WO2013087522A1 - Protection system, particularly for ships, against radar‑directed threats - Google Patents

Abstract

It is proposed that an intelligent radar‑directed threat be decoyed using active, electronically aimable and manipulable (off-board) decoys. The active decoying is effected using an antenna array (3) which is mounted on or beneath the surface (2) of a body (10), e.g. a munition or missile body, and also suitable control and signal processing (8) which reflect the received radar signals toward the threat with minimum delay. Furthermore, the signal processing (8) provides a way of sending a firmly prescribed, preferably manipulable, pulse shape toward the threat.

Description

 DESCRIPTION

Protection system, in particular for ships, against radar-directed threats

The invention relates to the active protection of in particular small or medium-sized ships against intelligent radar-guided threats or missiles.

Infrared, radar and dual mode guided missiles may become a. used for example to combat sea targets, such as ships, or other objects on land and air. After launch, these missiles or rockets initially fly inertially (eg DE 196 01 165 A1) or GPS steered into the target area. The missile then goes into a search phase when it has approached the target accordingly. In addition, the missiles turn on the target and pursue this until the impact. To deceive such guided missile different decoys are used to prevent the protection of objects missiles by disturbance in / at their function.

Known deceptive measures against these missiles are, for example, so-called active radar jammers (SIREN, NUKLA - see http://www.selex-sas.com/EN/Common/files/ SelexSAS UK / pdf datasheet / ew / SIREN.pdf, http: //en.wikipedia.org/wiki/Nulka, http://www.fas.org/man/dod-101/sys/ship/wets/mk-53.htm, or inflatable and / or floating radar reflectors (EP 0 182 274 B1) A "Van Atta Array", which is equally applicable in practice (eg US 5,134,413 A http://www.transpondernews.com/taretror.html) itself is a passive array Other missiles send upon detection of a threat Electromagnetic deception signals (DE 100 16 781 C2), others build "clouds" of floating dipoles (Chaff clouds), which are tuned to the radar frequency of the missile.

Variants of the floating dipoles are, for example, (radar) confusion decoys, (radar) seduction decoys or (radar) distraction decoys. A confusion decoy is usually deployed at a great distance between the object to be protected (ship) and the attacker before the attack of the missile. A method for providing a dummy target is known from DE 196 17 701 A1. With this, both infrared, radar and dual mode-guided missiles are directed away from the actual target to a decoy. The use of dipole and flake compounds in a certain ratio ensures that the dipoles are swirled by the flares being burned off.

A further method and a device for deceiving infrared, radar and dual-mode guided missiles are also disclosed in DE 10 2005 035 251 A1.

DE 199 51 767 C2 describes a dual-mode decoy to form a decoy target with an active mass emitting radiation in the IR range and an RF radiation backscattering mass based on dipoles of aluminum-coated or silver-coated glass fiber filaments. Both masses are ejected at the site of action together from the decoy and brought to effect simultaneously.

A chaff with a broadband effect over the entire radar frequencies from 0.1 to 1000 GHz, consisting of conductive or non-conductive fibers with a conductive coating, is disclosed in DE 101 02 599 A1. Other IR and / or radar-reflecting masses etc. are u. a. listed in the prior art of DE 102 30 939 A1. The disadvantage is that choppers are rejected or ignored by modern seekers as a target. For this they have so-called Düppel discriminators.

Inflatable systems in turn have u. a. the disadvantage that the flexible frame construction brings a low geometric accuracy with it. They have a high weight because they include pressure bottles or compressors. Additional equipment is needed to deploy the systems. Floating systems also carry the risk of uncertain duration of action, since they are not only exposed to the environmental influences as such, but also the waves, etc.

