DE19604745C1 - Steered munition deception method for protecting valid targets from laser-guided shells - Google Patents

Abstract

The deception method uses a decoy device (1) with a detector and a radiator positioned at a distance from a target (25) and activated automatically upon detection of the laser beam (21) of the munition guidance system, for providing a decoy laser beam (24') with the same pulse rate as the laser beam (24) reflected from the target and a higher energy level.

Description

The invention relates to a method according to the preamble of claim 1, and an arrangement for performing the method.

Methods for the detection of laser radiation are known, as well Methods and facilities for generation of false and false targets in the IR, radar and optical range.

The St. d. T. does not offer any defense against end-phase-directed, laser-controlled ammunition.

The object of the invention is to provide a method and an arrangement for effective and times deception of ammunition directed to the final phase.  

DE 34 46 464 A1 is a Establishment known for Detection of radiation by laser removal meters for the assessment of land vehicles is sent, indicating a radiation collector that is connected to a detector, and the one direction tion of the rays to be detected.

DE 41 22 354 C1 shows a multispectral false target, comprising at least one the temperature of the object to be protected heatable body and at least two corner reflectors ren, which are adjacent to the heatable body in different are arranged at a distance from the ground.

In DE 40 25 388 C1 becomes a method of creating a false target described, using at least one radiation source for coherent radiation from a conventional holo gram creates a holographic image of the wrong target becomes, or where more than one is more coherent to emission Radiation source provided for reconstruction a holographic image of the wrong target from one virtual hologram is used, the coherent Radiations of the radiation sources in a medium overlaid the refractive index of which is not linear with the intensity depends on the wave fields of the coherent radiations.  

The problem is solved by the characterizing parts of claim 1 and Pa Tent claims 5 specified features.

With the solution, the target object does not need any additional consumption products such as Smoke agent. It is relatively independent of environmental influences and through its own passivity not detectable itself. In addition, quick camouflage is possible.

Advantageous designs are contained in the subclaims.

The local offset between the emitter and the deceiver also realizes the Protection of the deceiver itself.

The inventive method also locates the laser target illuminator how its effective fight possible.

Using an exemplary embodiment with a drawing, the method of deception is intended are explained in more detail.

Show it:

Fig. 1 a stationary embodiment of an arrangement of a deceiver,

Fig. 2 shows a further embodiment of the arrangement of a deceiver onto a bewe constricting target object,

Fig. 3 shows a general structure of the deceiver,

Fig. 4 is a block diagram of the deceiver.

As shown in Fig. 1, a laser target illuminator (LZB) 20 , which illuminates a selected target 25 with an integrated laser, marks the target 25 in a known manner and manner. This marking is received by a phase-controlled ammunition 23 , which was shot, for example, by an artillery gun 22 , via a laser scattering radiation 24 . The recording is made by detectors (not shown) on the ammunition 23 , which record the reflection of the laser radiation 24 reflected from the target 25 (marking). The end-phase-guided ammunition 23 flies towards the illuminated target 25 by self-control in a known manner by means of reflected laser energy 24 . Known end-phase-guided ammunition 23 are aligned via a target seeker head, which is arranged in front of a detector attached to the ammunition 23 . The detector determines the spatial direction of the recorded laser beam 24 , as well as an angle between the laser beam 24 and the missile axis of the ammunition 23 . This is done in such a way that the seeker head with detector detects an area caused by the reflection at the target 25 of approx. 2π (solid angle) after the highest laser energy 24 .

Using this mode of operation of the final-phase guided ammunition 23 , a fool 1 is spatially displaced to the target 25 , preferably with a radiation of <1 sr (radiant interference), for example as a stationary arrangement within a combat unit-vehicle park. Upon receipt of a relevant laser radiation 21 from the laser target illuminator 20 , the deceiver 1 is automatically activated immediately after evaluation of the received signals. For this purpose, it is necessary that the deceiver 1 with a deceptive laser 5 , which is in stand-by mode and in seconds generates a laser beam 24 'corresponding to the received laser signal 21 '. The radiated laser energy 24 'of the shear 1 is substantially greater than the laser energy 24 reflected by the target 25 . Taking further advantage of the mode of operation of the ammunition 23 controlled in the end phase and the fact that a detector evaluation via the detector on the ammunition 23 only checks the highest energy level of the laser scattered radiation 24 , the ammunition 23 changes to the laser beam 24 'after a synchronization time of the deceiver 1 the deceiver 1 . The synchronization time between the laser beam 24 and the laser beam 24 'pulsed by the deceiver 1 is preferably only shifted by 1 pulse. The field of view of the detector of the ammunition 23 is defined via a conventional target search head (not shown) and is so large that the spatial offset between the laser marking on the target 25 and the deceiver 1 is negligible over the distance to the ammunition 23 , and thus always within a detector field (Opening angle 15-60 °), in practice 15-25 ° of ammunition 23 . The ammunition 23 switches on instead of the reflected laser beam 24 on the laser beam 24 'pulsed by the deceiver 1 and flies towards a spatially offset emitter 9 of the deceiver 1 , as a result of which the actual target 25 is missed by several meters. The ammunition 23 is detonated in an approximately detached area.

Since the emitter 9 of the deceiver 1 transmits at a different angle to the ammunition 23 than the reflected laser beam 24 , the trajectory of the ammunition 23 to the target 25 is always changed. The greater the distance from ammunition 23 to target 25 , the further away ammunition 23 is directed from target 25 . The spatial local offset of the radiator 9 of the cheater 1 to the target 25 should not exceed a radius of 100 m in order to ensure an effective cheating effect.

