DE102004040218A1 - Proximity sensor device for firing warhead of defense missile against approaching projectile, has detector with detection area for recording projectile, such that area is further limited, and distance sensor controlling firing of warhead - Google Patents

Abstract

The device has a detector comprising a hollow-cone-shaped detection area (14) for recording an approaching projectile (12), such that the area is further limited. A distance sensor is provided for controlling firing of a warhead of a defense missile based on the distance between the defense missile and the approaching projectile. An emission device is provided for transmitting a radiation (16) in spectral range of the detector.

Description

The The invention relates to a proximity sensor arrangement, especially for the triggering of the Warhead of a defense missile against an approaching projectile according to the preamble of the claim 1.

Such a proximity sensor arrangement is used in an active defense system, in which, for example, from an attacked object an attacking projectile, for example, according to US-A-5,661,254 a defensive grenade with splinter warhead or according to US-B-6,244,156 a defensive grenade with Blast warhead is shot against. The attacker may be a missile fired projectile (projectile) or a self propelled projectile (missile). Such a scenario is exemplary in the DE 196 01 756 C1 outlined. As shown there, it is not realistic to expect a collision between the attacking projectile and the defense missile. Therefore, the warhead of the defense missile must be detonated immediately before the flyby, because then for its fragmentation or blast effect just the optimal encounter situation relative to the attacking projectile results.

For the distance release against Air targets are for example Radarzünder in use. Their club-shaped detection characteristic but leads in the illustrated passage situation not to a clear and reproducible ignition information. At Radarzündern another major disadvantage is that that this prefers an attacking projectile in the direction of coaxial capture in advance and thus the ignition of the Warhead in a approach situation effect, in terms of distance and for the radially oriented effect of the defense warhead is extremely unfavorable.

Out DE-OS 25 27 368 is therefore an approach sensor with a hollow cone-shaped detection area for detecting an approaching projectile known, so that the triggering of the warhead of the defense missile better on the main radially oriented effect of the warhead is tuned. Around the opening angle, in which the splinters of the active charge scatter, to keep small and in order to increase the splinter density, the elevation angle becomes the detection range of the proximity sensor dependent on of the speed of encounter between the attacking projectile and the defense missile changed. The encounter speed is about an additional Doppler radar device in the Tip of the defense missile detected. The change of the Elevation angle can, for example, by means of several consecutive arranged photodiodes with a common Torroidlinse behind the effective charge can be achieved.

Further FR-A-1,464,783 describes an infrared proximity sensor with at least two conical Detection areas with different opening angles, wherein the ignition of the Warhead only with simultaneous capture of a target object done by both detection areas. By this measure should prevents the warhead mistakenly by a background radiation triggered becomes.

Also US-A-4,185,560 discloses a proximity sensor having two cone-shaped detection areas with different opening angles. In this case, the two detection areas but the Task solved become, target objects of different sizes equally effective to fight. This is achieved in that the first detection area with the smaller opening angle a flying projectile first detected and at the end of the received signal an ignition signal Spends while the second detection area with the larger opening angle an approaching Projectile later detected and the ignition signal with a certain delay after the beginning of the received signal. In the case of a big approaching Projectile is the end of the received signal of the first detection area at the expiration of the delay for the ignition signal of the second detection range has not yet been reached, which is why ignition signal according to the second Detection area after expiration of the delay after the start of the received signal is produced. In the case of a smaller approaching projectile, the End of the received signal of the first detection range already before Expiration of the delay for the ignition signal reaches the second detection range, so that the ignition signal according to the first detection area is generated at the end of the received signal.

outgoing from the above-described prior art is the invention the task is based, a proximity sensor arrangement for the ignition of the Warhead of a defense missile against an approaching projectile with a detector device, a detector with a hollow cone-shaped detection area for Detecting the approaching projectile in such a way that the detection range of the detector device is further limited, to the immunity of the Proximity sensor arrangement continue to increase.

These The object is achieved by a Proximity sensor arrangement solved with the features of claim 1. Preferred training or further education the inventive arrangement are Subject of the dependent Claims.

The Proximity sensor arrangement especially for the triggering of the Warhead of a defense missile against an approaching projectile, with a detector device, a detector with a hollow cone-shaped detection area for Detecting an approaching projectile, thereafter further a distance sensors on to the ignition of the warhead of a Defense missile dependent on from the distance between the defense missile and that through the detector device controlled approaching approaching projectile.

