RU199963U1 - Airborne personal protection system of an aircraft from the damaging effects of portable anti-aircraft missile systems - Google Patents

Abstract

The utility model refers to personal protective equipment (PPE) of an aircraft from the damaging effects of portable anti-aircraft missile systems (MANPADS) due to the formation of active interference in the optical-visual control path of MANPADS guidance to the target in the form of incoherent optical radiation directed to the lower hemisphere of the space surrounding the aircraft , the spectral range, the pulse-periodic structure and brightness of which were selected taking into account the possibility of a striking effect on the visual analyzer of the MANPADS operator in the daytime, leading to the physical impossibility of performing the target task assigned to him by the shooter-operator - the implementation of targeted guidance of MANPADS at the target The design feature of the proposed PPE aircraft is that it is made with the ability to generate radiation of active interference in the optical-visual control path for guiding MANPADS to the target, the brightness of which is at least 1.5 Vcd / m, but not more / m, where B is the brightness of the background of the daytime sky in the visible range of the optical spectrum. The technical result achieved when implementing the proposed design of PPE aircraft is to ensure the protection of aircraft from the damaging effects of MANPADS with an optical-visual targeting path from all attack-hazardous directions in during the entire time spent in the attack-hazardous zone with any variations in the brightness of the background of the daytime sky in the combat zone.

Description

The utility model refers to defense equipment, in particular to airborne personal protective equipment (IZ) of aircraft (LA) against the damaging effects of portable anti-aircraft missile systems (MANPADS) equipped with guided missiles (UR) with an infrared (IR) homing head (GOS) ...

MANPADS is designed to destroy jet, turboprop and propeller driven aircraft, as well as helicopters on head-on and catch-up courses with visual visibility of the target (attacked aircraft). Currently, MANPADS are the most effective means of engaging ground-based aircraft, preparation for combat use of which cannot be detected by means of optical-electronic and visual reconnaissance of the enemy, which allows the use of MANPADS suddenly and covertly. Due to their small size and weight, most MANPADS can be used by one gunner-operator for all types of air targets from any unprepared launch position, where the use of any other means of destruction of aircraft is difficult, for example, in a forest, mountainous terrain and within urban areas. The peculiarities of this type of weapon should also include the exceptional simplicity of its operation and user training (gunner-operator of MANPADS).

The development of means from aircrafts against the damaging effects of MANPADS is receiving increased attention in many countries of the world, since, as follows from the results of the study of the causes of combat losses of aircraft and helicopters, more than 90% of aircraft were hit with IC GOS UR, which are part of the Stinger type MANPADS "," Arrow "and" Needle "[1]. It should also be noted that recently there has been an increase in the use of MANPADS by various bandit formations and terrorist organizations to defeat aircraft not only for military, but also for civil purposes [2].

It is quite obvious that in the development of any device, the set of technical solutions used in its design is determined primarily by the purpose and principle of operation of this device. In this particular case, the target function of the claimed device is to ensure the counteraction to the damaging effect on the aircraft from the MANPADS and, therefore, the constructive implementation of the claimed device is primarily determined by the features of the design and operation of the MANPADS.

MANPADS, as mentioned above, refers to ground-based mobile weapons and is a launch tube coupled with a trigger and equipped with an optical-visual targeting device, in which a missile launcher with IR seeker is located. An optical-visual device for guiding MANPADS to a target (attacked aircraft), designed for operating MANPADS in the daytime, is made, as a rule, in the form of a mechanical sight, i.e. in the form of rear sight and front sight mounted on the launch tube at a certain distance from each other, which allows the use of MANPADS in the traditional way for weapons with an optical-visual guidance control path to the target - to launch the rocket from the shoulder of the MANPADS operator. Thus, the sighting device included in the MANPADS serves for visual detection, capture and tracking of the target (aircraft) by the MANPADS operator, the launching mechanism is intended for ground prelaunch preparation for launching and launching the missile launcher at the selected target, and the launch tube is essentially a guiding device providing an aimed launch of the missile launcher.

