The present application is based on International Application No. PCT/EP2005/053582, filed on Jul. 22, 2005, which in turn corresponds to FRANCE Application No. 04 08188 filed on Jul. 23, 204, and priority is hereby claimed under 35 USC §119 based on these applications. Each of these applications are hereby incorporated by reference in their entirety into the present application.
This invention relates to a method and system for activation of the charge in a munition. It also relates to a munition fitted with a high precision activation device. Finally, it relates to a system for neutralisation of a target. The invention is applicable particularly to hit hidden targets for which a direct impact with these targets is not necessary.
Guided or unguided munitions fired from a distance by any type of device, for example a pyrotechnic, electric or pneumatic gun, or various mechanical launchers, may have a direct kinetic effect on the objective. This effect may or may not be lethal depending on the firing conditions and the nature of the projectile (for example metal or rubber). These munitions may also have a reinforced or indirect effect by providing the munition with a secondary device such as:
For example, applications of indirect effects relate to:
The problem with this type of application is application of the secondary device at the right moment. There are several solutions.
It is known that target proximity can be detected by radar or optical type active means, or by magnetic or capacitive influence. However, proximity detection devices are not always satisfactory, for example for targets without a usable electromagnetic or magnetic signature or in complex environments.
It is known that remote control means can be used, for example for sending a radio signal at a precise instant. Such a solution is complex and expensive to implement and is consequently unacceptable.
It is also known that a secondary device can be triggered by an effect purely internal to the munition, for example by timing. Since the velocity of the munition is assumed to be known, a distance traveled can be deduced and therefore a trigger location can be defined. The main disadvantage of this solution is that it is not precise. The precision of the trigger distance is hardly compatible with operational needs. This need is typically for a precision better than a meter for a firing distance of the order of one kilometer. Uncertainties on the dynamics of the munition's movement are such that this precision of 1 in 1000 would seem to be unachievable.
One particular purpose of the invention is to overcome the disadvantages mentioned above, particularly by enabling a sufficiently precise trigger position without complex implementation. To achieve this, the purpose of the invention is a method for activating a munition close to a target using a laser beam that illuminates an object close to the target, firing of the munition charge being activated when the munition detects the laser spot reflected by the object.
Firing is activated at a time Δt1 after the time t0 at which the laser spot is detected, and the time Δt1 may possibly be approximately zero.
The line of sight of the munition preferably passes close to the object. The object may be an obstacle behind which the target is concealed.
The head of the munition is fitted with at least one optical detector.
The invention also relates to a system for activation of a munition close to a target, the system comprising at least:
When the laser source is coupled to the gun firing the munition, the sight direction of the gun passes close to the object.
The control unit emits the firing signal at a time Δt1, possibly equal to zero, after the detection signal reception time t0.
For example, the optical device comprises optical detectors placed at the periphery of the munition head.
The invention also relates to a munition comprising an activation device composed of at least one optical detector and a control unit, the optical detector being designed to detect a signal produced by an object close to a target.
Preferably, detectors are placed at the periphery of the munition head. Optical detectors may for example be located around the periphery of the same cross section.
Advantageously, the optical aperture of detectors is elliptical, the major axis of the aperture being oriented perpendicular to the axis of symmetry of the munition.
For example, the angle α between the optical axis of a detector and the axis of the munition is equal to approximately 60°.
Advantageously, the optical detector 43 and the control unit are made for example in the form of a kit adaptable to existing munitions to replace a control device originally fitted on the munition.
Finally, the invention relates to a system for neutralisation of a target comprising at least one munition like that described above and a laser source to illuminate an object in the vicinity of the target, firing of the munition charge being activated by the control unit using detection of the laser spot reflected by the object.
Other characteristics and advantages of the invention will become clear after reading the following description with reference to the attached drawings that represent:
The munition 23 is fitted with a directional optical detector designed to detect the laser spot 24 reflected by the object close to the target X, in fact the dwarf wall 3 in the example in
Therefore at time t0, the optical detector of the munition detects the laser spot 24 and the charge of the munition is fired after a pre-set delay Δt1. Δt1 may be set equal to zero if required. In this case, the delay created is the natural firing delay that is sufficient for the charge to explode a few meters after t0. The munition comprises an optical device to detect the spot. It also comprises a control unit to process detection signals received by the optical device, to create the delay Δt1 if required and to create a signal to activate firing of the munition charge using a received detection signal.