By the combination of the crescent-shaped Detection range and the distance sensor is achieved that the triggering of the Warhead of the defense missile on the mainly radial oriented effect of the warhead is tuned and only at a flyby of an approaching projectile within a radius of effect of Warhead takes place.

By the combination according to the invention can the sensitivity of the proximity sensor environmental disturbances be greatly reduced because detected objects only within one predetermined radius of the defense missile classified as a target become, whereby Cluttereinflüsse and false targets are filtered out.

The Distance sensor system of the proximity sensor arrangement can with an emission device for emitting radiation in the spectral range of detectable by the detector of the detector device Radiation be equipped. The radiation is thereby from the emission device having a main direction of propagation in the direction of flight of the defense missile, so that the radiation cone emitted by the emission device Radiation cuts the detection area of the detector device. The detection range of the detector device is thus determined by the Radiation cone of the emission device limited in the radial direction, causing, for example, highly reflective false targets outside this radius is suppressed become.

In a preferred embodiment The invention is the emitted from the emission device Radiation modulates, and the detector device performs a Cross correlation between the modulation of the emission device emitted radiation and by the detector of the detector device detected received signal, whereby extraneous radiation is further suppressed.

advantageously, is this radiation emitted by the emission device with a pseudo random noise signal modulated. Due to the cross-correlation, i. the maturity valuation the received signal can be the distance of the approaching projectile be captured, so the delay the triggering of the Warhead can be variably adjusted to the detected distance, while Objects that are too big Have distance from the radiation transmitter, rated as false targets or as Cluttereinflüsse can be.

to Realization of the hollow conical Detection area, the detector of the detector device preferably a detector element which in the image focussing plane behind a Cylinder lens with convex input and output end faces or one Immersion lens is arranged, through which an inclined towards the System axis entering parallel beam on a near-edge output range concentrated and images on the detector element.

The Detector element of the detector of the detector device is preferred annular trained or arranged. In the case of rotating around the system axis Defense missile the detector element may consist only of individual elements, the are arranged on a circular ring.

It can also several pixels of a receiver array selected in this way they will approximated form a ring structure, whereby the hollow cone-shaped characteristic in several Segments is divided. As a result, in a further embodiment invention, the detector device with two detectors to each other include parallel detection areas, bringing the relative speed between the defense missile and the approaching projectile can be determined so that the ignition of the Warhead of the defense missile dependent on can be controlled by the detected relative speed. In addition, can from the speed information to a valid destination or to a false destination getting closed. Because at valid Targets, the measurable differential speed is much higher than the mean intrinsic speed of the defense grenade, since yes the effective speed of your own and of the speed of the oncoming Angrei fers results. For the not so approaching false targets on the other hand, the speed measured on board is largely consistent with the mean intrinsic speed of the defense grenade.

On the other hand, on the apparative Auf wall for a triangulation to limit the detection range by installing a directionally emitting transmitter on board the defensive grenade or by irradiation from the object to be protected from omitted if according to a preferred embodiment of the present invention, the detector of the detector device comprises a detector element, out of itself also already provides information about the distances of detected objects. This may be a conventional active or retro-beam location system, or in particular a so-called small-sized PMD element (photonic mixer device or photonic mixer device) or an apparatus alternative thereto. Such a (PMD) detector element integrates the correlation function between transmit and receive signal by means of CMOS technology, so that separate expensive and large additional circuits for the evaluation of the received signal omitted. The PMD technology was developed by Prof. Dr.-Ing. R. Schwarte developed at the University of Siegen, and their basic concept and their functioning are, for example, in the DE 197 04 496 C2 explained in detail.

Further Details, features and advantages of the explained two implementation variants result from the following description of preferred embodiments a proximity sensor arrangement the invention. Show it:

1 a schematic illustration for explaining the principle of the present invention when applying a triangulation for limiting the radial detection range of the Abwehrfugkörper from;

2 a simplified block diagram of a proximity sensor arrangement for illustrating the principle of 1 according to a preferred embodiment of the invention;

3 a schematic representation for explaining a modification of the basic principle of 1 ; and

4 a schematic representation of the structure of a preferred embodiment of a detector for a proximity sensor arrangement according to the invention.

Based on 1 First, the principle underlying the present invention, a proximity sensor arrangement on board a defense grenade or other defense missile 10 explained against an approaching threat. The schematic diagram in 1 is not to scale, especially the elevation angle of the detection area 14 and the radiation cone 16 to the system axis 20 not on the in 1 limited angle shown.

