The present invention relates to a method for protecting ships against terminal homing phase-guided missiles provided with a target data analysis system in accordance with claim 1, as well as a protective system apparatus in accordance with claim 13.
Ever since the Israeli destroyer “EILAT” was sunk by Styx missiles of the Egyptian navy in the year 1967, antishipping missiles constitute a massive threat to ships.
Modern antishipping missiles possess radar (RF), infrared (IR), or DUAL MODE (RF/IR) sensors for the terminal homing phase guidance. Corresponding “intelligent” data analyses enable these missiles to discriminate between target and spurious target.
These missile-immanent data analyses meanwhile encompass any relevant temporal, spatial, spectral and kinematic features, such as, for example:
For the protection of military objects against missiles, RF and IR decoys have for a long time been utilized in the prior art. Just like the missiles, these were optimized in the course of time and constitute an effective countermeasure.
Owing to the rather unsatisfactory imitation of the ship's signature in all the spectral ranges in which the sensory equipment of the attacking missiles operates, the current decoys and decoy methods are nevertheless not optimally suited against the threat of a ship by guided seeking weapons.
Particularly under the premise of a respective maximum possible resemblance to nautical vessels, the known decoy methods and systems are only conditionally capable of satisfying the “and”-linked demands for:
DE 38 35 887 A1 describes a cartridge for producing phantom targets, in particular for the use with tanks for the protection against sensor-controlled ammunition. The phantom target cartridge is executed as a dual-mode ammunition, containing corner reflectors in order to imitate the radar signature of a tank, and incendiary charges in order to imitate the infrared signature of a tank. Corner reflectors and incendiary charges are distributed by an explosive charge so as to result in a tank signature in both spectral ranges.
An infrared active composition for producing phantom targets is described, e.g., in DE 43 27 976 C1. This is a flare mass on the basis of red phosphorus which preferably emits radiation in the medium wave range upon its combustion. These flares—where incorporated in corresponding decoy ammunitions—may be used for the protection, e.g., of tanks, ships, and drilling platforms.
DE 196 17 701 A1 equally describes a method for furnishing a phantom target for the protection of land, air, or water vehicles as a defense against guided target seeking missiles operating in dual mode or serially, wherein an active composition emitting radiation in the IR range and backscattering an RF radiation may be made to take simultaneous effect as a phantom target in the appropriate position.
EP 1 336 814 A2 discloses a RADAR countermeasure system for the protection of ships by deploying corner reflectors in a defined manner in azimuth and elevation in the trajectory of an approaching missile.
DE 199 43 396 moreover discloses decoys as well as a method for furnishing a phantom target, e.g. for the protection of ships, as a defense against missiles possessing both a target seeking head operating either in the infrared or radar range, as well as one operating simultaneously or serially in both wavelength ranges, wherein an IR active composition emitting radiation in the IR range on the basis of flares, and an active composition backscattering RF radiation on the basis of dipoles are made to simultaneously take effect in the appropriate position as a phantom target, with a ratio of dipole mass to flare active composition of approx. 3.4:1 to 6:1 being used; and flares being used whose descent rate is approx. 0.5 to 1.5/s higher than the descent rate of the dipoles.
HERRMANN, Helmut wt 2/89 “Tarnen und Täcuschen bei der Marine” [Concealment and Deception in the Navy] discloses a method for protecting ships against terminal homing phase-guided missiles provided with a target data analysis system. This reference furthermore describes that the missile moving in a direction towards the ship to be protected is detected by suitable sensors, located, and its expected trajectory is calculated by means of a computer.
For a successful defense against the missile, in accordance with HERRMANN, the direction of approach, azimuth and elevation, as well as the range must be known. Furthermore HERRMANN describes the dependency of the effective utilization of chaff on the ship's course, wind force and direction of wind, as well as the direction of the missile threat. HERRMANN also describes the use and taking into account of the ship's own data—travelling speed, direction of travel, rolling and pitching motions—for an effective deployment of decoys.
It is equally described that a computer calculates an optimal course of the ship and an optimal travelling speed of the ship in order to support the separation from the ship to be protected of the decoy formation which is deployed with support of the fire control calculator.
