EP3118563A1 - Method for protecting a vehicle against an attack by a laser beam - Google Patents

Abstract

The invention relates to a method for protecting a vehicle (2) from attack by a laser beam (8). The vehicle (2) can be quickly and effectively protected against a high energy laser beam (8) when a sensor system (16) of the vehicle (2) detects laser radiation of the laser beam (8) and a control unit (20) of the vehicle (2) detects the laser beam (8) from the data of the sensor system (16) recognizes as such, a start of a missile (12, 14) for the protection of the vehicle (2) in front of the laser beam (8) by the control unit (20) is controlled and the missile (12 14) starts from the vehicle (2).

Description

The invention relates to a method for protecting a vehicle from attack by a laser beam.

High-energy lasers can transmit very high power over several kilometers and over a longer period of time. With such services, sensitive parts of vehicles can be so severely damaged or destroyed within a few seconds that the functioning of the vehicles is jeopardized. Thus, for example, aircraft can be attacked from the ground, in particular slow-moving commercial aircraft with relatively low maneuverability are particularly vulnerable.

It is therefore an object of the present invention to provide an effective method for protecting a vehicle from attack by a laser beam.

This object is achieved by a method of the type mentioned above, wherein the invention detects a sensor system of the vehicle laser radiation of the laser beam and a control unit of the vehicle detects the laser beam from the data of the sensor system as such, a start of a missile to protect the vehicle from the laser beam is controlled by the control unit and the missile starts from the vehicle. The missile can shade the vehicle and / or approach and combat a laser source emitting the laser beam. This is done expediently so quickly that the laser energy deposited on the vehicle has not yet led to threatening damage. A fast protection can be achieved by starting the missile from the vehicle, since then the missile is already on site and dive into the laser beam for shading and / or can quickly fly to combat the laser source on this. Especially in the latter case, the missile is expediently equipped with a rocket motor.

The method is particularly suitable for use against a high energy laser source or a high energy laser beam. Also advantageous is a defense of a sturgeon laser. The sensor system comprises at least one sensor sensitive to laser radiation, which detects the laser radiation of the laser beam. For this purpose, the sensor or the sensor system is expediently sensitive in a radiation spectrum which is usually used for high-energy lasers or interfering lasers. To facilitate the detection of stray radiation, the spectrum in which the sensor is sensitive may be limited to a band around the one laser wavelength commonly used for high energy lasers. For example, the band is at most ± 100 nm around the wavelength of 3800 nm. In addition, the sensor expediently recognizes characteristics typical of laser radiation, such as the presence of coherent radiation. Further, it is advantageous if the sensor system detects by means of image processing methods, a laser beam as such in the environment, for example on the basis of scattered radiation. For this purpose, the sensor system advantageously contains an image sensor, for example a matrix detector.

The sensor system detects laser radiation of the laser beam, ie radiation directly emitted by the laser source and / or laser radiation scattered from the laser beam, for example by the scattering of the laser beam in the air, on particles and / or on an object. The sensor system absorbs the radiation and converts it into a measuring signal. From the measurement signal, the control unit expediently determines a threat level of the laser radiation, for example by a classification in at least the levels threatening or harmless. This can be done, for example, via the measured scattered light intensity in the atmosphere, an energy input into the sensor system, a spread spectrum and / or over a temporal characteristic of the radiation, such as a pulsation.

The vehicle is preferably an aircraft, and may be fixed-wing aircraft or a rotorcraft, such as a helicopter. However, the invention is also advantageously applicable for protecting a land vehicle or a watercraft. The vehicle may be a manned or unmanned vehicle.

The control unit may have one or more arithmetic units that can be arranged in the vehicle at a location distributed over the vehicle, in the vehicle and in the missile or exclusively in the missile housed in the vehicle - and thus likewise in the vehicle. The control unit recognizes the laser beam as such and initiates a start of the flying body as a function of the recognition result. If a laser beam is recognized as such and it is also classified as threatening to the vehicle, the missile is launched from the vehicle. If a laser beam is not recognized as such or classified as non-threatening, the launching of the missile expediently fails.

