. By using still more the operating mode of the munition 23 with final phase guidance and by using the fact that an evaluation by detector concerning the detector mounted on the ammunition 23 only controls the maximum level of energy of the scattered laser radiation 24, a change is generated after a time of synchronization of the jammer 1, this change causing the ammunition 23 on the laser beam 24 'of the jammer 1. The synchronization time between the laser beam 24 and the laser beam 24' pulsed by the jammer 1 is then preferably only shifted by one pulse. The range of visual range of the ammunition detector 23 is defined by means of a conventional target finder head, not shown in detail, and is so large that the spatial offset between the laser marking on the target 25 and the jammer 1 is negligible compared to the distance of the ammunition 23 and is always located within the limits of a detector field (opening angle of 15 to 60), in practice from 15 to 25, of the ammunition 23. The ammunition 23, instead of being oriented on the reflected laser beam 24, will switch to pass on the laser beam 24 'pulsed by the jammer 1 and flies on a radiating transmitter 9, spatially offset from the jammer 1, causing the target 25 proper is missed, by several meters. The detonation of the ammunition 23 takes place only in an area where there is no risk.

 Because the radiating emitter 9 of the jammer 1 emits at a different angle to the ammunition 23 than the reflected laser beam 24, there is always a change in the flight path of the ammunition 23 towards the target 25. Larger is here

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 distance between the ammunition and the target 25, the greater the distance between the ammunition 23 and the target 25 will be large. The local spatial offset of the radiating transmitter 9 of the jammer 1, relative to the target 25, should not exceed the limits of a circle of radius 100 m to ensure an effective jamming effect.

 For a flight speed of 300 m / s and a remaining flight time of 15 s, the distance from the target 25 is 4.25 km, whereas, if this time is 8 s, it is no more than 2.4 km, this means that the jammer 1, when the distance is 4.5 km between the ammunition 23 and the target 25 will deflect the munition 23 with guidance in the final phase over a greater distance vis-à-vis the target 25 than what occurs for a spacing of 2.5 km.

 The jammer 1 with the radiating transmitter 9 is located in FIG. 2 on a moving target 25, for example, the roof of a vehicle.

 The structure of the jammer 1 is shown in FIG. 3. A detector unit 2, mounted on the target 25, is electrically connected to an evaluation and control electronics 3 placed downstream. Via a cable, the evaluation and control unit 3 and the scrambling laser 5 are connected by connecting them. Optically connected to the laser 5 and thereafter in the scrambler 1, there are installed a coupling optic b, a light guide fiber 7 which is in a liftable mast 8 (adjustable in height), with a range for example of 3 to 4 m, as well as the radiating emitter. The detector unit 2 is always placed on the target 25 while the other components can also be outside of this target 25.

 The mode of operation of the jammer 1 is shown in FIG. 4.

 Starting from the laser detector 2, equipped with its individual detectors 2.1 to 2.8 mounted in a corresponding manner, the radiation 21 arriving directly

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 on the target 25, or else the scattered laser radiation 24 having been reflected from the laser signal 21 emitted by the target laser illuminator 20 is detected. Depending on the local conditions in which the local target is located, it is sufficient to have 2 to 3 detectors 2.

Preferably, however, 8 detectors 2 are used to obtain a usable opening angle of up to 60, this coming from the detector field of the ammunition 23. The laser signal 21 and / or 24 is here converted into an electrical signal and supplied to the evaluation and control electronics 3. The angle to the LZB 20 and the laser pulse code are determined in the evaluation and control electronics 3 by means of signal analysis 3 .at.

Also the wavelength of the laser is analyzed, for example, by interference. This is important to ensure the correct choice of laser. The laser pulse code having been determined, along with the wavelength, is retransmitted directly to the control of the jamming laser 5, for example a NEODYM YAK device, to the latter, via the cable 4. It is assured by means of signal analysis 3. 1 that the laser pulse code received is identical to the code transmitted by the radiating transmitter 9.

 This is done by the fact that the intensity of the laser frequency (succession of pulses) of the scrambling laser 5 is regulated by means of the evaluation and control unit 3. This laser energy is coupled by via the coupling electronics 6 in the light guide target 7 and is emitted via the radiating emitter 9, as a laser beam 24 ′, directly to the ammunition 23, that is i.e. by direct irradiation of the ammunition 23 with the laser beam 24 ′ of the jammer 1.

By an electrical input 12 indicated in FIG. 4, the electrical supply of the jammer 1 is ensured.

There are shown by lines 12. 1 and 12.2 the internal electrical supply of the jammer 1. It is provided, via an interface

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 additional designated by 11, a possibility of connection of the jammer 1 to other devices.

Thus, the information coming from the evaluation and control electronics 3 can be supplied by means of the interface 11 to a monitoring system, not shown in detail, intended to ensure automatic combat of, for example, the target laser illuminator 20. To this end, the angular range determined from the evaluation and control electronics 3, relative to the target laser illuminator 20, is also used as a known quantity to determine the spatial angle and the radiation angle being offset as much as possible for the laser beam 24 '. By conventional angular decoding from the determined angular range., The angle and the distance from the laser target illuminator 20 are determined. The angular range can also be transmitted directly to a sighting system. and information, not shown in detail, of the target 25 where, for example, elte is recorded by an optical / electronic system and the range of visual range of this system being aligned with the indicated direction.

Claims (7)

1. - Method of jamming a munition with guidance in the final phase, controlled by a laser guide ray coming from a laser radiation coming from a reflection or from a dispersion by the target, characterized in that a jammer (1) activates automatically on the target (25), after locating the target (25) by means of a laser beam (21) belonging to a target laser illuminator (20), picks up this laser beam (21 ), generates a laser beam (24 ') of greater energy having the same pulse repetition rate and emits it directly on the ammunition (23), the ammunition (23) being directed by the spatial offset of the jammer ( 1), to adopt another flight path towards the target (41) targeted by the radiation.  2.- Method according to claim 1, characterized in that the laser beam (24 ') of jammer (1) is emitted with a maximum offset of one pulse with respect to the laser beam (21) of the laser illuminator of target (20).  3. - Method according to claim 1 or claim 2, characterized in that the transmitter (9) of the jammer (1) exerts a jamming effect on the ammunition (23), within the limits of a circle up to at a radius of] OR m around the target (25).  4.- Method according to any one of claims 1 to 3, characterized in that one also uses the laser beam (24) reflected in order to generate the laser beam (24 ').  5. - Device for implementing the method according to claim 1, characterized in that a jammer (1) consisting of a detector unit (2) fixed on the target (25) and electrically connected to a unit evaluation and control (3), and at its outputs, via a cable (4), to a laser (5), is disposed directly on a target (25), a radiating emitter (9) of the jammer (1) being <Desc / Clms Page number 10>  disposed above or on the side of the target (25) and the radiating emitter (9) being connected to the laser (5) of the jammer (1) via a light guide fiber (7) thus than a coupling optic (6). b. - Device according to claim 5, characterized in that the radiating emitter of the jammer (1) is mounted bur a mast (8) liftable.  7. - Device according to claim 5 or 6, characterized in that the radiating transmitter (9) of the jammer (1) is arranged within the limits of a circle of 100 m around the target (25).  8. - Device according to any one of claims 5 to 7 cited, characterized in that the connection is established to the evaluation and control unit (3) electrically connected via an interface (11) , intended to allow a possibility of universal connection of the jammer (1).