Most of the known types of MANPADS operate on the "fire and forget" principle. Indeed, the combat work of MANPADS, for example, MANPADS of the "Strela-2" type, as follows from [3], is carried out as follows. After visual detection and identification of the target, the MANPADS operator turns the complex into a combat position. After the IC GOS UR enters combat mode, which takes about 5 seconds, the MANPADS operator manually aligns the aiming line with the direction to the attacked aircraft, i.e. ensures the alignment of the optical axis of the GOS UR with the axis of the sight of the MANPADS launch tube, which ensures target acquisition with a narrow field of view of the IR GOS UR, and after receiving a sound and / or light signal about the target acquisition of the GOS UR by pressing the trigger of the MANPADS trigger, it switches the GOS UR to the start mode target tracking. By pressing the trigger to failure, the shooter-operator launches the missile launcher in the direction of the target. The further flight of the missile to the target occurs autonomously without communication with the MANPADS launcher according to the commands generated by the IC GOS UR. Thus, the process of the combat use of MANPADS includes two successive stages, and at the first stage, the function of the master of the missile guidance system on the target is performed by the MANPADS operator through the eyes, and at the second stage - by the IC seeker of the UR, which performs the function of the receiving element UR homing systems [4, 5].

Individual protection of an aircraft from the damaging effects of MANPADS, as follows from the works [6, 7], can be carried out due to optoelectronic countermeasures of the IR seeker of the attacking aircraft of the UR by forming a damaging effect directly from the aircraft board, leading to functional or physical suppression of the main elements The seeker of an attacking aircraft of the UR, or by countering the process of homing the UR to the target by setting a simulating active interference from the IR seeker in the form of a structured incoherent optical radiation directed at the seeker in a certain way in the spectral sensitivity range of the IR seeker of the UR. A fundamental feature of this type of airborne vehicles from an aircraft of this type is that they counteract the damaging effect on an aircraft from MANPADS only at the second stage of its operation, i.e. only after the targeted launch of the UR. As follows from [8], the maximum operating range of most MANPADS models is about 5-6 km, and the height of damage is up to 3 km, ie. The aircraft is under the threat of being hit from the side of the earth's surface, the radius of which is about 4 km, which makes the aircraft equipped with an onboard IZ facility in the form of an opto-electronic countermeasuring device for the IC seeker of the UR by placing an imitating active interference in the direction of the seeker of the UR, very vulnerable in conditions of simultaneous multidirectional launch of the UR.

An increase in the efficiency of MANPADS functioning, as follows from [8], is achieved mainly due to the improvement of the UR homing systems, which, accordingly, inevitably leads to a significant complication of the design of the missile attack registration unit included in the onboard means from the aircraft (after launch SD) and a formation unit in the direction of the attacking SD simulating active interference towards the seeker. That is why it becomes necessary to counter the damaging effects of MANPADS by using the damaging factor that prevents the MANPADS operator from performing the target task at the first stage of MANPADS operation. This counteraction can be realized through the use in the composition of the executive body of the on-board complex IZ of the aircraft a means of forming active interference in the optical-visual control path for guiding MANPADS to the target, made with the possibility of influencing the visual organs of the MANPADS operator-operator, since, firstly, the organs of the gunner-operator MANPADS are a source of obtaining the most important information necessary for the regular functioning of MANPADS at the first stage, and, secondly, the physiological transformation of optical radiation into the energy of the nervous process of formation of visual images in a person's mind remains unchanged regardless of the constructive implementation of the optical-visual tract control of guidance of MANPADS to the target in the daytime.

One of the most effective means of non-lethal, and, therefore, not falling under international restrictions, physical impact on the gunner-operator of MANPADS, leading to the loss of his ability to perform the target task, is a means of influence using as a damaging factor directed to the lower hemisphere of the surrounding aircraft space of incoherent optical radiation, spectral range, pulse-periodic structure and brightness of which are selected taking into account the characteristics of human perception of visual information.

