RU2366885C1 - Method for non-lethal effect at human organs of vision with help of ehf-radiation and device for its realisation - Google Patents

Abstract

FIELD: physics, optics.

SUBSTANCE: invention is related to the field of effect at human organs of vision located behind optical devices with application of EHF-radiation as affecting factor. Method consists in effect at human organs of vision, which are located behind optical devices, by electromagnet radiation of millimetre range, besides, wave length is selected in the range of 8.75…8.8 mm, which corresponds to window of atmosphere transparency and transmission of radiation through optical devices. Moreover, radiation energy flux density is set, which makes a human being to responsively shut the eyelids. Device comprises movable platform, on which sighting accessory is installed, as well as unit of electromagnet effect at human organs of vision. Besides unit for effect at human being is arranged in the form of radiating antenna coupled with generator of electromagnet radiation of millimetre range of wave lengths.

EFFECT: improved efficiency of non-lethal effect at human organs of vision, including those behind optical devices and difficulty of protection against effect.

2 cl, 1 dwg

Description

The invention relates to the field of action on human organs of vision located behind optical devices, using EHF radiation as a damaging factor.

Known methods of damaging laser tissues of the eye with a therapeutic purpose, for example, for the formation of adhesions between the exfoliated retina and sclera (acc. Application Germany No. 1566107, publ. 02.09.76, MKI A61B 17/36) or for opening the lens capsule (a.s. USSR No. 581941 dated 12/12/72, MKI A61F 9/00).

At present, it is also known about the method of non-lethal exposure of the enemy’s organs of vision by laser radiation and the development of weapon systems that implement it [US Air Force Laser Illuminators, June 15-28, 1998, NDIA 14 ^th Annual Security Technology Symposium Williamsburg, VA]. In this case, laser emitters are used to blind the enemy by exposing the retina to coherent optical radiation of low and medium power (100-500 mW). Such an effect is completely reversible, since it does not cause injury. Blinding causes a person to lose part of the visual field, decrease the resolution of the eye and contributes to additional psychophysiological effects (a feeling of uncertainty, a sense of fear, an avoidance reaction). As a result, a subject who has been blinded significantly reduces their combat effectiveness.

The Saber 203 device that implements this method is a laser emitter placed in the barrel of the M-203 grenade launcher instead of explosive ordnance, and a power supply that is attached to the grenade launcher from the outside. The device can be used both to illuminate the target, and to affect the organs of vision of the enemy with the aim of blinding him.

The HALT device is an improved version of the Saber 203. Its effect is to illuminate firstly with continuous laser radiation, which after 10 seconds goes into flickering mode in order to increase the irritating effect and disorientation of the enemy. In addition, HALT dazzles at significantly greater distances than the Saber 203, both in daytime and at night, and provides lighting from a distance of about one kilometer.

The specified method and the devices implementing it are selected as a prototype.

The disadvantage of this method is the very mechanism of the action of laser radiation on the organs of vision, in which the radiation penetrates the retina [Radi J. The action of powerful laser radiation: Trans. from English - M .: Mir, 1974]. In this case, laser radiation of the visible wavelength range is focused on the retina of the eye into a very small spot. If the emitter is not very far away, its power may be enough to cause organic damage to the retina. If the emitter is located at relatively large distances from the target, then the power of the radiation that has entered the eye may not be enough to disrupt one or another operator activity, especially if the emitter is not located in the center of the observer's field of view.

In addition, the use of laser systems in combat conditions, characterized by the presence in the air of an increased concentration of dust and smoke particles, can be seriously difficult.

The objective of the present invention is to reduce the disadvantages of the prototype by eliminating the application of the enemy irreversible severe damage to the organs of vision, leading to impaired visual function, as well as providing the possibility of using a complex of weapons in difficult dusty environments and increasing the effectiveness of the impact on the organ of vision, when the angle between the optical axis of the beam and optical axis of the eye (including located behind the optical device) exceeds the size of the central fossa of the organ of vision.

