DE4406227C1 - Radar, IR or optical camouflage appts. for aircraft carrying radiators and sensors - Google Patents

Abstract

The appts. is used on an aircraft (1), threatened by tracking from hostile radar (2) on a mountain top (4) against the background of a lower peak (5) and carrying a number of sensors (7) on its background side connected to radiators (6) on its opposite side through a computer. Each segment of the surface of the aircraft emits radiation (g) at the same time in different directions with intensities corresp. to the background reflection (f) so that absorption by the aircraft is not recognisable by the radar.

Description

The present invention relates to a device for radar, Infrared and / or visual camouflage of objects on a variety of any of their respective front distributed radiators / absorbers and on the respective Back of the object have a similar number of sensors, which detect the background radiation of the object to be camouflaged and with this information the radiation intensity of the Radiator / absorber on the respective front of the object to the Adjust background radiation.

Moving and resting objects with good stealth properties suppress their radiation signature in the Main threats directions almost completely. On consideration against a clear sky this is also desirable, not however, when looking towards one stronger reflective or radiant background, like clouds, Massifs of rock or the surface of the earth. In this case, the Radiation signature a hole can be seen, which for exposure can be used. Aim of camouflage wearer it is transparent, but not including his Make background image portion invisible.

DE 28 48 072 C2 describes a method and a device to adapt the radiation of a metallic target to the Radiation of his surroundings known. For the purpose of camouflage the radiation of the environment as a measure of active adaptation with the help of a radiation source installed at the target used, whereby the radiation of the vegetated environment, the ambient temperature and the cloud cover measured and the result is the natural radiation of the under utilization the reflective radiation of the sky in comparison with the Earth of colder target over a microwave radiation source at least in one of the atmospheric spectral ranges of 20,  35 or 95 gigahertz is adjusted. In this well-known The procedure will be an effective camouflage of the person to be protected Object only achieved against microwaves if the respective Background seen the same from all directions shines strongly or if it is only one Direction of threat and this is known in advance. The Background radiation is measured from the Ambient temperature and the cloud cover. Local differences and details in the background radiation from an area shaded by the target cannot be captured if the target, such as B. the tank according to DE 28 48 072, according to the invention, the strong emission radiation of the vegetation Environment simulated, but just over a steel bridge low emission. Furthermore, the level of Radiation intensity is not complete, but only approximately reached (column 4, line 65).

DE 32 17 977 C2 describes a device for camouflaging Objects against an enlightenment by means of thermal imaging devices Creation of dummy images using each other connected, heat-sensitive sensors and thermal Energy sources, the heat-sensitive sensors and the thermal energy sources combined into a camouflage segment are covered by these camouflage segments the object to be camouflaged and every heat-sensitive sensor of a camouflage segment one side of the object is a thermal energy source Assigned to the camouflage segment on the opposite side of the object is. The camouflage is only effective if the respective background seen from all viewing directions shines equally strong or if only one Direction of threat exists and this is known in advance. The Radiation from the background is measured across the board, i.e. H. only for a single threat direction.

The object of the present invention is to provide a device create with a much better camouflage of objects against education by means of electromagnetic radiation is ensured by the object to be camouflaged covered background for all threats to everyone  Time is shown as true to nature as possible, so that no Hole in the signature occurs.

Starting from a device of the aforementioned Art this problem is solved in that each Segment of the object surface at the same time in different threats to those intensities that emits the different background sections of each object surface segment.

There is advantageously a between sensors and emitters Computer switched that with the information from relative movement of object and background as well as a reduced number of control measurements of the background radiation largely to be radiated from the background independently created or changed and - if one The background images are already saved in the on-board computer starting the vehicle is possible - this stored data instead of or in addition to the control measurements for Creation of the illusion used.

Preferred are with rapidly changing background details the background data stored before the flight and the during correction values of the background measured during the flight On-board computer so to control the radiation of the illusion processed that the inertia of the emitters largely is compensated.

The device according to the invention offers the decisive one Advantage of considering the directional dependency. This means that the device is not only in one Direction of threat or not just for a uniform Background is effective, but it will be used in both Determination of the background and the radiation of the Multiple image to reconstruct this background or all directions considered.

The invention is based on the drawing for a Function example with radar camouflage explained; show it  

Fig. 1 shows schematically the beam path between a radar device, an aircraft and cloud cover; and

Fig. 2 shows the beam path between a tip arranged on a radar device and a lower flying plane.

In Fig. 1, 1 a to be camouflaged object, such as an aircraft, referred to that absorbs a certificate from a radar device 2 impinging radar radiation to a large extent. If there is now a cloud bank 3 above the aircraft 1 , which is also suitable as a reflector for radar radiation, the enemy radar 2 notices a so-called shadow hole at the point at which radar radiation is not reflected by the aircraft 1 but is absorbed. With a high-resolution radar device 2 , an object to be camouflaged can thus be detected, so that unmasking is possible.