Known active systems have a high price and a complicated application process. In addition, the above-mentioned deceptive measures against the radar-guided seekers for digital data processing constantly require increased computer power to initiate a reliable Täuschmaßnahme can. The frequency and amplitude modulation of radar-guided missiles simultaneously lead to large and heavy arrangements with extreme energy requirements. Also because of the known signal vibration (high-frequency signal fluctuation) illuminated chaff decoys are therefore discarded as real goals rather. A protective device connected to protective measures for the protection of an active radar or a transmitting radar system from an anti-radiation missile (ARM) is disclosed in DE 10 2006 017 107 A1. As an active countermeasure, however, the use of passive transmitters / decoys is provided, which is preferably irradiated by the own radar and their radiation is absorbed by the ARM. By doing so, the ARM can not distinguish whether it's decoys or the right radar.

A method and an arrangement for deceiving an end-phase guided ammunition is proposed in DE 196 04 745 C1. Although the principle used here is that a Täuschlaserstrahl is identical in pulse sequence and wavelength with a laser beam of a Zielbeleuchters, the laser emitting the Täuschlaserstrahl is mounted on a mast, so that the ammunition flying past the target, but it is here not about intelligent radar-guided missiles.

To ward off active missiles passive decoy (chaff) are known. These are deployed and reflect a signal emitted by the missile back in the direction of the approaching missile. A passive radar missile is described in US 3,938,151 A1. From US 2,908,002 A1 a passive electromagnetic reflector is known.

Alternative active decoy targets, as mentioned for example in DE 600 10 701 T2, are generally activated only when they are moved, so that a certain amount of time has to be scheduled until the decoy target has fully unfolded.

On the website http://transpondernews.com/taretror.html a passive radar converter is described. A passive reflector also describes the US 5,134,413 A.

From the unpublished DE 10 201 1 1 14 574.9 an active decoy is formed by the use of a retro-reflector or a retrodirective antenna, preferably in the form of a van-Atta array or by at least one backscatter system that a radar beam than Reflection beam can send back exactly in the direction of incidence and thus back to the missile. The retrodirective antenna consists of at least one receiving and reflector antenna. Furthermore, a sensor is integrated, which serves to detect the direction of the approaching missile and is electrically connected to a position control, which acts on servo motors of the protection system to optimally align at least the decoy target on the missile. The invention has as its object to provide an active protection, which causes an effective deception and has a low weight.

The problem is solved by the features of claim 1. Advantageous embodiments are enumerated in the subclaims.

The invention is based on the idea of deceiving an intelligent radar-guided threat with the aid of active, electronically controlled and manipulatable (off-board) decoys.

The active deceit takes place with the aid of an antenna array (planar antenna), which on or below the surface of a body, for. As an ammunition or projectile body, is applied, and a suitable control and signal processing, by the recorded radar signals are reflected with a minimum delay against the threat. In addition, a possibility is created by the signal processing to send a fixed, preferably manipulable pulse shape against the threat. Thus, an active radar reflector is used.

Basically, temporally continuous, non-fluctuating signals with a corresponding frequency and signal course (edge formation) represent an optimal possibility for the formation of attractive and effective radar noises.

The active radar reflector (PARROT = Programmable Active Radar Offboard Targetenhancer) is characterized by the fact that a suitable signal processing and geometry affects both the directivity and the radar signal to be emitted. The actively reflected signal is sent back to the seeker head in such a way that the best possible effect is achieved.

To simulate, for example, a Doppler shift, the signal processing performs a frequency shift between the incoming and the transmitted (active) radar signal.

Furthermore, significant signatures of various potential targets can be impressed on the reflected or hard-coded transmit signal to ensure a better switch-on of the seeker head to the reflector and to divert it from the actual original target. These significant signatures are for example in a memory in the Signal processing stored and preferred by a, the threat detecting sensor retrievable and the seeker head aufprägbar.

The ability to manipulate the actively reflected signal and send it in the direction of the threat bypasses the choppy jitter effect. This effect is caused by the characteristics of electrical transmission media - also called high-frequency signal fluctuation -.) As a result, the signal generated by the active reflector at the seeker head is no longer detectable by chatter discriminators.

The miniaturization and programmability of electronic assemblies allows them to be made small and inexpensive. It also ensures the highest level of flexibility, which is sufficiently responsive to current and future threats.