A similar ship protection system is disclosed in U.S. Pat. No. 4,222,306, however this does not exceed the content of disclosure of the HERRMANN article.
The means for generating special decoy patterns in dependence on decoy and attack structure are not described.
It is true that all of the mentioned documents describe the generation of decoys or phantom targets which partly have a signature resembling a ship. In combination with the available decoy ejectors, however, an effective temporal and spatial utilization of decoys for the protection of ships may not be achieved in an optimal manner by any of the hitherto disclosed methods and apparatus.
Most decoys are launched either as decoy rockets or in accordance with the mortar principle from rigid ejectors, so that an accurate positioning is not possible. Even when fired from dirigible decoy ejectors, the demanded temporal staggering and spatial separation of the decoys is extremely difficult with the hitherto disclosed methods and apparatus inasmuch as a sequential deployment with spontaneously (as a reaction to the current threat situation) selectable launching intervals and spontaneously selectable firing distances may not be realized.
Starting out from the prior art of the HERRMANN article, it is therefore the object of the present invention to furnish an improved method as well as an apparatus for the protection of ships by means of decoys.
In terms of method, this object is achieved through the characterizing features of claim 1.
In terms of apparatus, the above object is achieved through the characterizing features of claim 13.
The following demands are being made to a method and an apparatus for the protection of ships against “intelligent”, terminal homing phase-guided missiles:
An effective decoy method or system must ensure, in dependence on
This decoy formation must correspond to the ship's signature in all of the spectral, spatial, and temporal criteria that are of relevance for the missile target seeking heads. The decoy formation must be composed of single decoy ammunitions so as to be able to ensure maximum flexibility and versatility with regard to shape and size of the decoy formation.
The decoys encompass decoy ammunitions which include either RF and/or IR and/or combined RF/IR active compositions so as to be able to reproduce the ship's RF and IR signatures.
The method of the invention utilizes decoy ammunitions having a generated phantom target diameter each corresponding to about 10 m to 20 m so as to be able to reproduce the spatial signature of the ship to be protected.
In accordance with the invention, the decoys are adapted to be deployed such that by means of the arrangement of individual decoy ammunitions, in particular of patterns separated in width and height, a ship-type extension and movement of the decoy formation is generated which separates from the ship to be protected.
By the method of the invention and the protective system apparatus for implementing the method it is ensured that it is possible, in dependence on all of the input parameters (missile, ship, wind), to spontaneously generate a decoy formation which is fully flexible with regard to the parameters of:
In particular the present invention relates to a method for protecting ships against terminal homing phase-guided missiles provided with a target data analysis system, wherein
It is preferred if RF and/or IR and/or UV sensors are used for detection of the approaching missile. Preferably the ship's on-board reconnaissance radars are used.
Preferably the wind measuring sensors of the ship's on-board wind measuring equipment are used for detecting direction of wind and wind speed.
Furthermore the ship's own data, in particular pitching and rolling motions, is detected by the navigation equipment and the gyroscopic stabilization equipment on board of the ship to be protected or by means of separate acceleration sensors.
As data interfaces, for example standardized interfaces, in particular NTDS, RS232, RS422, ETHERNET, IR, or BLUETOOTH interfaces are used.
As decoy ammunitions, those with RF, IR, and combined RF/IR active compositions as well as radar reflectors known per se (Airborne Radar Reflectors) are used.
As a fire control calculator, preferably a personal computer, a micro-controller control or an SPS control is used, with the fire control calculator transmitting the determined data for deploying the decoy formation to the decoy launchers via a standardized data interface, in particular via a CAN bus (Controller Area Network Bus).
Here it is a preferred embodiment of the present invention if a radio frequency reflector, in particular a radar reflector, preferably a corner reflector, preferably a radar reflector having eight tri-hedral corner reflectors (tri-hedrals), in a particularly preferred manner a corner reflector known per se; preferably in the form of nettings or foils, is used as a decoy.
