RU228084U9 - On-board system of individual protection of aircraft from the damaging effects of man-portable air defense missile systems - Google Patents

Abstract

The utility model relates to on-board personal protection systems (PPE) of an aircraft against the damaging effects of man-portable air defense systems (MANPADS) equipped with a guided missile (GM) with an infrared (IR) homing head (GHS) and a thermal imaging sight (TIS) as part of an optical-visual tract (OVT) for controlling the guidance of the MANPADS at the target. The PPE of the aircraft implements the sector principle of constructing an aircraft protection zone by placing an active interference (AI) formed by a group of directional emitters of amplitude-modulated incoherent IR radiation in the spectral range of 3.0-5.0 μm, installed motionless relative to the aircraft body, identical in lighting characteristics, the combined indicatrix of which covers the aircraft protection zone in azimuth and elevation. The design feature of the proposed PPE of aircraft consists in the fact that each of the directional emitters forming the group is designed with the possibility of functioning in two modes - the formation of the imitation AP of the IR homing head of the guided missile within the time interval of being in the zone of its spatial operation of the attacking guided missile and the formation of AP in the OVT of the MANPADS in the absence of the attacking aircraft of the guided missile in the zone of its spatial operation. The technical result consists in increasing the operational reliability of the PPE functioning due to ensuring the formation of AP radiation in the OVT of the MANPADS and the imitation AP of the homing head of the attacking aircraft of the guided missile by a group of jointly functioning directional emitters. 1 fig.

Description

The utility model relates to weapons, in particular to on-board personal protection systems (PPE) of aircraft (AC) against the damaging effects of man-portable air defense systems (MANPADS) equipped with guided missiles (GM) with an infrared (IR) homing head (GHS).

The development of aircraft PPE against the damaging effects of high-precision weapons is receiving increased attention in many countries around the world, and one of the priority areas in this area of activity is the development of aircraft PPE against the damaging effects of MANPADS, since, as follows from the results of studies of the causes of combat losses of aircraft and helicopters [1], over 90% of aircraft were hit by guided missiles with IR homing heads, which are part of MANPADS of the Stinger, Igla and Strela types. At present, MANPADS equipped with guided missiles with IR homing heads are one of the most effective means of destroying ground-based aircraft, the preparation for combat use of which cannot be detected by visual and optical-electronic reconnaissance of the enemy, which allows MANPADS to be used suddenly and covertly. The maximum range of most MANPADS is about 5-6 km, and the altitude of destruction is up to 3 km [2], i.e. The aircraft is under the threat of attack from MANPADS from the earth's surface zone (the so-called attack-hazardous zone or zone of possible missile launches), the radius of which is about 4 km. Due to their small size and weight, most MANPADS can be used by one MANPADS operator against all types of air targets from any unprepared launch position where the use of any other anti-aircraft weapons against aircraft is difficult - in the forest, in the mountains, within urban areas. The special features of this type of weaponry also include the exceptional simplicity of its operation and user training (MANPADS operator).

It is quite obvious that the design of any technical object is determined, first of all, by the purpose and principle of operation of this object. The target function of the claimed device is to ensure counteraction to the damaging effect on aircraft from MANPADS and, therefore, the design of the aircraft onboard PPE is determined by the features of the functioning and design of the MANPADS.

MANPADS, as indicated above, are land-based mobile weapons systems and are a launch tube coupled with a launch mechanism and equipped with a sighting device with a direct-vision optical-visual tract (OVT), in which a guided missile with an IR homing head is placed. Such a design allows the MANPADS to be used in a way that is traditional for mobile weapons systems with direct-vision OVT for target guidance control - to launch the guided missile from the shoulder of the MANPADS operator-gunner. The sighting device included in the MANPADS serves for visual search, detection and tracking of the selected target (the aircraft under attack) before the MANPADS operator-gunner launches the guided missile, and the launch tube is, in essence, a guide device that ensures the aimed launch of the guided missile in the direction of the selected target (aircraft).