With a flight speed of 300 m / s and a remaining flight time of 15 s, the distance to the destination 25 is 4.5 km, with only 8 s 2.4 km. This means that at a distance of 4.5 km from ammunition 23 to target 25 , the deceiver 1 steers the final-phase-controlled ammunition 23 further away from target 25 than at 2.5 km.

In Fig. 2 the deceiver 1 with spotlight 9 is on a movable target 25 , for example vehicle roof.

The structure of the deceiver 1 is shown in Fig. 3. A detector unit 2 at the target 25 is electrically connected to a subsequent evaluation and control electronics 3 . The evaluation and control unit 3 is connected to the false laser 5 via a cable 4 . Optically connected to the laser 5 and subsequently installed in the deceiver 1 are a coupling optics 6 , an optical fiber 7 , which is located in an elevatable (height-adjustable) mast 8 , for example 3-4 m, and the radiator 9 . In this case, the detector unit 2 is always arranged at the target 25 , while the other assemblies can also be located outside the target 25 .

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

The laser detector 2 with its correspondingly attached individual detectors 2.1 to 2.8 detects the radiation 21 directly incident on the target 25 or the reflected laser scattered radiation 24 of the laser signal 21 emitted by the laser target illuminator 20 . Depending on the local nature in which the target 25 is located, two to three detectors 2 are also sufficient. However, 8 detectors 2 are preferably to be used in order to obtain a usable opening angle of up to 60 °, due to the detector field of the ammunition 23 . The laser signal 21 and / or 24 is hereby converted into an electrical signal and sent to the evaluation and control electronics 3 . In the evaluation and control electronics 3 , the angle to the LZB 20 and the laser pulse code are determined by means of signal analysis 3.1 . Likewise, the wavelength of the laser is analyzed, for example by means of interference. This is important to ensure the correct choice of laser. The determined laser pulse code with Wel lenlänge is passed directly to the deceptive laser 5 , for example NEODYM YAK to this via the cable 4 . The signal analysis 3.1 ensures that the received laser pulse code is equal to the code emitted by the radiator 9 .

This is done by regulating the laser intensity and frequency (pulse train) of the deceptive laser 5 via the evaluation and control unit 3 . This laser energy is coupled via the coupling electronics 6 into the optical fiber 7 and emitted via the emitter 9 as a laser beam 24 'directly to the ammunition 23 , ie direct irradiation of the ammunition 23 by the laser beam 24 ' of the deceiver 1 . The electrical supply of the cheater 1 follows through an electrical input 12 shown in FIG. 4. The internal power supply of the cheater 1 is shown with lines 12.1 and 12.2 . About an additional 11 be marked interface, the connectivity of the deceiver 1 is guaranteed to other devices. Thus, the information from the evaluation and control electronics 3 can be given by means of interface 11 to a tracking system (not shown in more detail) for the automatic control of the, for example, laser target illuminator 20 . For this purpose, the angle range determined from the evaluation and control electronics 3 to the laser target illuminator 20 for determining the solid angle and the maximum shifted radiation angle for the laser beam 24 'is further used as a known variable. By conventional angle decoding conditions and the distance to the laser target illuminator 20 can be determined from the determined angular range. However, the angular range can also be forwarded directly to a vision and information system (not shown in more detail) of the target 25 , where it is recorded, for example, by an optical / electronic system, and sets up the viewing range of this system in the direction indicated.

Claims (7)

1. A method for deceiving a phase-controlled ammunition, which is controlled by a laser guide beam from a reflected or scattered laser radiation, characterized in that a deceiver ( 1 ) consisting of a detector unit ( 2 ) and a radiator ( 9 ) at the target ( 25 ) after the target ( 25 ) has been located by a laser beam ( 21 ) of a laser target illuminator ( 20 ) automatically switches on, this laser beam ( 21 ) receives a laser beam ( 24 ') of higher energy with the same pulse repetition rate and the same wavelength as the reflected laser beam ( 24 ) generates and emits, whereby there must be a spatial distance between the emitter ( 9 ) and the illuminated target ( 25 ). 2. The method according to claim 1, characterized in that the laser beam ( 24 ') of the deceiver ( 1 ) by a maximum of one pulse to the laser beam ( 21 ) of the laser target illuminator ( 20 ) is sent shifted. 3. The method according to claim 1 or 2, characterized in that the reflected laser beam ( 24 ) is also used to generate the laser beam ( 24 '). 4. Arrangement for performing the method according to claim 1, characterized in that a deceiver ( 1 ) consisting of an attached to the target ( 25 ) detector unit ( 2 ) which is electrically connected to an evaluation and control unit ( 3 ) and the outputs of which are arranged directly at a target ( 25 ) via a cable ( 4 ) with a laser ( 5 ), a radiator ( 9 ) of the deceiver ( 1 ) being arranged above or to the side of the target ( 25 ) and the radiator ( 9 ) via an optical fiber ( 7 ) and coupling optics ( 6 ) with the laser ( 5 ) of the deceiver ( 1 ). 5. Arrangement according to claim 4, characterized in that the radiator ( 9 ) of the deceiver ( 1 ) is attached to an elevable mast ( 8 ). 6. Arrangement according to claim 4 or 5, characterized in that the radiator ( 9 ) of the deceiver ( 1 ) is arranged in a radius of 100 m from the target ( 25 ). 7. Arrangement according to one of the preceding claims 4 to 6, characterized in that an interface ( 11 ) for universal connectivity of the deceiver ( 1 ) with the evaluation and control electronics ( 3 ) is electrically connected.