It is assumed that the obstacle 3 is rough, in other words in particular that it comprises surface irregularities with dimensions larger than the laser wavelength, and that it is not completely absorbent, so that the reflected laser signal 24 is not very directional and its intensity is sufficient so that it can be detected at a few meters. These conditions frequently occur in reality and therefore are not very restrictive.
The distance M0H depends on the overflight height of the munition over the obstacle, the point illuminated on the obstacle and the orientation angle α of the detector, assumed to be known perfectly. It follows that:
M0H=IH/tan α (1)
Consequently, there is an absolute error Δ(M0H) given by the following relation:
Δ(M0H)=Δ(IH)/tan α (2)
The uncertainty Δ(IH) depends particularly on errors in aiming the laser line of sight and the firing line, the characteristics of the laser spot on the obstacle 3 and characteristics of the onboard detector in the munition 23. The error Δ(IH) for a firing distance of the order of one kilometer may be of the order of 2 meters.
The choice of the angle α is important. This angle α depends on the arrangement of the detector in the munition 23 and more particularly the inclination of its optical axis with respect to the axis of the munition. If α is small, the term 1/tan α becomes very large and tends towards infinity when α tends to 0.
for α=45°: Δ(M0H)=Δ(IH)
for α=90°: Δ(M0H)=0
Therefore, it is advantageous to choose an angle α close to 90°, but there are two disadvantages:
A good compromise can be to use an angle α of the order of 60°. In particular, for α=60°: Δ(M0H)=Δ(IH)/1.73. This gives a required order of magnitude for Δ(M0H).
Starting from point M0 corresponding to time t0, the charge is fired with a delay:
Δt=M0MF/v (3)
where v is the velocity of the munition assumed to be known with a negligible relative error compared with the relative error on the distance M0MF, itself equal to Δ(M0MF)/M0MF.
The munition is composed of a body, not shown, for example containing the pyrotechnic charge and the head 41. Conventionally, the head has an approximately conical shape around the axis of symmetry 42 of the munition that is coincident with the axis of its trajectory during the firing phase. The head 41 of the munition comprises an optical device that in particular will detect the laser spot reflected by an obstacle 3. This optical device comprises optical detectors 43 placed around the periphery of the head 41 of the munition. For example, the optical detectors are infrared detectors. The angle formed between the optical axis 26 of a detector 43 and the axis 42 of the munition is denoted as α. In accordance with what has been described above, the angle α may for example be of the order of 60°. The field of the optical lens is a parameter to be adjusted as a function of the mission characteristics. A typical order of magnitude is an aperture β=15°. This aperture may be circular or advantageously elliptical, particularly as described below.
For example, the optical detectors are arranged on a single cross section of the head and are distributed around the periphery of this section. They may be distributed uniformly, with a sufficiently large number to cover the entire space and more particularly to take account of the roll of the munition. The position of the munition in roll is not usually known. Several detectors then have to be distributed around the periphery of the head, preferably on the same cross section. These detectors may be distributed uniformly and symmetrically about the axis 42 of the munition. It is advantageous to use optics with an asymmetric aperture, for example including a wide field in the plane perpendicular to
If the munition is stabilised by the gyroscopic effect, in other words by self-rotation about its axis 42, the device with several detectors is also useful to reduce uncertainty on the detection time. For medium calibre artillery munitions, for example 40 millimeters, this rotation velocity can typically be equal to or greater than 1000 turns per second. Two detectors may be sufficient under these conditions.
The head also comprises an electronic unit designed particularly to process optical signals output by detectors and then to create the munition charge firing activation signal, possibly with a delay t1. The electronic unit is connected to the optical detectors for this purpose.
A munition for which the head is shown in
Advantageously, the optical detector 43 and the control unit are made for example in the form of a kit adaptable to existing munitions to replace a control device that was originally used in the munition, for example to replace an electronic time fuse or an impact detector. The old control device is then taken out, for example by unscrewing, and replaced by the adaptable kit.
Number | Date | Country | Kind |
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04 08188 | Jul 2004 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2005/053582 | 7/22/2005 | WO | 00 | 1/23/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2006/010741 | 2/2/2006 | WO | A |
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4199686 | Brunsting et al. | Apr 1980 | A |
4269121 | Sochard | May 1981 | A |
4903602 | Skagerlund | Feb 1990 | A |
7089865 | Regev | Aug 2006 | B2 |
7143539 | Cerovic et al. | Dec 2006 | B2 |
Number | Date | Country |
---|---|---|
2 747 185 | Oct 1997 | FR |
2132740 | Jul 1984 | GB |
03106911 | Dec 2003 | WO |
Number | Date | Country | |
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20070193466 A1 | Aug 2007 | US |