The missile is expediently a guided missile and in particular an unmanned missile. It may be equipped with a rocket engine and / or an air-breathing engine, such as a turbine engine. In this case, an air-breathing engine is advantageous in accompanying the vehicle by the missile, and a rocket motor is more advantageous in an intended fight the laser source. Also possible is a missile without its own engine, for example in the form of a steering column. The missile expediently comprises a control unit which steers the missile, for example parallel to the vehicle and / or to the laser source.

In an advantageous embodiment of the invention, the sensor system picks up the laser beam from the side, and the control unit detects the laser beam from sensor data obtained from the recording from the side, in particular exclusively from these sensor data. In this way, the laser beam can already be detected, even if he has not yet hit the vehicle, so that early detection of the laser beam as such is possible. In addition, since in a recording of the side only in the air scattered radiation of the laser beam is recorded, can be dispensed with a strong combustion protection of the sensor system. As a result, an image acquisition is facilitated because unprotected, image-processing sensors can be used. A laser beam recorded from the side can be recognized as a straight line in the environment and can thus be recognized as such by means of image processing methods.

Due to the high energy input of the laser beam when hitting the sensor system, this can be destroyed within milliseconds. In order nevertheless to obtain the detection capability of the sensor system, it is advantageous if the sensor system has a plurality of laser-sensitive sensors. These are expediently arranged at different positions on the outer shell of the vehicle, so that they can detect the laser beam from different locations. If one of the sensors is hit and destroyed by the laser beam, the sensory activity of the sensor system can be continued or resumed by another sensor. The sensors are expediently spaced apart at a distance of more than one meter. In particular, in each case at least one sensor is arranged in at least two regions of the group: front half of the fuselage, rear half of the fuselage, upper half of the fuselage, lower half of the fuselage, on a wing. By a wide distance of the sensors from each other can also be achieved the further advantage that a position calculation of a laser source by triangulation from the sensor data of at least three sensors is possible. In this way, the position of the laser source can be determined easily, and the missile can be instructed to this position.

In order to counteract targeted and rapid destruction of the sensors by a movement of the laser beam directed at the sensors, it is advantageous if at least one sensor of the sensor system is covered during operation of the sensor system. In particular, regular operation provides that one sensor is always covered by several sensors of the sensor system. In a surprising attack, at least this part of the sensors can be preserved and used for the detection of the laser beam. It is advantageous in that only a part of the sensors of the sensor system is directed into the environment of the vehicle and another part of the sensors is covered against the environment. Furthermore, it is advantageous if at least one covered sensor is directed into the environment depending on the functionality of one of the other sensors, in particular is brought from a passive state into an active state. If one sensor fails, another can be brought from the covered state to the active state directed to the environment, and the detection of the laser beam can be continued. For example, while the vehicle is in motion, a first sensor can permanently examine the surroundings of the vehicle for laser radiation. If this sensor fails, for example because it was hit by the laser beam, another sensor is activated at another position of the vehicle for further observation and thereby directed or opened into the environment.

Another advantageous possibility for maintaining the functionality of the sensor system is that the sensor system has a multiple sensor with multiple sensor heads. These can, for example, be directed one after the other into the environment. Advantageously, at least one of the sensor heads is always concealed, while at least one other of the sensor heads is directed into the environment and detected. The multiple sensor may be, for example, a turret sensor carrying a plurality of sensors on a drum. Also possible are successively used sensors, the front sensor or an element connected to it, covering the underlying sensor.

Particularly in the case of an aircraft, it is advantageous if at least one sensor of the sensor system is directed exclusively into an upper half space above the vehicle. In an attack of a laser beam from below, the sensor, especially if it is permanently directed in the above half-space, not be hit directly. A detection of the laser beam is still possible on the detection of scattered radiation.

The launched by the vehicle missile can be used to combat the laser source, which emits the laser beam. For this purpose, the missile can fly directly into the laser source and / or destroy the laser source by a detonation charge, in particular by a cone-shaped forward splitter charge. For this purpose, it is advantageous to know the position of the laser source, either relative to the position and / or direction of movement of the vehicle or in absolute coordinates. If the laser beam is sensed by a sensor from the side, it can be determined as a straight line with an abrupt end. The end point of the line can be equated with the position of the laser source.