The protective system apparatus in accordance with the invention, which is suited for implementing the method in accordance with the present invention, is equipped with:
A suitable decoy launcher may, e.g., include the following components:
Further advantages and features will become evident from the description of an exemplary embodiment and from the drawing, wherein:
a is a schematic top view of an exemplary decoy formation deployed in accordance with the invention, as a countermeasure against an attacking RF-guided missile;
b is a schematic lateral view of an exemplary decoy formation deployed in accordance with the invention as a countermeasure against an IR-guided missile;
A missile attacking the ship to be protected is detected, located and identified by means of suitable sensors (
By means of suitable sensory equipment the current wind speed and direction of wind is detected continuously (
The ship's own data is equally detected by means of suitable sensory equipment. In the exemplary case, travelling speed, direction of travel, rolling motions and pitching motions of the ship to be protected are detected (
The determined sensor data is transmitted by means of suitable data interfaces to a fire control calculator (
Other possible standardized interfaces include, e.g., NTDS, RS 422, ETHERNET, IR, or BLUETOOTH interfaces.
In the case of a detected approaching missile, a decoy launcher in
Control of the decoy launcher and firing the decoy ammunitions, which are represented in
In the exemplary case, the calculated data of the fire control calculator with regard to optimal course of the ship and ship's speed is transmitted by means of an RS 232 data interface to the ship's central station (
Transmission of the data of the fire control calculator to one or several decoy launchers (
The exemplarily utilized decoy launcher is pivotable at least in two axes (azimuth and elevation) (
The decoy ejector used in the exemplary case includes the following components:
The decoy ammunitions comprise integrated, electronically freely programmable delay elements in which the delay times transmitted from the launcher or fire control calculator, respectively, are stored, so that the activation of the active compositions is initiated following lapse of the delay time (
Lastly, by means of the decoy ammunitions variable in distance, in connection with the dirigible decoy launcher, a decoy pattern is generated that is freely selectable in all spatial and temporal dimensions (
a and 2b exemplarily show a top view and a lateral view, respectively, of a possible decoy formation in the case of an approaching RF-guided missile (
In these figures it is visible that a multiplicity of different decoy ammunitions (in the exemplary case 10 pcs.) may flexibly be staggered temporally, in terms of distance, as well as height and direction, by means of the method in accordance with the invention.
By the method in accordance with the invention it is possible, e.g., to generate a decoy formation which begins in the immediate vicinity of the ship (
By means of a concurrent separation in height (
Missiles intended to fight naval targets are provided for target detection and target tracking with sensors operating in the following electromagnetic wavelength ranges: ultra-violet (UV), visual/electro-optical range (EO), LASER (e.g., 1.06 μm and 10.6 μm), infrared (IR), as well as RADAR (e.g., I/J band and mmW).
With the aid of electronic methods (such as filtering methods) and mathematical algorithms (such as pattern recognition), these modern missiles are capable of discriminating between genuine naval targets (such as ships, drilling rigs, . . . ) and spurious targets by using spectral, temporal, kinematic, and spatial differentiation features.
In order to be able to defend against the multiplicity of various missiles in different threat situations by means of a decoy system, the ability of generating individually adapted, accurately placed decoy patterns in response to any threat situation is indispensable. The specific threat situation is here defined as given by the following parameters:
FIGS. 3 to 7 exemplarily show some temporally and spatially staggered decoy patterns required for defending against a missile, which are composed of single decoys (represented as circles/spheres), which are stored in a database of the computer, and which are adapted to the respective missile type and the associated attack structure.
In accordance with the invention a decoy system is described which calculates by means of a tactical mission calculator the optimal decoy pattern for the specific threat situation for a defense against a missile with regard to the required number of decoy(s) and the spatial and temporal intended coordinates (xn, yn, zn, tn), and subsequently realizes the accurate spatial (xn, yn, zn) and temporal (tn) positioning of the decoys by means of a decoy ejector. In other words, the gist of the invention resides in the fact that virtually any patterns may be formed of decoy clouds even under the conditions of a rough sea.