It is known that the function of human vision is a multifactorial psychophysiological process of converting primary light excitation into visual sensations (the fact of awareness) and is carried out by the so-called. visual analyzer. The human visual analyzer consists of three interconnected links - peripheral, connective and central [9-11]. The peripheral link of the visual analyzer is the human eye, which is a combination of optical and light-sensing systems. The spectral range of sensitivity of the light-receiving system of the peripheral link of the human visual analyzer is from 0.4 to 0.76 μm (visible range of the optical spectrum). The central link of the visual analyzer is located in the occipital lobe of the cerebral cortex of the human brain. The peripheral and central links of the human visual analyzer are connected by an afferent nerve, which performs the function of a connecting link of the visual analyzer. Human daytime vision is due to the difference in the reflection coefficients of solar radiation in the visible range by various objects in the field of view of the human eye. The optical radiation of the visible range perceived by the peripheral link of the visual analyzer is converted by it into primary electrical impulses, which, through the connecting link of the visual analyzer, enter the central link of the visual analyzer and are transformed by it into visual images. In a number of works [9-11] it is indicated that, firstly, visual images in the central link of the visual analyzer do not appear instantly, but with some delay relative to the moment of the onset or end of light stimulation of the peripheral link of the visual analyzer, and, secondly, electrical the activity of the central link of the visual analyzer of a person at rest, i.e. in the absence of light stimulation of the peripheral link, it is characterized by the so-called. α-rhythm. The numerical values of the time of inertia of the human organ of vision and the frequency of the α-rhythm are somewhat different for individual human individuals and range from 0.05 to 0.2 sec and from 8 to 13 Hz, respectively. The operability of the visual analyzer is preserved provided that the tasks of visual perception are consistently solved by all three links, and the normal functioning of the peripheral link of the visual analyzer is determined by the energy aspect of the perceived optical signal in the visible range of the optical spectrum (0.4-0.76 μm), and the normal functioning of the central link of the visual the analyzer is determined by the information component of the perceived light signal. In [10] it is indicated that with direct visual perception of the light signal, the peripheral link of the human visual analyzer reacts directly to the brightness of the radiation source forming the light signal in a fairly wide range - from 2⋅10 ^-6 cd / m ² (lowest brightness) to 2 ⋅10 ⁵ cd / m ² (maximum absolute or so-called blinding brightness), i.e. for the normal functioning of the peripheral link of the human visual analyzer, the brightness of its light stimulation should exceed the perception threshold (2⋅10 ^-6 cd / m ² ), but should not exceed the level of absolute blinding brightness (2⋅10 ⁵ cd / m ² ). Disruption of the normal functioning of the central link of the visual analyzer, as indicated in a number of works [9-12], causes light stimulation of the peripheral link of the visual analyzer by a pulsating light flux, the pulsation frequency of which corresponds to the α-rhythm of the human brain, and the pulse duration corresponds to the time of inertia of the visual organs human. Such light stimulation inevitably leads to a violation of the psychomotor functions of the subject of influence, in particular, leads to a loss of spatial orientation, and causes a condition usually preceding an epileptic seizure, reducing to a minimum the likelihood of aiming the MANPADS at the target if the subject of the impact is the MANPADS operator. At the same time, the indicated light stimulation of the peripheral link of the visual analyzer causes a psychotronic effect - a person is seized by a feeling of panic fear, which significantly reduces his combat capability.

A known device for active interference for personal protection of aircraft from damaging effects from the likely attack sector of ground-based mobile weapons systems (including MANPADS), the executive body of which contains a means of implementing in the daytime a damaging effect on the visual analyzer of the operator-operator MANPADS [13] , leading to the physical impossibility of performing the target task assigned to him by the shooter-operator. The executive body of this device from the aircraft, selected as a prototype, contains an emitter installed on board the aircraft directed to the lower hemisphere of the surrounding aircraft space in the 360 ° zone in azimuth of incoherent optical radiation of the visible range in the form of pulses repeated in time and constant in amplitude with a fixed repetition rate corresponding α-rhythm of the human brain, and a duration of time corresponding to the inertia of human bodies, the magnitude of which the luminance is from 0,4⋅10 ⁵ cd / m ² to 1,6⋅10 ⁵ cd / m ^2, i.e. does not exceed 80% of the level of absolute blinding brightness, since for the normal functioning of the peripheral link of the human visual analyzer, the brightness of its light stimulation should not exceed the level of blinding brightness.