The technical result consists in increasing the effectiveness of non-lethal effects on the human organs of vision, including those located behind optical devices, and the difficulty of protection from exposure.

The achievement of the technical result is ensured by the fact that in the non-lethal method of influencing the human organs of vision located behind optical devices with electromagnetic radiation of the millimeter range, the wavelength is selected in the range of 8.75 ... 8.8 mm, which corresponds to the window of transparency of the atmosphere and the passage of radiation through optical devices, and set the density energy flow, causing a person's reflex closure of the eyelids.

In the claimed method of exposure to humans, the task is solved by the totality of the claimed features.

The difficulty in protecting against exposure is achieved by the fact that the irradiation of the human organs of vision is carried out by electromagnetic radiation lying outside the visible range, so the effect is as unexpected as possible, and therefore more effective.

The above technical result is achieved by a device that implements the inventive method, comprising a movable platform, an aiming device and a block of exposure to human organs of electromagnetic radiation. In this case, the human exposure unit is made in the form of a radiating antenna coupled to an electromagnetic radiation generator of the millimeter wavelength range, where the working wavelengths correspond to the transparency window of the atmosphere and ensure the passage of radiation through optical instruments, and the energy flux density causes the person to have a reflex eyelid closure.

The implementation of the generator of electromagnetic radiation of the EHF range will allow you to quickly and efficiently affect the human organs of vision located behind optical devices, as well as openly located. For this, it is advisable to use electromagnetic waves with a working wavelength of 3 ... 3.3 mm or 8.3 ... 8.8 mm and an energy flux density of 5 to 10 W / cm ² . These wavelengths correspond to the windows of transparency of the atmosphere [O. Betsky. Millimeter waves and promising areas of their application. // Foreign electronics. 2002, No. 5], and the selected energy flux density of EHF radiation leads to intolerance of pain in a person a few seconds after the start of irradiation [Burlakov K.Yu., Naumov ND, Panteleev SV An analytical model of the thermal effect of EHF radiation on biological tissues // Biomedical Radioelectronics. 1998, No. 4, pp. 30-33].

It is known that for EHF radiation, the penetration depth of electromagnetic energy into biological tissues is tenths of a millimeter. Electromagnetic waves of this range are strongly absorbed by water and aqueous media and, when exposed to biological tissues, are almost completely attenuated in their upper layers. With intense impacts, a noticeable heating of the tissues occurs and pain occurs.

It is known that the external tissues of the human eye - the cornea and conjunctiva - are covered with tear fluid, which is constantly produced in small volumes and protects them from drying out [Fundamentals of Sensory Physiology: Trans. with English / ed. R Schmidt. - M.: Mir, 1984].

Thus, the effect of EHF radiation on the organ of vision is limited by its interaction with the tear fluid and will be absorbed by the cornea on the front surface of the eye. It is also known that the eyes of mammals are not able to independently adjust the temperature to the required level and its increase will inevitably lead to reflex closure of the eyelid [Possible Acute Effects of Overexposure to MMWS: Eyes, Air Force Research Laboratory, Directed Energy Bioeffects Division, Brooks AFB, TX 78235; Department of Biology, Trinity University, San Antonio, TX 78212; Naval Health Research Center Detachment, Brooks AFB, TX 78235; Veridian Engineering, Inc., Brooks AFB, TX 78325, Manuscript received May 19, 1998; revised manuscript received 15 February 1999, accepted 11 Septembre 1999]. In this case, the impact of EHF radiation on the enemy’s organs of vision will inevitably lead to the disruption of any operator’s activity (driving, shooting, observing, etc.).

It is known that an optical device from the point of view of electromagnetic radiation passing through it is a waveguide of variable cross section. The elements in it made of dielectric materials absorb a part of the energy of electromagnetic radiation. Various types of waves can propagate in a circular waveguide. The smallest possible wavelength of electromagnetic radiation that can still propagate in a circular waveguide corresponds to a wave of type H11. The critical wavelength of type H11 in a circular waveguide is 3.41 of the radius (1.7 diameter) of the waveguide. As the radius of the waveguide decreases, the critical wavelength of the radiation propagating in the waveguide decreases [A.L. Feldstein, L.R. Yavich, V.P. Smirnov. Guide to the elements of waveguide technology. M.: Soviet Radio, 1967].