Further, not insignificant advantages are that the PARROT can be deployed by known Werfersysteme and no additional equipment outside the actual ammunition are necessary. The PARROT glides then during its phase of action, for example, hanging on a parachute, to the ground or into the water. In addition, the PARROT can also be mounted on a dinghy and guided away from the ship.

It is thus created an analogue decoy, which real deception by simple amplification of the radiated signal (frequency, amplitude) realized, an electrical directivity of the radiated signals allows and programmable in duration and mode of action, a signal fading and thus detection by chaff - Discriminators is excluded.

Reference to an embodiment with a drawing, the invention will be explained in more detail, reference being made to the known principle of discharging the decoy by means of throwers, etc.

It shows:

1 shows a representation of the array on the surface of a reflector,

Fig. 2 block diagram of the active reflector. FIG. 1 shows an active "off-board" reflector 1, which is characterized by an antenna array 3 attached to the surface 2 of a body 10 acting as a waveguide and programmable signal processing (not shown) with a broadband input and output stage (FIG. 2) The antenna array 3 consists of a plurality of individual dipoles 4, which are arranged in the manner of a line and which are preferably mounted in a cylindrical manner on the surface 2. However, alternative shapes, such as a rectangle, a parallelogram, etc., are also possible.

The antenna array 3 is for receiving and transmitting, two dipoles 4 each form the transmitting and receiving antennas.

Each dipole element 4, which is mounted on the surface, is assigned an active switching group 20. This has a reception amplifier 6, a logic (eg pulse detector) 7, a signal processing 8 and a transmission amplifier 9.

Upon receipt of a radar pulse of a missile not shown this pulse is received by the respective dipole pairs 4, amplified by the broadband amplifier 6 (Fig. 2) and delayed shortly, so that in this time switching to transmit mode (logic 7) can take place.

During the delay, the transmit signal may be correspondingly manipulated in the signal processing 8 to produce various effects, such as a duplexer shift (frequency increase or decrease) or a pulse shape change (eg, signal widening or narrowing). These changes as manipulation of the received signal (pulse) are possible by the possibility of individual control of each dipole 4 by the respective active switching group 20, since this can be used to influence the directional characteristic of the overall arrangement. It also enables the most effective bundling of transmission power in the direction of the threat.

Instead of switching from receive to transmit mode, a 3-port circulator can alternatively be provided.

In the case of firing, the reflector 1 can be integrated in a non-illustrated ammunition body with propellant. The ammunition body should preferably additionally have a parachute or the like, which opens in function of the reflector 1, so that the reflector 1 on the parachute to the ground (into the water) can slide.

Claims

1 . Protection system for objects, in particular small or medium-sized ships, against intelligent radar-guided threats, comprising:

 a body (10),

 an antenna array (3) consisting of a plurality of line-like arranged individual dipoles (4) which are mounted on or below the surface of the body (10), wherein

 - Each dipole element (4) is associated with an active switching group (20) having at least one receiving amplifier (6), a logic (7), a signal processor (8) and a transmission amplifier (9).

2. Protection system according to claim 1, characterized in that in the signal processing (8) during the delay, the transmission signal of the threat is manipulated.

3. Protection system according to claim 2, characterized in that the manipulation can be the generation of a frequency increase or decrease as well as signal broadening or narrowing.

4. Protection system according to claim 3, characterized in that these manipulations are significant signatures of the object to be protected, which can be stored in a memory of the signal processing (8).

5. Protection system according to one of claims 1 to 4, characterized in that the reflector (1) is incorporated in an ammunition body with propellant.

6. Protection system according to claim 5, characterized in that the ammunition body additionally has a parachute or the like, which opens in function of the reflector (1).,

7. A method for protecting, in particular, small or medium-sized ships against intelligent radar-guided threat, comprising the following steps:

 deploying a protection system (1),

 receive a signal from the radar-directed threat,

amplify and manipulate this signal in the protection system, bundled sending back the amplified and manipulated signal to the threat.

8. The method according to claim 7, characterized in that for signing significant signatures in the protection system (1) are deposited.