RU2388013C2 - Method for functional jamming laser systems for searching for submerged underwater objects and device for realising said method - Google Patents

Abstract

FIELD: physics, optics.

SUBSTANCE: invention relates to laser engineering and can be used for protecting underwater objects from active laser search systems. According to the method for functional jamming laser systems for searching for submerged underwater objects, the target surface laser tracking system is auto-tracked and exposed to powerful laser radiation at wavelength closer to the wavelength of the system being jammed. In order to increase operational security of the underwater object, flares of the underwater laser field created by the surface laser source of the system being jammed during accidental focusing of radiation of this source by the wavy surface of the sea are also detected. The direction to the brightest of the detected flares is determined and powerful laser radiation is emitted in that direction.

EFFECT: increased operational security of the underwater objects.

2 cl, 2 dwg

Description

The invention relates to the weaponry technique of the submarine fleet and can be used to protect underwater objects (software) from airborne laser search tools, as well as to suppress laser communication systems with enemy underwater objects, disable laser depth gauges, sea lidars, etc. .

There is a method of searching for submarines in the underwater position by aircraft laser ranging systems (Patrakov Yu.M., Zakomoldin I.M., Zavyalov A.K. Optical location visibility of ships and problems of their protection against detection by laser location systems. // Marine Radioelectronics, 2005, No. 4. - S.46-50).

A known method of destroying objects using laser radiation, which is implemented in the development of laser weapons YAL-1A ABL (USA, the head developer of Boeing), a multipurpose optical suppression system developed by EADC (Germany), a land and sea-based laser system ARMS (USA) et al. (see, for example, in the collection "New Information Technologies" dated August 12, 2006, the article "New Laser Weapons" it new. com.ua/24548.html., the article by P. P. Makarov "Laser Weapons "In the collection" Inventors "inventors.ru/index.asp mode = 1934; article by Sokolov Prospects for laser weapon »http://pentagonus.narod.ru/army/stat/w2.htu).

In the known method, the target is detected and a high-power laser is pointed at it, the target is tracked along the angular coordinates and irradiated with damaging laser radiation.

The known method cannot be used when direct determination of the direction to the target is impossible, for example, if there is excited sea water between the direction finder and the target, which leads, in particular, to random refractions of radiation from the target and the combat laser.

There is a method of homing power radiation to a target by means of wavefront reversal (see V.Ya. Zel'dovich, V.V. Shkurov / Wave treatment / http: //rusnauka.ru/lib/physic/wavfrount/l/obrwavr.htm; V.Ya. Zel'dovich, N.F. Piteletsky, V.V. Shkurov / Wavefront reversal / p.22/ M .: Nauka, 1985), containing the guidance of an auxiliary pulsed laser on the target, interception reflected by the target radiation by the aperture of a power laser, wavefront reversal and amplification of intercepted radiation.

In the known method, the backward wave at the return path of the amplifier removes the stored energy and is accurately delivered to the target with theoretically complete compensation for distortions associated with the inhomogeneities of the target – reversal system path, as well as with imperfections in the manufacture and alignment of all elements of the optical path.

However, the known method is not effective for hitting surface targets from aboard submerged software, because for its implementation, it is necessary to determine the coordinates of the target through the excited surface of the sea and use an auxiliary laser with unacceptably high power, while the radiation of this laser can be intercepted due to random refractions when the excited sea surface passes in an unacceptably wide angular field (the interception zone with a probability of more than 80% represents a cone with an angle between the axis and the generatrix of about 10 °).

Thus, the known method is not suitable for the functional suppression of laser locators to detect underwater objects due to the impossibility of covertly accurate submission of auxiliary radiation from under water to the underwater object.

It is theoretically possible to modernize the known method without using an auxiliary stand. In this case, the “suppressed locator — laser amplifier and reversing system” should function as a self-excited system. However, a necessary condition for the self-excitation of this system is the high-precision laser guidance of the underwater object on the underwater locator and precision auto tracking along the angular coordinates of this locator. With a known sequence of actions, the necessary condition for self-excitation is not feasible.

The closest in technical essence is the method of hitting targets with sea-based laser means, which was used in the development of the U.S. Navy in relation to the HELL-HELLATE (High Energy Laser Low Aspect Target Tracking Experiment), FEL (Free Electron Laser) and other systems (see, e.g. Jane's Defense Week 2004, v 41, No. 35, p.12; Development of naval weapons, status and prospects, facts, discussions, http: //forums.arbase/ru/2007/08/09/topk - 55514.3 - Rasvitie - morskogo - oruzhiya /. Sostoyanie - i - perspektivy. Fakty - diskussii. html).