On the other hand, the attenuation of electromagnetic radiation passing through a dielectric (for example, optical glass) rapidly increases with increasing frequency [S. Baskakov. Fundamentals of electrodynamics. Textbook for universities. M .: Soviet Radio, 1973].

Therefore, the smallest losses when passing through the optical device will have electromagnetic radiation, the wavelength of which slightly exceeds the critical wavelength of type H11 for the waveguide formed by the device body. In a first approximation, we can assume that this critical wavelength should be 1.75 times greater than the characteristic size of the narrowest part of the device, which, as a rule, is the aperture diaphragm.

The image of the aperture diaphragm, created by the eyepiece and called the exit pupil, has a size corresponding to the average size of the pupil of the human eye, and is ~ 5 ... 6 mm [Optics in military affairs. M.: Publishing House of the Academy of Sciences of the USSR, 1948, p. 47, 228, 232, 238]. Therefore, for numerous telescopic systems built on the principle of Kepler’s pipe (binoculars, sighting tubes, etc.), the minimum geometric dimensions of the narrowest part cannot be less than the specified value.

Thus, electromagnetic radiation with a wavelength of 8.75 mm is the most effective for influencing the human organs of vision located behind optical devices and corresponds to the transparency window of the atmosphere. In this case, the presence of dust is not an obstacle to the propagation of EHF radiation, since the radiation wavelength is more than an order of magnitude greater than the maximum size of particles in the air.

A comparable analysis of the proposed method and device with the prototype shows that the claimed objects meet the criterion of "novelty."

In support of the criterion of "industrial applicability" we consider an example of a specific implementation of the device for the implementation of the proposed method.

The drawing shows a system of action on the human organs of vision, using the above effect, where:

1 - person (object of influence);

2 - optical device;

3 - movable platform;

4 - a radiating antenna;

5 - sights;

6 - generator of EHF radiation.

Upon detection of the optical device 2, the system mounted on the movable platform 3 is delivered to the position from which it is supposed to carry out the action, after which, using the sights 5, the radiating antenna 4 is guided to the location of the device. After the antenna is oriented in the necessary direction, the EHF-generator 6 is launched and electromagnetic waves of the EHF range are emitted to the location of person 1, who is observing through an optical device.

EHF electromagnetic radiation penetrates through an optical device and, interacting with the tear fluid of the human eye, increases the temperature of the cornea, which will inevitably lead to reflex closure of the eyelid and, as a result, to disruption of any operator’s activity (driving, shooting, observing and etc.).

Thus, the proposed method and device for influencing the human organs of vision provide for its effective defeat, exclude the enemy from causing irreversible serious damage, leading to impaired visual function, and complicate protection from this effect.

Claims (2)

1. The method of non-lethal exposure to the human organs of vision, including exposure to the organs of vision located behind optical devices, electromagnetic radiation, characterized in that the exposure is carried out by electromagnetic waves of the millimeter range with a wavelength of 8.75 ... 8.8 mm, corresponding to the transparency window of the atmosphere and the passage of radiation through optical instruments, and with a density of energy flow, causing a person to reflex closure of the eyelids. 2. The device of non-lethal effects on the human organs of vision, containing a movable platform, on which the sighting device and the unit for the impact of electromagnetic radiation on the organs of human vision are installed, characterized in that the unit for the impact of electromagnetic radiation on the organs of human vision is made in the form of a radiating antenna coupled to a generator electromagnetic radiation of the millimeter wavelength range, the working wavelengths of which correspond to the window of transparency of the atmosphere and provide passage radiation through optical instruments, and the density of the energy flux causes a person's reflex closure of the eyelids.