RU2497064C2 - Target destruction laser system - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: proposed system comprises amplifier laser and guidance laser. Guidance laser incorporates dissipating optical system. Amplifier laser is composed of two spherical mirrors, one semi translucent with identical curvature radius R located at one mirror axis at 2R from each other. Said laser operated in amplification mode. Beams reflected from target and passing through sphere center will be amplified so that said laser generated radiation flow that moves toward the target over reflected guidance laser beam.

EFFECT: fast aiming, higher accuracy of hits, possibility to hit group target.

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Description

The invention relates to space and military technology, namely to laser weapons, in particular, to non-contact protective equipment.

The proposed laser system for hitting a target can be used to protect spacecraft and astronauts in outer space from a micrometeorite swarm, as well as to protect people and equipment and other objects from firearms. In addition, the proposed system can be used to destroy unmanned aerial vehicles on the battlefield, including microscopic ones, to protect armored vehicles from armor-piercing shells, etc.

Among peaceful applications, the proposed system, the system can be used as a means of controlling locusts and protecting runways from airfields. With the appropriate power of the device, the system can be used to protect the Earth from meteor shower, as well as as shock components of a missile defense system for aimed destruction of maneuvering hypersonic targets. In this technical solution, defeat is understood as automatic targeted irradiation of objects.

The prior art laser system for hitting a target, including a working laser and a guidance laser [1] (see patent RU 2380288, CL F41H 13/00, publ. 01.27.2010), which involves the procedure of targeting the target, with the operation targeting (guidance), due to the inertia of the devices, requires a certain, sometimes quite long, time, which in a critical situation can have undesirable consequences. In addition, the known lesion system contains a number of probabilistic parameters, which suggests a number of unsuccessful lesions.

In addition, experimental installations are known from open sources, for example, the 100 Kilowatt solid-state laser of the American military-industrial company Northrop Grumman Corporation (NYSE: NOC) - the American military-industrial company

(man.com/Capabilities/SolidStateHighEnergyLaserSystems/Pages/SolidStateLaserTestbedExperiment.aspx) [2] for military use.

From US 5747720 (publication date 05/05/1998) a laser target system is known. The essence of the invention according to US5747720 [3] is that the laser system for hitting a group target consists of a main laser, a system of mirrors controlled by a microprocessor, two laser amplifiers and a laser backlight. According to the specified invention, the backlight laser scans the affected area ("shield"). The backlight laser radiation reflected from the projectiles hits the sensors, the signal from which is fed to a control unit containing a microprocessor that determines the coordinates of the targets, their direction of movement, and generates a control signal for the mirror segments that determine the direction of the striking rays. The striking beam is formed as follows. The radiation of the main laser (Master laser) is divided using several moving segments of the mirrors into several beams. They fall into laser amplifiers. The rays of the main laser, amplified in the "amplifiers" (amplifier) with a mirror are sent to the affected area.

Known laser systems [1], [2], [3] suggest a procedure for aiming at the target. At the same time, the operation of aiming (guidance), due to the inertia of these systems, requires a certain, sometimes quite long, time, which in a critical situation can have undesirable consequences. In addition, they contain a number of probabilistic parameters, which suggests a number of unsuccessful defeats, and are not intended for the simultaneous defeat of a group target.

On the set of essential features [2] adopted as the closest analogue.

The objective of the invention is to remedy these disadvantages. The technical result consists in automatic aiming of the system without an additional aiming system, which allows to reduce the aiming time and increase the accuracy of the defeat, as well as to ensure the possibility of simultaneous destruction of the elements of the group target.

The problem is solved, and the technical result is achieved by the fact that the laser system for hitting a target, including a working laser, the open resonator of which is made in the form of two spherical mirrors, one of which is translucent, and the guidance laser equipped with a scattering optical system, according to the invention, the resonator operates in amplification mode, and spherical mirrors are made with the same radius of curvature R and are located on the same axis of symmetry at a distance of 2R from each other.

The drawing shows a diagram of the proposed system.

The laser system for hitting a target consists of a working laser amplifier 1 and a laser 2. A laser 2 is equipped with a scattering optical system 3, which allows you to increase the illuminated area of the space in which the intended target (s) can be located 4. The working laser amplifier 1 is a powerful shock laser operating in amplification mode. This type of device has long been known (see sources [4], [5]) and is traditionally used in radiophysical experiments for research on nonlinear optics. It can work on a clearance, or on reflection from one of the mirrors. The resonator of the working laser amplifier is made in the form of two spherical mirrors 5 and 6 with the same radius of curvature R located on the same axis of symmetry at a distance of 2R from each other, i.e. resonator mirrors are diametrically located fragments of one spherical surface centered at point O. Moreover, the front mirror 5 is translucent. A similar type of resonator is well known, and refers to a type that is boundary between stable and unstable generation, and is called concentric (see source [6], pp. 24-25). Amplifier lasers are rarely used for their intended purpose, since sensitive sensors exist to detect weak radiation.