In this respect, it is advantageous if the control unit determines from the data of the sensor system the position of a laser source which emits the laser beam. In this case, a radiation end of the laser beam can be detected and the position of the laser source can be determined from the position of the beam. Alternatively or additionally, the position from triangulation can be determined from the data of several sensors. The position of the laser source can be detected as a direction, for example as an absolute direction or as a direction relative to the direction of flight of the aircraft. It is also possible to determine the direction as an absolute, ie geographical, direction. Furthermore, a determination of a distance of the laser source from the sensor system is advantageous. This can be done particularly easily using a flying height of the vehicle. If the direction of the laser source and the altitude are known, the distance to the laser source can be calculated from this in a simple manner, in particular taking into account topographical data of an overflown landscape.

In order to enable rapid control of the laser source, it is advantageous if the launch of the missile is fully automatic and in particular triggered by the detection of the laser beam. Alternatively, a semi-automatic triggering is possible in which an operator of the vehicle gives an enable signal and triggering takes place only after the release signal, in particular fully automatically, for example, only when a direction or position of the laser source has been detected with sufficient certainty and accuracy. A start of the missile is expediently already before an alignment of the laser beam on the vehicle, so before the vehicle was hit by the laser beam.

The launch of the missile can take place from a starting device, for example from a container. This can be mounted in the fuselage of the vehicle, so that in particular several missiles can be started in a salvo shot simultaneously or immediately sequentially to protect the vehicle. The term "start" may in this case include a launch.

In order to enable a very fast control of the laser source, it is advantageous if an alignment of a starting device of the missile takes place as a function of the position of the laser beam, in particular in dependence on the position of the laser source. It can be a targeted launch in the direction of the laser source, so that the time is saved for a detour flight. Accordingly, it is advantageous if the missile starts directed to a laser source of the laser beam. In this case, a curved trajectory, for example, taking into account ballistic influences, are used so that the alignment of the missile at the start does not have to be in a straight line to the laser source.

Further, it is advantageous if the control unit in the missile passes a target instruction on a laser source of the laser beam to a control unit of the missile. This can be done before the launch of the missile and / or in particular during the flight of the missile, for example by a data link from the vehicle to the missile. The control unit of the missile receives the target instruction and directs the missile to the laser source. In this way, the missile can already be started before the exact position of the laser source has been calculated.

The flight of the missile can be controlled independently by a control unit of the missile. Additionally or alternatively, it is possible that the remaining in the vehicle control unit controls the flight of the missile or mitsteuert. For example, the self-controlling missile an escape or Abschattungsanweisung be issued by the vehicle, which is then taken into account by the control unit of the missile.

A control of the missile from the vehicle is also advantageous if the position of the laser beam or the laser source can be accurately determined by the vehicle or the vehicle detects an impact of the laser beam and delegates the missile in a shading position. Thus, for example, laser-sensitive areas of the vehicle can be deliberately shadowed by the corresponding flight control of the missile, or the onward flight of the missile can be controlled in the case of a destroyed sensor of the missile further to the laser source.

The invention is also directed to a vehicle having a sensor system for detecting a laser beam. According to the invention, the vehicle is equipped with a missile which is prepared for controlling a laser source of the laser beam and / or for shading an element of the aircraft. Advantageously, the aircraft includes a control unit which is prepared to detect the laser beam from the data of the sensor system as such and to control a start of the missile from the vehicle to protect the vehicle from the laser beam.

The description of advantageous embodiments of the invention given so far contains numerous features that are summarized in several dependent claims in several groups. However, these features may conveniently be considered individually and grouped together into meaningful further combinations, in particular when reclaiming claims, so that a single feature of a dependent claim can be combined with a single, several or all features of another dependent claim. In addition, these features can be combined individually and in any suitable combination both with the method according to the invention and with the device according to the invention according to the independent claims. Thus, process features can also be formulated formally as properties of the corresponding device unit and functional device features also as corresponding process features.

The above-described characteristics, features, and advantages of this invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following description of the embodiments, which will be described in detail in conjunction with the drawings. The embodiments serve to illustrate the invention and do not limit the invention to the combination of features specified therein, not even with respect to functional features. In addition, suitable features of each embodiment may also be explicitly considered isolated, removed from one embodiment, incorporated into another embodiment to complement it, and / or combined with any of the claims.