In the known method based on direction finding, the target is irradiated with pulsed laser radiation for a time sufficient to defeat the latter.

The known method can only be used when the surface of the software, because Neither direction finding of the target, nor guidance of the results of this direction finding of the laser beam are possible through the excited surface due to random refractions of light when passing through the water-air interface. Thus, the main disadvantage of this method is the low stealth of actions.

The aim of the invention is to increase the secrecy of the actions of the underwater object.

This goal is achieved by the fact that in the known method containing auto tracking of the affected surface laser system and irradiating this system with powerful laser radiation at a wavelength close to the wavelength of the suppressed system, the following are additionally introduced:

- detection of glare of the underwater laser field created by the surface laser source of the suppressed system with random focusing of the radiation of this source by an excited water surface,

- determination of directions to the brightest of the detected glare,

- radiation in these directions of power laser radiation.

The figure 1 presents a structural diagram of a system of functional destruction of surface laser means from the board of an immersed underwater object, where:

1 - optical transceiver system,

2 - photoelectronic matrix receiver (direction finder),

3 - selector of the brightest glare (multichannel peak detector),

4 - shaper commands operational guidance,

5 - optical system of two-coordinate operational deflection of the beam (deflector),

6 - power laser

S - radiation (quasi-parallel beam) of the suppressed system,

S _C - power (damaging) radiation,

MP - sea surface,

Bl - flare of radiation S.

The figure 2 presents an example of the structural implementation of a wide-angle system of optoelectronic matrix receivers (ie, structural elements, which are indicated in figure 1 by the numbers "1" and "2"), which consists of 22 lenses with interference filters, 22 matrix photodetectors (CCD - receivers).

The system that implements the proposed method works as follows.

Radiation S of a surface laser locator propagating in water undergoes two competing effects associated with random focusing on large inhomogeneities and scattering on small ones. As a result, a laser pulse propagating through an ensemble of randomly distributed scatterers is decomposed into coherent and incoherent components.

Coherent intensity preserves the shape of the pulse, and incoherent spreads out in time due to superpositions of radiation (scattering) from different regions of space with different time delays.

Of practical interest for submarine search systems are areas (cases) of "weak fluctuations" in which the weakly scattered (coherent) component of the probe pulse is quite pronounced.

It is in these cases that it is possible to provide the necessary energy potential and the required accuracy characteristics for the detection of underwater objects from the reflections of laser pulses from these objects or from the optical inhomogeneities created by them in the ocean.

To detect the enemy’s underwater laser system and covertly target the underwater laser weapon on it, it is proposed to use glare structures of the underwater light field, which are formed during random focusing of the radiation incident on water S.

The crests and troughs of sea waves act on this radiation like a system of optical lenses with randomly changing characteristics.

These "lenses" create fluctuating images (real - underwater and imaginary - surface) of the radiation source (ie, the transmitting optical antenna of the suppressed locator).

Each such image (flare) contains information about the location of the surface transmitter. The radiation of these glare, passing through the optical (mirror-lens) system 1, enters the coordinate-sensitive (matrix) photodetector 2, where the angular position of the glare relative to the instrumental coordinates of the laser weapon system is determined by the number of illuminated elements of the photodetector matrix.

In block 3, the brightest of the recorded glare is revealed. The coordinates (α _i , β _i ) of the selected (in this case, by the criterion of the highest brightness) i-th glare are compared in the block with the orientation (α, β) of the optical axis of the deflector 5.

Based on the results of this comparison, in block 4, teams are formed that uniquely reflect the discrepancies Δα _i = α _i -α and Δβ _i = β _i -β. These commands are received in the deflector 5 for working out the residuals.

When Δα _i = Δβ _i ≈ 0, a start-up pulse of laser 6 is formed in block 4. The optical axis of the laser is aligned with the optical axis of the receiving optics of system 1. Thus, the radiation of the power laser 6 is directed to the place where the selected one was detected (for example, the brightest) flare.

The requirement for the speed of pointing to the place of registration of the glare (i.e., the speed of performing registration operations, selecting flares, working out the guidance and laser start commands) should not exceed the time T - “freezing” of the excited surface and the practical “immobility” of the suppressed laser locator. This time T can correspond to the interval (from 1 to 10) ms.

In accordance with the principle of reversibility in optics, the laser pulse of the emitter 6 is guided along the same optical path as the pulse from the brightest glare. In this case, the power pulse of the laser weapons of the underwater object passes through the surface of the sea, which has not changed since the probing laser pulse of the suppressed system passed through it. Given the practical immobility of the underwater locator over time

the direction of the probe beam is reversed (here: R is the surface range to the suppressed target, h is the immersion depth of the software, α * and β * are the direction of the glare relative to the topocentric coordinates of the software).