The proximity sensor assembly typically becomes in the defense missile 10 to ward off approaching projectiles 12 , such as projectiles or missiles used. The defense missile 10 generally contains a warhead with a splinter or blast active charge, an igniter for igniting the active charge and a detector device for controlling or triggering the igniter of the active charge. Since the approach sensor arrangement of the present invention is basically not limited to a specific structure of the defense missile, but rather is generally applicable, will be omitted at this point to a more detailed explanation of the defense missile.

The proximity sensor arrangement of the invention comprises a detector device with a detector having a hollow cone-shaped detection area 14 has. Furthermore, the proximity sensor arrangement includes a distance sensor, which is an emission device for emitting a radiation cone 16 whose main direction of propagation in the direction of flight 18 of the defense missile 10 or in the direction of the system axis 20 of the defense missile 10 is oriented. The wavelength of the radiation emitted by the emission device 16 corresponds to the spectral range of the detectable by the detector of the detector device radiation.

As from the triangulation relations in 1 to recognize, in this implementation variant, the radiation source for the cone 16 and the detector for the hollow cone 14 with from the cone 16 deviating and in particular larger cone angle in the axial direction 18 - 20 offset from each other, wherein the detection characteristic 14 in the direction of flight 18 in front of the transmission cone 16 is initiated. This is how the radiation cone cuts 16 the detection area 14 , and at this distance is thereby the detection area 14 in the radial direction to the system axis 20 limited. In this way it is ensured that of the detector of the detector device only signals from target objects within a predetermined distance from the defense missile 10 be recorded. Thus, an unnecessary ignition of the warhead at too large a distance between an approaching projectile 12 and the warhead of the defense missile 10 be avoided. In addition, the sensitivity of the proximity sensor to environmental disturbances is severely limited because received signals are detected only within a predetermined radius, ie background noise is filtered out.

While in 1 the radiation 16 from the rear of the defense missile 10 goes out, ie the emission device of the distance sensor on the defense missile 10 is provided, it is also possible for the distance determination according to the triangulation method, the emission sensor of the distance sensor on the launcher (not shown) of the defense missile 10 provided. It must be known only for the cross-correlation, the current transmission frequency. This can be done by the defense missile 10 from by means of a backward, so directed towards his thrower sensor recorded by the launcher currently used modulation. In addition, the time offset must be taken into account, which in external irradiation by the duration of the launcher of the defense missile to the launched defense missile 10 occurs. Finally, for the correct target distance the throw distance should be measured.

In 2 is a block diagram of the circuitry of a preferred embodiment of a proximity sensor array of 1 illustrated. In particular, the proximity sensor arrangement comprises the detector device and the distance sensor system. The detector device is of a detector 22 and a control section 24 built up. The detector 22 contains in particular a detector element 26 and an optical system connected thereto, which may for example comprise different lenses and filters. The distance sensor includes the already mentioned emission device 30 and the control section 24 which may be formed as a common control section with the detector device when the emission device 30 on the defense missile 10 is arranged. The wavelength of the emission device 30 emitted radiation 16 is tuned to the spectral range of the detector 22 the detector device can be detected, and is preferably selected in the infrared range.

The control section 24 contains in particular a signal generator 32 for driving the emission device 30 and a signal processor 34 to evaluate the from the detector 22 detected received signal. To get off the detector 22 is detected by the emission device 30 emitted radiation from the signal generator 32 preferably modulated, while the receiving side adapted band-pass filtering takes place. This modulation of the signal generator 32 will also be the signal processor 34 fed.

In the preferred embodiment of the invention, which in 2 not only becomes the detection area 14 the detector device is limited, but it is also the distance between the approaching projectile 12 and the defense missile 10 measured. This is done by the modulation of the emission of the device 30 emitted radiation 16 by means of the signal generator 32 , preferably in the form of an intensity modulation with a pseudo random noise. That of the detector 22 detected receive signal is then in the control section 24 the detector device in a known manner with the pseudo random noise of the signal generator 32 cross-correlated to the duration of the signal and from it the distance of the approaching projectile 12 to determine. The signal processor 34 then causes a delay in the firing of the warhead, the variable to the specific distance of the approaching projectile 12 is adjusted.