It should be noted that in modern conditions the high dynamism of combat operations leads to the need to conduct combat actions practically around the clock and, therefore, the OVT for controlling the guidance of MANPADS on the target must be designed with the possibility of 24-hour and all-weather functioning of the MANPADS with the direct participation of the MANPADS operator-gunner in its functioning. Such functioning of the OVT for controlling the guidance of MANPADS on the target is possible only when using a special device as part of the OVT of the MANPADS - an input converter of optical information about the target (the attacked aircraft) and the airspace surrounding the target, which is, in essence, a link between the object of observation (the attacked aircraft) and the MANPADS operator-gunner, whose organs of vision perform the function of the setting element of the control system for the guidance of MANPADS on the target. Optical-electronic devices used as part of the OVT for controlling the guidance of MANPADS on the target are known, which use their own thermal (IR) radiation of the target and the airspace surrounding the target as a carrier of useful information, i.e. their thermal contrast. The operating principle of such devices, the so-called thermal imaging sights (TIS), is based on the transformation of IR radiation received from the observation object and the surrounding space (background) into an intermediate electronic image with subsequent visualization - the transformation of the electronic image into a visible one. The spectral sensitivity range of TIS intended for use in the control system for targeting MANPADS is 3.0-5.0 μm [3]. Currently, there is a tendency to use standard TIS as part of the control system for targeting MANPADS. For example, the Stinger type MANPADS is equipped with a standard TIS of the WASP type [3].

The guided missile, which is part of the MANPADS, is a carrier equipped with a jet propulsion system, on which the target load unit (the guided missile warhead) and the guided missile homing system of a passive type, which is implemented according to the principle of a tracking system [4,5], are placed. The controlled value in this system (the so-called misalignment) is the deviation of the longitudinal axis of the guided missile carrier and, consequently, the optical axis of the guided missile seeker, from the direction of the attacked aircraft, and the seeker performs the function of the master element of the guided missile homing system, the output of which is the information input of the guided missile rudder control circuit, which, in turn, perform the function of the actuator element of the homing system of the missile attacking the aircraft. The guided missile IR seeker is, in essence, an optoelectronic device of a passive type with the "URLA" communication channel, in which the algorithm of amplitude-time target selection is implemented, i.e. The IR seeker converts the continuous thermal (IR) radiation of the attacked aircraft in the spectral sensitivity range of the IR seeker of the missile (3.0-5.0 μm) into amplitude-modulated radiation, the modulation frequency of which is determined by the design features of the implementation of the seeker of a specific missile, and forms an electrical signal on its basis, which, after appropriate conversion by the control circuit, is fed to the power drives of the steering device of the homing system, and the steering device performs spatial orientation of the missile in such a way that the longitudinal axis of the missile carrier corresponds to the direction to the attacked aircraft.

It follows from the above that the process of combat operation of MANPADS includes two successive interconnected stages [4,5], and at the first stage the MANPADS operator-gunner, after visual detection and identification of the target by means of the MANPADS guidance control system, manually tracks the target, i.e. ensures the alignment of the optical axis of the guided missile seeker located in the MANPADS launch tube with the direction of the target (attacked aircraft), which ensures the target is captured by the narrow field of view of the guided missile seeker and the transition of the guided missile seeker to the target tracking mode, and then launches the guided missile (the so-called aimed launch) in the direction of the attacked aircraft. The subsequent flight of the guided missile to the target (attacked aircraft) is carried out autonomously without communication with the MANPADS operator-gunner, according to commands generated by the IR guided missile seeker.