It is known that the visual perception (light sensation) of a person is not uniquely determined by the brightness of the observed object, but depends on the observation conditions - first of all, on the distribution of brightness in the entire visual field of the peripheral link of the visual analyzer, both immediately at the time of observation and in the previous period. Numerous studies have shown that the performance of the human visual analyzer depends on its adaptation to the corresponding illumination of the observer's field of view. The initial task of the MANPADS gunner-operator, which, as mentioned above, is a "functional element" of the optical-visual control path for guiding MANPADS to the target, is target detection (attacked aircraft), which is usually performed in the search mode, because ... initially, the position of the target in the field of view is unknown in advance. A fundamentally important distinctive feature of the process of visual target detection is that the sought object of search (AF) is observed against the background of the daytime sky, and the overwhelming part of the field of view of the MANPADS operator is initially the background of the daytime sky, the brightness of which determines the level of initial brightness adaptation of the peripheral link of the visual analyzer gunner-operator MANPADS.

It is generally accepted that the background brightness is comparable to the brightness of the sky, the brightness of which in the visible range of the optical spectrum largely depends on the height of the Sun and the zenith angle of observation, i.e. on the time of day, time of year and a specific geographic area, as well as the presence of cloud cover. In [14, 15] that cloudless sky brightness changes from 0,1⋅10 ⁴ cd / m ^2, up to ⁴ 2,0⋅10 cd / m ^2:

- over 1,2⋅10 ⁴ cd / m ² - bright day;

- from 0.1⋅10 ⁴ cd / m ² to 1.2⋅10 ⁴ cd / m ² - a normal day;

- 0,1⋅10 less than ⁴ cd / m ² - Transition (twilight).

In [16] stated that if the brightness of the observed object brightness significantly exceeding the initial adaptation, the effect of the visual analyzer glare peripheral unit may occur when the observer luminances values is less than the absolute value of glare (2,0⋅10 ⁵ cd / m ²⁾ ... In that paper shows the calculated maximum allowable formula (blinding) brightness of the radiation source (V _cl) causing glare effect, i.e. disrupting the normal functioning of the peripheral link of the visual analyzer, subject to its initial brightness adaptation (In ^hell ):

Thus, the device of active interference for personal protection of aircraft from the damaging effects of MANPADS, selected as a prototype, is made with the possibility of carrying out a damaging effect on the central link of the visual analyzer of MANPADS due to the absence of a blinding effect on the peripheral link of its visual analyzer during combat operations in daylight conditions. illumination when the value of the background brightness is over 0.8⋅10 ⁴ cd / m ² .

From the above, it follows that the design of the aircraft IZ device from the damaging effects of MANPADS, selected as a prototype, from the point of view of the principle of damaging effects on the central link of the visual analyzer of the MANPADS operator operator through the formation of active interference in the optical-visual control path for the guidance of the complex on the target in the daytime is completely justified, and the disadvantage of the design of this device lies in the practical impossibility of guaranteed ensuring the minimum time interval for achieving a damaging effect on the central link of the visual analyzer of the MANPADS operator, taking into account the primary adaptation of the peripheral link of his visual analyzer and the brightness of the background of the daytime sky in the combat zone.

The task to be solved by the utility model consists in eliminating the indicated drawback by optimizing the brightness of the active interference radiation generated by the aircraft IZ device in the optical-visual control path for guiding MANPADS to the target, taking into account the primary adaptation of the peripheral link of the visual analyzer of the MANPADS operator to the brightness of the background of the daytime sky in the combat zone.

The technical result achieved by the implementation of the proposed solution consists, accordingly, in the guaranteed protection of the aircraft from the damaging effects of MANPADS with an optical-visual control path for aiming at the target from all hazardous directions during the entire time spent in the hazardous area and with any variations in the brightness of the daytime background. sky in the combat zone.