A modification of the basic approach sensor arrangement of 1 is in 3 illustrated. Unlike the construction of 1 contains the detector device of the proximity sensor arrangement of in 3 shown embodiment, two detectors with two different hollow cone-shaped detection areas 14a . 14b , which are concentric and preferably approximately parallel to each other. By means of these two successively arranged detection areas 14a . 14b it is possible to measure the passage or relative velocity between the approaching projectile 12 and the defense missile 10 to determine. With this proximity sensor arrangement, the delay of the triggering of the warhead of the defense missile 10 be adapted to the thus determined relative speed in order to achieve an optimum ignition timing for the effect of the warhead. Above all, this speed measurement opens on board the defense projectile 10 other very effective ways of clutter suppression using speed classifications.

The in 4 represented detector 22 as it can be used in the above-described proximity sensor assemblies of the invention is the subject of the earlier application DE 102 07 923.4 the applicant.

The detector 22 consists essentially of an annular detector element 26 , which is coaxial with the system axis 20 behind a long cylinder lens 36 is held. The detector element 26 can be constructed of individual arranged on a circular ring elements, if the defense missile 10 one around the system axis 20 is rotating anti-aircraft missile. At the cylinder lens 36 lies a convex entrance end face 38 a likewise convex output end face 40 which does not necessarily have to have the same curvature, axially opposite. Instead of in 4 illustrated cylindrical lens 36 Optionally, an immersion lens can also be used.

A parallel beam 42 , inclined to the system axis 20 through the convex entrance end face 38 in the cylinder lens 36 enters, becomes the system axis 20 broken down and on a dependent of the angle of incidence small near-edge outlet area in the convex output end face 40 focused, with the focus slightly behind the exit end face 40 lies. In this focus is the detector element 26 in a protective housing 44 behind a window 46 arranged. As the detector element 26 only the edge region corresponding to a certain angle of incidence of the beam 42 ie a certain hollow cone-shaped detection area 14 should capture, it is preferably formed annular disc-shaped with a corresponding diameter and corresponding ring width. Optionally, the detector element 26 also disc-shaped and be centrally covered to respond only to the free ring zone. As mentioned above, the detector element 26 in the case of one around the system axis 20 rotating defense missile 10 consist only of individual, annularly arranged elements. For more details on the in 4 illustrated construction of the detector 22 will be here for the sake of brevity, at the point already mentioned DE 102 07 923.4 directed.

In summary, with respect to the present invention, with the limitation of the detection distance, it can thus be established that the approaching projectile 12 upon entry into the hollow truncated wall detection area 14 one on the defense missile 10 provided detector 22 by igniting the warhead in the defense missile 10 is being fought. The detection area 14 results in a space-flying anti-aircraft missile 10 by incorporating a detector ring in the form of an annular detector element or in the form of a sequence of individual detector elements on a circle, with a corresponding inclination of the detector elements with respect to the axis of flight 18 anticipated according to 1 / 3 , or parallel to the axis of the aircraft 18 ahead oriented behind a cylindrical lens 36 according to 4 , At one around the axis 18 rotating defense missile 10 results in its rotational movement because of the detection area 14 already by a single detector element. For a speed discrimination, around the detector 22 only to be addressed in encounter situations that are much faster than the movement of the defense missile 10 over ground (and thus also against the solar radiation), can do two in the direction of flight 18 mutually offset detection areas 14 ( 14a and 14b in 3 ) be provided. The triggering of the warhead to ward off the projectile 12 is then dependent on the penetration of the projectile 12 in the two detection areas located one behind the other 14 occurs due to the system typical speed of encounter in at least one predetermined rapid sequence.

For a distance discrimination to limit the triggering distance to hide background effects and in the interest of the defense effect of the warhead, so can be provided by the triangulation method, with the defined hollow cone-shaped detection area 14 from the defense missile 10 from or from the launcher of a radiation cone 16 defined, such opening angle to intersect that the detector 22 only appeals when the approaching projectile 12 in the sufficiently close intersection of the detection area 14 and radiation cone 16 is detected and has a reflective effect. Considerably simpler in terms of apparatus and therefore preferable in the context of this invention is the distance discrimination without the requirement of a separate radiation cone ( 16 in 1 / 3 ) for such a triangulation via radiation emitter, target reflector and radiation receiver, in accordance with installation conditions in accordance with 1 / 3 or according to 4 an active detector 22 is used with PMD function, so with run-time-dependent modulation of the reflected after projectile to be defended 12 from the detector 22 resumed radiation. So while after the in 2 illustrated embodiment, the cross-correlation of the received signal of the detector 22 with the modulation of the radiation 16 the emission device 30 through the control section 24 takes place, is more advantageous apparatus since da kleinbauender as a detector element 26 of the detector 22 the detector device, so for clamping at least one detection area 14 a PMD (Photonic Mixer Device or Photomischdetektor) - detector element is used, which also directly a distance information to the reflecting object (the attacker to be defended 12 ). By evaluating this distance information, the detection range can therefore be limited without triangulation measures for the purpose of clutter suppression. The PMD integrates the phase correlation function between transmit and receive signal by means of CMOS technology in the detector element, so that separate expensive and space-consuming radiation transmitter and additional circuits for the evaluation of these reflection signals omitted. Regarding the structure and the functioning of a PMD is the sake of brevity on the DE 197 04 496 C2 directed. The detector element 26 in 4 is therefore preferably a PMD detector element; or a commercially available PMD array, wherein only the necessary, lying on about a ring elements of the array are used for the evaluation. In this way, for which independent protection is claimed, the positions and mutual distances of the rings and their diameter can be optimally adjusted by software in terms of the target.