In the flow diagram of
By means of suitable sensory equipment the wind data (wind speed and direction of wind) as well as the ship's own data (velocity, course, pitching and rolling motions)) is detected and supplied to a central computer (
Warning sensors detect approaching missiles, and the respective missile type as well as its direction of approach and distance are determined. This data is also supplied to the central computer 2. The specific data relevant for a missile defense with regard to the detected missile type is fetched from a correlation database (threat table). This is in particular:
Depending on this missile data and the ship's data (velocity, course, radar signature, infrared signature) and wind parameters (velocity and direction), the optimal decoy pattern in regard of the number of decoy(s) required for defense against the missile as well as their spatial and temporal intended coordinates (xn, yn, zn, tn) is now determined individually (for examples, see
For the case that no data concerning the missile is available in the correlation database, recourse is made to a generic decoy pattern which is also stored in a database for particular threat situations and missiles (for instance a “camouflage screen” in accordance with
In order to realize the predetermined decoy pattern (intended values), an apparatus is used in accordance with the invention which possesses the following components (see
For the purposes of the further description, reference is made for simplicity to the decoy pattern represented in
In order to realize the predetermined decoy pattern (intended values), in accordance with the invention the following calculation steps are performed by means of the computer (
The values thus calculated are now converted into machine instructions, and the equipment described in
In the following, a specific exemplary embodiment of the invention shall be described.
Sensor for detecting the rolling and pitching motions (
The ship's own movements, rolling and pitching, are detected by gyroscopic stabilization equipment, preferably by an inclinometer.
Computer for the calculation of the firing data (
Basically all the customary computers 2 are suited, however preferably a microprocessor-based PC or SPS controls are employed.
The computer calculates from the intended coordinates (xn, yn, zn, tn) of the decoys the temporal staggering (###t) and through the given ballistics (at an identical velocity of departure v0) by means of a mathematical approximation method, e.g., ‘Runge-Kutta method’, the firing azimuth ###n, the firing elevation ###n, and the required flight time and thus the effective distance dn of the single decoy ammunitions.
The calculated data is converted by control equipment, preferably servo-controllers, into machine instructions for the above described, 2-axis launcher (
The launcher movable in two axes is realized by means of electric, hydraulic, or pneumatic directional drives. Preferably an electric drive is used which either acts directly on the launching platform, or preferably indirectly transmits the movement to the launching platform through the intermediary of a transmission. The power of the drives for the azimuthal directing movement and the elevational directing movement is adapted to the masses to be moved and torques. In order to be able to reach an adequate reaction speed, and in order to be able to compensate the ship's own movements, the drives are designed such that an angular velocity of more than 50 DEG/s, or an angular acceleration of more than 50 DEG/s2 (positive and negative acceleration) is achieved both for the azimuthal directing movement and for the elevational directing movement.
The directing range is designed such that when taking into account the details of the launching platform, a firing direction in azimuth of 0 DEG to 360 DEG and in elevation a firing direction of 0 DEG to 90 DEG is achieved. Programmable firing restrictions were realized, so that firing the decoy ammunition in the direction of the ship's superstructures should be avoided. For safety reasons preferably program memories on an EPROM basis are employed.
A launching platform having a multiplicity of individually controllable launching elements (
The launching platform is designed such that firing of at least 20 single decoys is possible. Preferably any decoy ammunition may be fired singly. In addition it is realized that programming of the flight time of the decoy ammunitions to the desired effective distance is performed through the intermediary of the launching platform. The interface with the decoy ammunition may be realized through contacts, however is preferably realized through an inductive interface so as to avoid corrosive influences on data transmission.
Decoy ammunitions with programmable delay elements which may be programmed from the launching platform through the intermediary of a data interface (
The decoy ammunitions are designed such that all have the same velocity of departure (v0). This is necessary in order to ensure the correct and accurate placement of the decoys on the basis of the computer's ballistic calculations. The maximum flight distance preferably is at least 100 m. The vo is adapted in correspondence with the ammunition's weight, the drag coefficient (cw), and the front end surface area (A).
The decoy ammunitions each comprise a programmable delay element, so that the flight times until taking effect at the intended coordinates (xn, yn, zn) are variable and may be programmed immediately prior to launching by means of the launching platform. The interfaces with the launching platform are preferably made to be inductive, i.e. through a respective coil system.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP04/09736 | 9/1/2004 | WO | 12/1/2006 |