The declared IZ LA onboard complex from the damaging effects of MANPADS, like the IZ LA device, selected as a prototype, contains in the executive body a block for forming active interference in the optical-visual control path for guiding MANPADS to the target, made with the possibility of generating a direction directed to the lower hemisphere of the surrounding Aircraft space in the area of 360 ° in azimuth of incoherent optical radiation of the visible range in the form of pulses repeating in time and constant in amplitude with a fixed repetition rate corresponding to the α-rhythm of the human brain and duration corresponding to the time of inertia of human visual organs.

кд/м², где B_ф - яркость фона дневного неба в видимом диапазоне оптического спектра.The difference between the proposed on-board complex IZ LA from the prototype is that the block for generating active interference in the optical-visual control path for guiding MANPADS to the target is equipped with a device for controlling the level of brightness generated by the specified block of incoherent optical radiation of the visible range in the composition of the driving element and the electronic block for generating the control action , moreover, the driving element of the specified device is made in the form of a brightness meter oriented towards the background of the daytime sky in the visible range of the optical spectrum, the output of which is the information input of the electronic unit for generating the control action, and the electronic unit for generating the control action is configured to provide generation by the generating unit of active interference in opto-visual guidance control to the target path MPADS incoherent optical radiation in the visible range, the luminance value of which is not less than 1.5 _f cd / m ² but not used more

cd / m ^2, wherein B _f - background brightness of the daytime sky in the visible range of the optical spectrum.

FIG. 1 shows a block diagram of a specific implementation of the claimed on-board complex from the aircraft from the damaging effects of MANPADS. In this particular case, the IZ LA onboard complex contains master 1 and executive 2 organs. The driving organ 1 is made in the form of a passive optoelectronic device for remote registration of the ultraviolet component of the radiation from the jet propulsion system torch of the attacking aircraft of the UR, the design of which and its use in the onboard means of the aircraft is known [17, 18]. The executive body 2 contains a block 3 for the formation in the direction of the attacking missile simulating active interference IR seeker UR and block 4 for the formation of active interference in the optical-visual control path of MANPADS guidance to the target. The design of block 3 and its use as part of the aircraft equipment is known [7, 18] and does not require a special explanation. Unit 4 contains an emitter 5 directed to the lower hemisphere of the surrounding aircraft space of repetitive in time and constant amplitude pulses of incoherent optical radiation of the visible range, which includes a light-forming element and a power and control unit (not shown in Fig. 1), and a level control device brightness of the light-forming element of the emitter 5 as part of the driving element 6 and connected to its output of the electronic unit 7 for generating the control action. The structure of the optical radiation generated by the emitter 4 is set by the program included in the power and control unit (not shown in Fig. 1). The principle of operation of the emitter 4 is based on the conversion of electrical energy into optical radiation of a certain structure, followed by its redistribution into the surrounding space. Various embodiments of devices of this type are well known in the art. In this particular case, the light-forming element 5 of the emitter 4 is made in the form of a combination of a pulsed gas-discharge lamp that generates radiation in the visible range of the optical spectrum (0.4-0.76 μm) and a light-redistributing optical system, and the power and control unit is made according to the usual scheme, used for pulsed gas discharge lamps. The light-redistributing optical system is installed on the lower surface of the aircraft body and forms, in this particular case, a circular radiation indicatrix in azimuth and a radiation angle equal to 170 ° in elevation [13]. The driving element 6 is made in the form of a daytime sky background brightness meter oriented to the upper hemisphere of the space surrounding the aircraft. As such a meter can be used radiometers of the "Argus" series or a brightness meter of the "TKA-04/3" type, which are based on the principle of optoelectronic conversion [19]. The principle of operation of the unit 7 for generating the control action and the variants of the technical implementation of the functional elements forming it are well known and, therefore, in this particular case, no detailed explanation is required.