FIG 1

ein Luftfahrzeug unmittelbar vor einem Angriff durch ein Lasersystem,

FIG 2

einen Revolversensor eines Sensorsystems des Luftfahrzeugs und

FIG 3

mehrere Verteidigungen des Luftfahrzeugs mit Hilfe von Flugkörpern.

Show it:

FIG. 1

an aircraft immediately before an attack by a laser system,

FIG. 2

a turret sensor of a sensor system of the aircraft and

FIG. 3

several defenses of the aircraft with the help of missiles.

FIG. 1 shows a vehicle 2 in the form of an aircraft, which is designed in this case as a commercial aircraft for the transport of passengers or air freight. In a landscape 4, over which the vehicle 2 flies, a laser system 6 is positioned, which in the in FIG. 1 represented moment a laser beam 8, which is generated by a laser source 10, directed into the sky. The laser system 6 is placed in the embodiment shown on the ground and immovable. However, it is also possible that the laser system 6 is movable and is mounted, for example, in an aircraft. All details described below and related to the laser source 10 are then to be adapted accordingly to the mobility or height above the ground.

The laser system 6 is a high-energy laser system which emits the laser beam 8 predominantly in the infrared spectral range, for example at 3.8 microns, wherein the Laser beam 8 over a distance of several kilometers transported enough energy to destroy sensitive parts of the aircraft and thereby endangering its flying capacity acutely. The laser system 6 is used to combat aircraft and has a control unit which pivots the laser beam 8 on the vehicle 2 and the laser beam 8 automatically tracks the movement of the aircraft 2. In the control unit, a laser-sensitive point of the vehicle 2 is deposited, to which the laser beam 8 is automatically directed by means of image processing methods to irradiate the laser system 6 pictorially deposited point of the aircraft 2 over a period of a few seconds and thereby destroy.

Instead of the high-energy laser system 6, a designator laser system or marker laser system can be fought or disturbed, which illuminates the vehicle 2 in order to control a guided missile into the vehicle 2. By shading the vehicle 2 and / or destroying the laser source 10, this mark can be disturbed, so that the attacking missile can not find the vehicle 2. The following description refers to a stationary high energy laser system 6 without being limited to this system.

To protect the vehicle 2, this has at least one missile 12, 14, wherein in FIG. 1 to illustrate several protection methods three missiles 12 and a missile 14 are shown. Furthermore, the aircraft has a sensor system 16 with a plurality of sensors 18, which are each signaled by a control unit 20. In the illustrated embodiment, the aircraft is equipped with five sensors 18, one in the rear half of the fuselage, one in the front half of the fuselage, one on each wing of the aircraft, and one upward sensor 18 on the upper half of the fuselage of the aircraft ,

To protect the aircraft, initially only one of the sensors 18 of the sensor system 16 is active, and the other of the sensors 18 are covered. Covered in this context means that the laser-sensitive element of the corresponding sensor 18 is covered by a laser-resistant cover so that it is not destroyed by a beaming from the outside of the aircraft 2 laser beam 8, in particular can not be achieved. Active means in this context that a field of view of the laser-sensitive element in the environment is free and the sensor 18 receives sensor data and to the control unit 20 passes. By means of this safety measure, it is possible to ensure that not all the sensors 18 are destroyed by a plurality of laser beams 8 or by a laser beam 8 traveling very rapidly over the fuselage, before the laser beam 8 has been detected. Due to the wide distance of the sensors 18 from each other also a rapid scanning of the individual sensors 18 is made difficult by the laser beam 8. In addition, one of the sensors 18 is oriented upward and can not be reached by a laser beam 8 incident from below on the aircraft 2. Aligned upward means in particular in this context that the sensor 18 is directed in a horizontal flight of the aircraft exclusively in the upper half-space. This sensor 18 is thus very well protected and also suitable to detect the laser beam 8 from scattered radiation of the laser beam 8 in the atmosphere.

At the in FIG. 1 shown embodiment, the front sensor 18 of the sensor system 16 is active and the remaining sensors 18 are covered. The sensor is designed as a revolver sensor and schematically in FIG. 2 shown.