For better understanding, the beam emitted by the radar device 2 is designated in FIG. 1 and the beam reflected by the background, ie in the cloud bank 3 , is designated by b. C denotes the radar beam emitted by the radar device and directed onto the aircraft 1 , and d denotes the far too small proportion of the beam reflected by the aircraft 1 in the direction of the radar device 2 , the major part of which is absorbed. The "disturbed" retroreflection is due to the double stroke || designated. E now denotes a beam emitted by the aircraft and f denotes the reflected portion of this beam, which is detected by a sensor 7 . A large number of sensors on the side of the object to be camouflaged, that is to say the cloud bank 3 , in the case of the cloud bank 3 , in this case the aircraft 1 , are distributed arbitrarily on the upper side thereof and can be connected to a computer, which in turn is connected to one or a plurality of Radiators / absorbers is connected, arbitrarily on the side facing the main threat directions, e.g. B. are distributed on the underside of the aircraft 1 . The computer now controls the emitters in dependence on the signals supplied by the sensors in such a way that each emitter emits different intensities in different directions at the same time.

FIG. 2 shows an object to be camouflaged, ie an aircraft 1 , which is to be detected by an enemy radar 2 arranged on a hilltop 4 . As a background, ie in the extension of the main direction of threat from the radar device 2, there is a low hilltop or the ground 5 . The side of the aircraft 1 facing this background 5 now has, according to the invention, any number of sensors 7 which are connected via the computer to the emitters 6 facing the radar device 2 . The latter emits the beam c in the direction of the suspected object. The beam labeled d is now the one with the double line || which is disturbed by the camouflaged aircraft 1 and does not correspond to the reflection of the background 5 identified and returning to the radar device 2 , whereas g corresponds to the radiation of the beam f generated by the aircraft 1 , corresponding to the background, with which the shadow hole is removed which corresponds to the shadow created by the illuminated aircraft 1 due to its absorption. Schematically, 6 denotes one of the emitters and 7 one of the sensors for controlling the emitter 6 . It is clear that emitters and sensors can be distributed as desired over the surface of the object to be camouflaged, thus creating optimal camouflage for all possible threats.

A simplification of the effort for the invention Device can be achieved in that the background is saved in the on-board computer before starting and only occasionally by resampling and appropriate correction changes that have occurred in the meantime during the flight is adjusted. This technique is particularly advantageous when it comes to fast moving objects, such as. B. aircraft, that simulate less detail of the background have to be, for example, large ships.  

It is assumed that the background is already in front of the Launch is essentially known. If not should be, for any point on the surface of the Object at the same time the background from all Viewing directions determined and immediately in all Threats are emitted. However, this means a considerable effort.

To reduce this effort, the surface can be segmented in a meaningful manner, in particular in the case of large objects, such as ships, and at the same time a restriction to a limited number of threat directions can be advantageous. The main simplification in the measurement of the background can be achieved in that the measured values are not passed on directly to the emitters 6 , but rather are fed to the computer, which processes them into a dummy image and stores it, the computer corresponding to the relative movement of the object and background itself changed. A reduced number of background measurement values is used by the sensors to correct the calculated image or to generate the image parts newly added at the front edge of the image.

In extreme cases, this means one in the case of a ship Forward speed from zero (i.e. that the ship turns on the spot) that all background points after a first measurement are known and only by computer on the Ship surface shifted according to the ship's rotation Need to become. Except for measuring some correction pixels no new background points need to be measured.

In the other extreme case of straight forward movement in front of you every pixel moves from the bow to a different background of the ship to the stern and during this time it takes except for occasional corrections, no longer measured too become.

If the background is not only local, but at recorded location also changes in time, they come here  proposed simplifications only to a lesser extent Carry. However, a major advantage is still being gained be achieved, especially with periodically running changes over time, such as waves, beacons, etc., fewer measurements are required. In practice, mostly these and similar extreme cases are superimposed. The statements for the ship naturally apply to maneuvering planes. As a relief comes on the plane added that fewer background details are reproduced have to.

The device according to the invention is just as suitable for improved camouflage of objects to be determined visually e.g. B. be illuminated by headlights and in front a background with greater reflectivity. In In this case, optically effective emitters Depending on the direction, light intensities are radiated back to the reflective background.

Essential to the invention is the increase in the security of the Camouflage against enemy radar and / or infrared reconnaissance due to the consideration of the directional dependency, d. H. of the signals emitting the background every emitter with different intensities in different directions at all times.

The invention relates to the entire Wavelength range of electromagnetic radiation, especially from visible light via infrared and Radar and microwave range up to the radio waves.

Claims (3)

1. Device for radar, infrared and / or visual camouflage of objects that have a plurality of arbitrarily distributed radiators on their respective front and have a similar number of sensors on the respective rear of the object that detect the background radiation of the object to be camouflaged and use this information to adjust the radiation intensity of the emitters on the respective front of the object to the background radiation, characterized in that each segment of the object surface emits those intensities at the same time in different threat directions which correspond to the different background sections of each object surface segment. 2. Device according to claim 1, characterized in that a computer is connected between sensors and radiators, the one with the information from the relative movement of object and Background as well as from a reduced number of Control measurements of the background radiation created to appear radiating image of the background or changed and - if the Background images in the on-board computer before the start of the Object is possible - this stored data instead or in addition to the control measurements to create the Illusion used. 3. Device according to the preceding claim 2, characterized characterized in that with rapidly changing Background details before the start of the object  stored background data and those during the movement correction values of the background measured in the object On-board computer so to control the radiation of the Dummy image that are processed Switch-on delay of the spotlights is compensated.