10

Defense missiles

12

anfliegendes projectile

14

detection range

16

radiation the emission device

18

Direction of flight from 10

20

System axis of 10

22

detector

24

control section

26

Detector element e.g. PMD

28

optics

30

emitting device

32

signal generator

34

signal processor

36

cylindrical lens

38

convex entry end face of 36

40

convex output end face of 36

42

parallel ray beam

44

housing

46

window

Claims (11)

Proximity sensor arrangement, in particular for the triggering of the warhead of a defense missile ( 10 ) against an approaching projectile ( 12 ), with a detector device comprising a detector ( 22 ) with a hollow cone-shaped detection area ( 14 ) for detecting an approaching projectile, characterized in that the proximity sensor assembly further comprises a distance sensor to detect the firing of the warhead of a missile ( 10 ) as a function of the distance between the defense missile and the approaching projectile detected by the detector device ( 12 ) to control. Proximity sensor arrangement according to claim 1, characterized in that the distance sensor system an emission device ( 30 ) for emitting a radiation ( 16 ) in the spectral range of the detector ( 22 ) of the detector device contains detectable radiation, the radiation having a main propagation direction in the direction of flight ( 18 ) of the defense missile ( 10 ) is emitted so that the radiation cone ( 16 ) of the emission device ( 30 ) emitted radiation the detection area ( 14 ) of the detector device. Proximity sensor arrangement according to one of claims 1 or 2, characterized in that the detector device comprises two detectors ( 22 ) with mutually offset detection areas ( 14a . 14b ) to determine the relative velocity between the defense missile ( 10 ) and the approaching projectile ( 12 ) and to control a clutter suppression or the ignition triggering of the warhead of the defense missile as a function of the detected relative speed. Proximity sensor arrangement according to claim 2, characterized in that the emission device ( 30 ) on the defense missile launching device ( 10 ) is provided. Proximity sensor arrangement according to one of claims 2 to 4, characterized in that the of the emission device ( 30 ) emitted radiation ( 16 ) and the detector device cross-correlates the modulation of the radiation emitted by the emission device with that of the detector ( 22 ) of the detector device detects detected received signal. Proximity sensor arrangement according to claim 5, characterized in that that of the emission device ( 30 ) emitted radiation ( 16 ) is modulated with a pseudo random noise signal. Proximity sensor arrangement according to claim 5 or 6, characterized in that the detector ( 22 ) of the detector device a PMD detector element ( 26 ) having. Proximity sensor arrangement according to one of claims 1 to 7, characterized in that the detector ( 22 ) of the detector device a detector element ( 26 ), which in the image focus plane behind a cylindrical lens ( 36 ) with convex entry and exit end faces ( 38 . 40 ) or an immersion lens is arranged, through which an inclination relative to the system axis ( 20 ) incoming parallel beam ( 42 ) is focused on a peripheral output area and on the detector element ( 26 ) is focused. Proximity sensor arrangement according to claim 8, characterized in that the detector element ( 26 ) of the detector ( 22 ) of the detector device is annular or arranged. Proximity sensor arrangement according to claim 8, characterized in that the detector element ( 26 ) consists of individual elements which are arranged on a circular ring, whereby the defense missile ( 10 ) on the system axis ( 20 ) is rotating defense missile. Proximity sensor arrangement according to one of Claims 9 or 10, characterized in that the detector element ( 26 ) consists of individual elements which are at least approximately arranged on a circular ring and represent a subset of a larger array.