FIG. 2 shows one of the sensors 18 of the sensor system 16 from FIG. 1 , The sensor 18 comprises six sensor heads 22, of which five of the sensor heads 22 are covered by a cover element 24, for example a metal plate. One of the sensor heads 22 is behind an opening 26 of the cover 24, is thus aligned in the environment and can look into the environment and detect laser radiation. The sensor heads 22 are pivotable about a common axis, as in FIG. 2 indicated by the curved arrow. If the currently active sensor head 22 is destroyed, the turret can be further rotated by 60 °, so that the next sensor head 22 comes to lie behind the opening 26 and can detect the detection.

Arranged in the middle and also behind the cover element 24 is a further sensor head 28, which has the task of detecting when a high-energy laser beam 8 is directed onto the sensor 18. Although the sensor head 28 is not able to detect laser radiation per se, it measures an energy input on the cover element 24, so that an active switching of an undamaged sensor head 22 can be avoided as long as the laser beam 8 is directed to the sensor 18.

The remainder of the sensors 18 of the aircraft 2 may be as in FIG. 2 be shown sensor 18 executed. In a simplified version, however, the rest the sensors 18 only a sensor head 22 and the sensor head 28 and a movable cover 24 on. As long as the laser beam 8 is directed to the sensor, the cover conceals the laser radiation-sensitive sensor head 22. Only when the control unit 20 has enabled the activation of the sensor and as an additional condition, the laser beam 8 does not rest on the sensor 18, the sensor head 22 and thus the Sensor 18 switched active.

The sensor heads 22 each comprise image sensors behind a 180 ° optics, so that the scene of a hemisphere of the surrounding space is imaged onto a laser-sensitive element. In this way, an image of the laser beam 8 can be recorded in the environment, and from this further information about the laser beam 8 can be determined, such as geometry, position and intensity of the laser beam. From the geometry recognizes the control unit 20 of the sensor system 16, in particular by means of image processing methods, the laser beam 8 as such. As geometrical features can be used that the laser beam is seen as a straight line in the landscape. In addition, it has a sharply defined end on the laser source 10. At its other end, however, the laser beam becomes weaker, as long as it does not strike an object FIG. 1 is shown, so that a defined end is not readily determinable. This feature of the upper attenuation of the laser radiation can also be used for laser detection.

From the geometric data of the laser beam 8 and its spectrum and radiation intensity, the control unit 20 first classifies the laser beam 8 in the three stages harmless, potentially dangerous and dangerous. In a classification harmless in the level of the laser beam 8, which is generated for example by a laser pointer, further observed, however, neither the laser beam 8 is shadowed nor the laser source 10 is combated. Classification in one of the other two levels will prepare for shading and / or combat. For this purpose, a canister 30, which accommodates at least one of the missiles 12, is pivoted in the direction of the laser source 10. This pivoting is in FIG. 1 indicated by the curved double arrow on the canister 30. Alternatively or additionally, the ejection of the missile 14 from the fuselage of the aircraft 2 is prepared. Classification into the highest of the threat classes will initiate combat and / or shadowing. For this purpose, for example, a release of an operator of the aircraft 2, such as a pilot, necessary. However, this has already been given in advance, for example because it is known that the aircraft is flying through a potentially dangerous region.

Both for shading and for controlling the laser source 10, it is advantageous if the position of the laser source 10 is known. This determines the control unit 20, for example, from the geometry of the laser beam 8. Thus, at the location of the abrupt end of the laser beam 8, the laser source 10 can be suspected. In addition, the laser beam 8 can be given a direction, at least a rough direction at the top and bottom, wherein the laser source 10 is positioned only at a lower end of the laser beam 8. In this way, a direction of the laser source 10 relative to the aircraft 2 can be determined. From the direction and a flight altitude of the aircraft and expediently a topography of the overflown landscape, the distance between aircraft and laser source 10 can be determined, in particular the absolute geographic coordinates of the laser source 10 are determined.

The detection of the laser beam 8 takes place insofar by a recording of the laser beam 8 from the side, wherein from the laser beam 8 scattered in the atmosphere laser radiation is recorded. This can also be done by the upward sensor 18 whose view is adjusted to the laser source 10. On the basis of the orientation of the visible part of the laser beam 8, a further course of the laser beam 8 can also be extrapolated in the environment.