It should be noted that the use of a brightness meter for the background of the daytime sky as part of the onboard equipment of a military aircraft for protection against optical-visual reconnaissance means of the enemy is known [20], but in relation to the onboard complex IZ LA from the damaging effects of MANPADS, the executive body of which is made with the possibility of implementing striking 'impact on the visual analyzer of the shooter-operator MANPADS, such a solution is used for the first time.

The declared on-board complex IZ LA from the damaging effects of MANPADS works as follows. Initially, in the absence of the fact of a missile attack, but only in case of its threat, block 1 and block 4 operate in combat mode, and block 3 remains in standby mode until the first fact of a missile attack is registered. The driving element 6 of block 4 generates an electrical signal proportional to the brightness level of the background of the daytime sky in the combat zone. This signal is fed to the input of the electronic unit 7 for forming a 'control action. Block 7, taking into account the program embedded in it, generates a control signal, which, when it enters the input of the emitter 5, generates by the latter incoherent optical radiation of a given structure, the brightness of which takes into account the peculiarities of the energy perception of visual information by the peripheral link of the visual analyzer of the MANPADS operator. It is known that the performance of the peripheral link of the human visual analyzer depends not only on the conditions of adaptation to the corresponding illumination of the visual field (brightness of the daytime sky), as indicated above, but also largely depends on the brightness of the surrounding background in terms of contrast sensitivity, depending on external illumination. In work [21] it is indicated that visual contrast is the ability of visual perception due to which the visual assessment of the observed object changes depending on the brightness of the surrounding background, and the value of contrast (K) is determined by the expression:

where In _max and B _min are the maximum and minimum brightness in the observer's field of view. On the basis of experimental data [22, 23], it was found that the most optimal when performing a number of works related to the observation of a moving object is the value of the brightness contrast, which in the first approximation is the same for all human individuals and has a value of the order of 0.2-0.3 (medium contrast).

Thus, the value of the brightness (B) of the incoherent optical radiation of the visible range, formed by the emitter 5, taking into account the excess of the background brightness (B _f ) with a contrast value of about 0.2, but not more than 80% of the blinding brightness, subject to the primary brightness adaptation of the peripheral link visual analyzer should be:

The proposed design of block 4 of the executive body 2 of the onboard complex IZ LA allows you to quickly control in automatic mode the value of the brightness level of optical radiation, which provides a damaging effect on the central link of the visual analyzer of the MANPADS operator operator from all attacked directions during the entire time the aircraft is in the hazardous area for any variations in the brightness of the background of the daytime sky in the combat zone, which provides an increase in the survivability of the protected aircraft in the conditions of the enemy's use of ground-based damaging effects with an optical-visual channel for targeting.

The industrial applicability of the proposed solution is determined by the possibility of its repeated reproduction during the production process using standard equipment, materials and technologies.

Literature:

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Claims (1)

An on-board system for individual protection of an aircraft from the damaging effects of portable anti-aircraft missile systems, containing, as part of the executive body, an active jamming unit in the optical-visual control path of guidance of a portable anti-aircraft missile system at a target, made with the possibility of generating a surrounding aircraft directed to the lower hemisphere space in the 360 ° zone in azimuth of incoherent optical radiation of the visible range in the form of pulses repeated in time and constant in amplitude with a fixed repetition rate corresponding to the α-rhythm of the human brain and duration corresponding to the time of inertia of the human visual organs, characterized in that the block the formation of active interference in the optical-visual control path of guidance of the portable anti-aircraft missile system to the target is equipped with a device for controlling the brightness level of the incoherent optical radiation generated by the specified unit. range in the composition of the driving element and the electronic unit for generating the control action, and the driving element of the said device is made in the form of a brightness meter oriented towards the background of the daytime sky in the visible range of the optical spectrum, the output of which is the information input of the electronic unit for generating the control action, and the electronic block for forming the control action is adapted to ensure the formation of the active generating unit in the optical-interference visual guidance control path portable air defense missile system at the target incoherent optical radiation in the visible range, the luminance value of not less than 1.5 _f cd / m ² but not more than

cd / m ^2, where B _^ - background brightness of the daytime sky in the visible range of the optical spectrum.

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