A significant part of the radiation of the underwater transmitter is fed to the photodetector of the surface locator. The intensity of this radiation is close to S _n .

,

,

where: S _oc - the intensity of the emitted signal,

k _B (h) · k _atm (R) is the integral attenuation of radiation, respectively, in water and in the atmosphere,

And _eff is the effective area of the receiving antenna of the suppressed locator,

Ω is the surface divergence of the suppressive radiation.

,

,

here: F is the focal length of the water "lens" (F = 5 ÷ 50 m),

d is the diameter of the laser beam (d = 10 ^-2 m).

Even if the power of the laser 6 is not significantly different from the power of the laser transmitter of the suppressed location system, a laser pulse of 10 ¹² ÷ 10 ¹³ times higher intensity will be delivered to the input of the photodetector of this system in comparison with the reflected signals.

As a result of exposure to a series of N such damaging pulses (N∈ [1 ÷ 10000]), the photodetector of the attacked system will be destroyed or at least temporarily blinded (functionally affected).

In order to avoid an attack of their own laser communication systems with submerged software, the functional suppression system can be supplemented by a friend or foe decoder 7. In this case, the attack is carried out after receiving and processing n pulses of the surface transmitter, i.e. solving the "friend or foe" problem.

Systems 1 and 2 must satisfy the conflicting requirements of optical selection of a narrow wavelength range in a wide angular field with a sufficient effective pupil area of the receiving optical antenna.

The resolution of this contradiction is possible, for example, by increasing the number of receiving channels. Figure 2 shows an embodiment of a wide-angle underwater photodetector system, which consists of 22 receiving lenses, each of which is equipped with an interference optical filter in the entrance pupil and a matrix photodetector in the image plane (i.e., systems 1 and 2 are made 22-channel) . Each photodetector channel receives a signal in a relatively narrow (units of degrees) angular field. Moreover, the total angular field is tens of degrees. All photodetectors function as a single system. Power radiation is deflected accordingly with respect to the optical axis (s) of the receiving channel, in which the longest living (brightest) glare is selected.

The technical and economic advantage of the proposed technical solution consists in the fact that to defeat the enemy’s laser means with narrow-field (secretive) radiation from under the water, it is not necessary to detect the carrier of the laser means. It is enough to fix underwater glare created by the enemy’s transmitter. In this case, in order to eliminate the conditions for inducing power radiation onto it, the adversary must find ways to eliminate waves at sea and / or to cancel the principle of reversibility of the propagation paths of light quanta, i.e. no real protection against the proposed method of functional suppression exists.

Claims (2)

1. A method for the functional suppression of laser systems for searching for submerged underwater objects, comprising auto-tracking the affected surface laser system and irradiating this system with powerful laser radiation at a wavelength close to the wavelength of the suppressed system, characterized in that, in order to increase the stealth of the actions of the underwater object, introduced:
detecting glare of the underwater laser field created by the surface laser source of the suppressed system with random focusing of the radiation of this source by an excited sea surface,
determination of directions to the brightest of the detected glare,
radiation in these directions of power laser radiation. 2. The device for implementing the method according to claim 1, containing an optical transceiver system 1 placed on the body of the underwater object and receiving radiation S of the surface laser locator, which is fed to the photoelectronic matrix receiver 2, consisting of 22 lenses with interference filters and 22 matrix photodetectors ( CCD receivers), where the angular positions of glare relative to the instrumental coordinates of the laser suppression system are determined by the number of illuminated elements of the photodetector matrix, selector 3 (multichannel peak detector) reveals the brightest of the recorded glare, the coordinates of which (α _i , β _i ) are compared in the block of the command generator of the operational guidance 4 with the orientation (α, β) of the optical axis of the deflector 5, the command generator of the operational guidance 4 from the results of the comparison generates commands , reflecting the residuals Δα _i = α _i -α and Δβ _i = β _i -β, which again enter the deflector 5 for their processing, block 4 generates at Δα _i = Δβ _i ≈ 0 a laser trigger 6, the optical axis of which is aligned with optical axis of the receiving optics of system 1, radiation S _c power laser 6 is guided along the same path to the place where he is registered been accumulated flare passes through the surface of the sea and enters the photodetector freeboard locator, where the impacts series affecting pulse occurs incapacitate photodetector topside radar system, the decoder "own “alien” 7, included in the scheme of the system of functional suppression of an underwater object as a functional addition and serving to avoid the defeat of one’s own search forces by solving problems and determining whether the laser search signal belongs to one’s forces or one’s adversary.

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