In the event that the laser beam 8 is already directed at the aircraft 2 and thus the undefined upper end is no longer recognizable as such and the laser beam 8 has an abrupt end both above and below, the determination of the position of the laser source 10 is detected by another of the sensors 18 of the sensor system 16, for example by a sensor 18 on a wing of the aircraft 2. This recognizes the laser beam 8 per se and both abrupt ends, the control unit 20, the lower abrupt end of the laser beam 8 as the location of Laser source 10 selects. Also possible is a position determination of the laser source 10 by means of triangulation. Once three or more sensors 18 have detected the laser beam 8 and determined its lower abrupt end, in addition to the direction of the laser source 10 and its distance can be determined by the known orientation of the sensors 18 on the aircraft 2 to each other.

To protect the aircraft, at least one missile 12, 14 is now started by the aircraft. The control of the start takes over the control unit 20 of the Sensor system 16, which may also be part of a central vehicle control of the vehicle 2.

FIG. 3 shows two embodiments for protecting the aircraft, which can be performed individually or in combination. In a first embodiment, a missile 12 is started in the form of a steering rocket. This missile 12 is started from the canister 30, for example, by a drop, a launch and / or a launch of a missile engine of the missile 12. Since the missile 12 is already aligned by the orientation of the canister 30 to the laser source 10 to the laser source 10, detours can be avoided and the missile 12 can be sent in direct line to the laser source 10. As an alternative to the guided missile, other guided missiles may also be used, for example steerable projectiles. This is also a control unit 32 for controlling the steered flight and a. Steering system 34 to perform the steering. Furthermore, the missile 12 expediently comprises an active part 36 with an explosive charge for controlling the laser source 10. Depending on the design, the missile 12 may have a rocket motor for independent acceleration.

The control of the missile 12 can be done independently by the control unit 32 of the missile 12. It is also possible that the control is carried out by the control unit 20 of the aircraft, either in addition or independently by the specification of appropriate commands to the control unit 32 of the missile 12. In this way, the missile 12 is controlled on or in the laser source 10 so that they gets destroyed. Shortly before the missile 12 reaches the laser source 10, the active part 36 can be ignited, which hurls a fragmentation charge in a forward direction and thereby destroys the laser source 10. The ignition of the active portion 36 may be by an impact fuse or a proximity fuse located in the missile head.

The flight of the missile 12 is suitably guided by the laser beam 8. For this purpose, it can be further observed by the sensor system 16 of the aircraft, and in the missile 12 corresponding control signals can be given. Alternatively or additionally, it is possible that the missile 12 independently uses the laser beam 8 as flight guidance and steers its own flight depending on its orientation in space. The missile 12 thus flies guided by the laser beam 8 independently in the laser source 10. Here, the flight in the laser beam. 8 or be guided along the outside of the laser beam 8 or at a suitably predetermined distance along the laser beam 8 along.

In particular, in an independent control of the missile 12 to the laser source 10, the transfer of a target instruction from the control unit 20 to the control unit 32 is advantageous. As a result, at least a rough navigation in the first part of the approach can be considerably facilitated.

In the other embodiment, the missile 14 is dropped from the fuselage of the aircraft, and this begins its flight, which is substantially parallel to the flight of the aircraft. The purpose of this flight is to shade the aircraft, in particular at least laser-sensitive points of the aircraft 2, from the laser beam 8. The missile 14 is driven by an air-breathing internal combustion engine, for example a turbine, so that a long flight accompanied by the aircraft is possible. Alternatively or additionally, a rocket motor is possible, in particular a solid fuel motor, which is tuned in terms of its performance on the airspeed of the aircraft. The missile 14 is equipped with large wings for large-scale shading of the aircraft. At least the entire lower side of the missile 14 is laser-hardened, so that an irradiation of at least two minutes by the high-energy laser beam 8 does not cause the flight destructive destruction on the missile 14.

For holding the missile 14 in the laser beam 8 there are several possibilities. For example, the position of the laser beam 8 in the space or its end on the vehicle 2 can be determined by sensors 18 of the sensor system 16. Corresponding control signals are given by the control unit 20 to a control unit 40 of the missile 14.