The proposed device operates as follows.

To defeat a single or group target, the radiation flux of the guidance laser 2 is directed to the area where the intended target (s) 4 can be located. Part of the radiation is reflected from the surface of the target (s) 4 and enters the resonator of the working laser through a translucent mirror 5. Since the working laser 1 operates in the amplification mode, the rays reflected from the target (s) 4 passing through the center of the sphere O will be amplified, and, due to the geometry of the resonator, move back in the direction of the target. It is the spherical geometry of the resonator mirrors that ensures that the laser beams reflected from the target and passing through the center of the resonator sphere, reflected from the mirror 6, will also pass through the center of the sphere. The rays reflected from the target passing into the resonator, and which do not pass through the center of the sphere, will fall on the side walls, or, reflected from the rear mirror 6, will go to the side, without creating conditions for generation. Thus, the working laser amplifier 1 almost instantly generates a powerful radiation flux that moves exactly in the direction of the target (s) 4 along the target laser beam 2 reflected from the target (s) 4. The defeat sector is determined by the angular cone, whose apex is at the center of the sphere is O, and the generatrix passes through the boundaries of the front mirror 5.

The radiation from the working laser has a certain divergence angle, i.e. represents a light cone with a vertex in the center of the sphere. Its axis passes through the center of the resonator sphere, and the point where the target is in space at the time of reflection of the backlight from it. From the condition that during the movement of the light beam from the target to the working laser and vice versa, the target will shift to the side, the maximum transverse speed is calculated.

Since the proposed system of preemptive aiming is not performed, the condition of the defeat is determined by the distance that the target travels during the time T = 2R / c perpendicular to the line of sight:

V · T <R · α / 2, i.e. V <α · c / 4,

where T is the time the light travels the distance from the target to the laser and vice versa,

V is the speed perpendicular to the line of sight (lateral speed),

R is the distance from the working laser to the target,

c is the speed of light,

α is the angle of divergence of the laser beam. Since the final formula for speed does not include R, the aiming range of the device is limited by the power of the laser amplifier. Of the characteristics of the target, this formula includes only lateral speed. We calculate it.

V _max = α · c / 4.

The angle of divergence of the laser beam α = 10 ^-3 rad, the speed of light c = 3 · 10 ⁵ km / s. Substituting c and a in we get

V _max = 3 · 10 ⁵ · 10 ^-3 /4=0.75·10 ² = 75 km / s

To date, such a speed is unattainable. The first cosmic velocity - the speed of an artificial Earth satellite - is about 8 km / s, which is much lower than V _max . Thus, the proposed system allows you to hit targets with a lateral speed of less than V _max , which is determined by the angle of divergence, and range by the power of the laser amplifier. Damage to an object (target) is understood as irradiation with its laser radiation in order to achieve a certain result. This may be the failure of photoelectronic sensors. The withdrawal of internal mechanisms, damage to the casing, or complete defragmentation as a result of heat and light shock. The implementation of any of the tasks will be determined by the power of the laser amplifier.

The proposed system can be installed permanently to protect objects such as nuclear power plants, and can also be installed on a mobile platform, such as a tractor, aircraft, spaceship, etc. In addition, to increase the damaging effect, several shock lasers can be combined into a battery and run from a single guidance laser. In this case, the power limit of the damaging beam is removed. The working laser 1 and the guidance laser 2 are components of the same device, although they can be spaced at significant distances from each other.

Sources of information, literature

1. Patent RU 2380288, cl. F41H 13/00, publ. 01/27/2010

2. ems / Pages / SolidStateLaserTestbedExperiment.aspx

3. Patent US 5747720 (publication date 05/05/1998).

4. Karlov N.V. Lectures on quantum electronics. Publisher: Science, Year of publication: 1984, p. 44.

5. Zvelto Orazio. The principles of lasers. Moscow .: World. 1990, p. 485.

6. V.K. Ablekov, Yu.N. Denisov, F.N. Lyubchenko. Handbook of gas-dynamic lasers. - M.: Mechanical Engineering, 1982. P. 25.

Claims (1)

A laser system for hitting a target, including a working laser, the resonator of which is made in the form of two spherical mirrors, one of which is translucent, and a guidance laser equipped with a scattering optical system, characterized in that the beam from the backlight laser reflected from the target directly enters the amplifier in which a beam is generated that is directed back towards the target, and the spherical mirrors of the amplifier are made with the same radius of curvature R and are located on the same axis of symmetry at a distance of 2R from each other ha.