An alternative or additional possibility is that the missile 14 determines the shading itself and controls its flight from this. Thus, the missile 14 has an upwardly directed laser-sensitive sensor, which observes the aircraft 2 from below. An impact of the laser beam 8 on the aircraft 2 is detected, and the missile 14 is controlled so that the irradiation spot of the laser beam 8 on the aircraft 2 disappears. For this purpose, the flight is controlled so that the control variable, namely the visibility of the laser spot on the aircraft 2, disappears or at least reduced. This is done by a particular achieved complete shadowing. On the other hand, if the laser beam 8 is moved away from the aircraft, the laser spot also disappears. In this case, the missile 14 continues to accompany the aircraft for a predetermined distance or time duration in order to maintain protection against the potentially again dangerous laser beam 8.

LIST OF REFERENCE NUMBERS

2

vehicle

4

landscape

6

laser system

8th

laser beam

10

laser source

12

missile

14

missile

16

sensor system

18

sensor

20

control unit

22

sensor head

24

cover

26

opening

28

sensor head

30

canister

32

control unit

34

steering system

36

active part

38

rocket engine

40

control unit

Claims (15)

Method for protecting a vehicle (2) against attack by a laser beam (8), in which a sensor system (16) of the vehicle (2) detects laser radiation of the laser beam (8) and a control unit (20) of the vehicle (2) detects the laser beam (8) from the data of the sensor system (16) recognizes as such, a start of a missile (12, 14) for the protection of the vehicle (2) in front of the laser beam (8) by the control unit (20) is controlled and the missile (12 14) starts from the vehicle (2). Method according to claim 1,
characterized,
in that the sensor system (16) receives the laser beam (8) from the side and the control unit (20) recognizes the laser beam (8) from sensor data obtained from the image taken from the side. Method according to claim 1 or 2,
characterized,
in that the sensor system (16) has a plurality of laser-sensitive sensors (18) which detect the laser beam (8) from different positions of the outer shell of the vehicle (2). Method according to claim 3,
characterized,
that only a part of the sensors (18) is directed into the environment of the vehicle (2), another part of the sensors (18) is covered against the environment and at least one covered sensor (18) depending on the functionality of one of the other sensors (18) is directed into the environment. Method according to one of the preceding claims,
characterized,
in that the sensor system (16) has a multiple sensor with a plurality of sensor heads (22) which can be successively directed into the surroundings. Method according to one of the preceding claims,
characterized,
in that at least one sensor (18) of the sensor system (16) is directed exclusively into an upper half space above the vehicle (2). Method according to one of the preceding claims,
characterized,
that the control unit (20) from the data of the sensor system (16) detects a beam end of the laser beam (8) and from the position of the beam end, the position of a laser source (10) determines that emits the laser beam (8). Method according to claim 7,
characterized,
that a distance to the laser source (10) using an altitude of the vehicle (2) is determined. Method according to one of the preceding claims,
characterized,
that the start of the guided missile (12, 14) is fully automatic and is triggered by the recognition of the laser beam (8). Method according to one of the preceding claims,
characterized,
that alignment of a start device (30) is carried out of the guided missile (12) in dependence on the position of the laser beam (8). Method according to claim 10,
characterized,
in that the guided missile (12) starts directed towards a laser source (10) of the laser beam (8). Method according to one of the preceding claims,
characterized,
in that the control unit (20) sends the guided missile (12, 14) a target instruction to a laser source (10) of the laser beam (8). Method according to one of the preceding claims,
characterized,
in that the control unit (20) controls a flight of the guided missile (12, 14) from the aircraft (2). Method according to claim 13,
characterized,
that the control unit (20) determines a position of the laser beam (8) in the space and the flight of the guided missile (12, 14) controls, using the position determined. Vehicle (2) having a sensor system (16) for detecting a laser beam (8), a guided missile (12, 14) and a control unit (20) which is prepared to read the laser beam (8) from the data of the sensor system (16). to recognize as such and to control a start of the missile (12, 14) from the vehicle (2) to protect the vehicle (2) from the laser beam (8).

Images