It is quite obvious that the direct damaging effect on the attacked aircraft is carried out by the guided missile and therefore, until recently, individual protection of the aircraft from the damaging effect of MANPADS was carried out exclusively at the second stage of the system’s operation, i.e. after the MANPADS operator-gunner has carried out an aimed launch of the guided missile in the direction of the attacked aircraft. One of the effective methods of individual protection of the aircraft from the damaging effect of guided missiles with an IR homing head is considered to be counteraction to the homing process of the attacking aircraft by the guided missile by means of placing from the protected aircraft a simulated active interference of the guided missile head in the form of amplitude-modulated incoherent IR radiation (the so-called amplitude-modulated simulating active interference) in the spectral sensitivity range of the guided missile’s IR homing head (3.0-5.0 μm). The process of the effect of the amplitude-modulated simulating active interference on the guided missile’s IR homing head is described in sufficient detail in [6, 7]. As follows from the specified works, when the radiation of the amplitude-modulated simulating active interference enters the input path of the homing head of the attacking missile and its subsequent optoelectronic conversion, in accordance with the program embedded in the homing head, the radiation of the simulating active interference becomes a source of false information about the location of the attacked aircraft, i.e., it actually creates a kind of “phantom target” in the homing system of the attacking missile, the location of which differs from the current coordinates of the real target, which necessarily leads to the failure of the homing process of the missile on the attacked aircraft. In work [6] it is indicated that the efficiency of counteracting the homing process of a missile by means of simulating active interference is characterized, in essence, by the time interval of the interference effect on the missile seeker head, necessary for disrupting the homing process of the missile on the attacked aircraft, the value of which is determined by the pulse repetition rate of the simulating active interference, the value of which should be close to the frequency mode of operation of the attacking missile seeker head, and the peak radiation power of the simulating active interference, the value of which should exceed the intensity of the attacking aircraft's own thermal (IR) radiation of the propulsion system in the spectral sensitivity range of the attacking missile's IR seeker head. Obviously, ensuring the required value of the peak radiation power of the active interference in the direction of the attacking aircraft's missile seeker head for a given value of energy consumption necessary for generating the simulating active interference radiation by the primary optical radiation source, which is part of the aircraft's onboard PPE actuator unit, is closely related to the issue of spatial generation of the simulating active interference radiation by the aircraft's PPE actuator unit. That is why, at present, to protect aircraft from the damaging effects of guided missiles with IR homing heads included in MANPADS, as a rule, directional PPE is used, characterized by spatial locality of operation within the protection zone (attack-hazardous zone) of the space surrounding the aircraft in the direction of the homing head of the attacking guided missile during the time interval of the attacking guided missile's presence in the aircraft's protection zone. Airborne PPE of aircraft of this type ensures a closed cycle of counteracting the attacking effect of guided missiles with IR homing heads on aircraft and is designed with the ability to generate directional, amplitude-modulated, incoherent IR radiation in the spectral sensitivity range of the IR homing head of the attacking guided missile and control the spatial orientation of said radiation in the direction of the homing head of the attacking guided missile. It should be noted, however, that in real operating conditions of the aircraft onboard PPE, in the absence of reliable information about the type of the attacking aircraft of the missile, there is a very high probability of a mismatch in the frequency modes of operation of the aircraft PPE actuator unit and the homing head of the attacking aircraft of the missile, and, consequently, there is a high probability of an increase in the time interval of the effect of the radiation of the simulating active interference on the homing head of the attacking aircraft of the missile before the homing process of the attacking missile is disrupted. In work [6], it is indicated that in a critical case, the value of the time interval required to disrupt the homing process of the attacking missile reaches a value that is comparable with the time interval of the missile flight to the attacked aircraft at the minimum launch range of the missile, which makes the aircraft very vulnerable in conditions of simultaneous multidirectional attack effects of MANPADS within the attack-hazardous zone of the space surrounding the aircraft.

A design of an onboard PPE of an aircraft against the damaging effects of MANPADS equipped with guided missiles with an IR homing head is known [8], which implements the sector principle of aircraft protection within the attack-hazardous zone of the space surrounding the aircraft, which makes it possible to counter the homing process of guided missiles with an IR homing head attacking aircraft simultaneously from different directions. The peculiarity of the design of the said onboard PPE of an aircraft is that it is made according to the principle of a tracking system in the form of a combination of a master block, a control action generating block and an actuator block. The master block of the said onboard PPE of an aircraft is designed with the possibility of detecting and tracking an attacking aircraft with a guided missile in the form of a passive optoelectronic device for remotely recording the ultraviolet (UV) component of the radiation from the jet propulsion system torch of the attacking missile, the sensitivity zone of which covers the aircraft protection zone (attack-hazardous zone of the space surrounding the aircraft) in azimuth and elevation. Such devices based on instantaneous view optoelectronic sensors have high resolution, accuracy and speed [9]. The actuator unit of the specified onboard PPE of the aircraft [8] is designed with the possibility of generating radiation of simulating active interference in the direction of the attacking missile with an IR homing head and is equipped with a group of directional emitters of modulated incoherent IR radiation in the spectral sensitivity range of the IR homing head of the attacking aircraft of the missile, identical in terms of their lighting characteristics, installed motionless relative to the outer surface of the aircraft body, the combined radiation indicatrix of which covers the aircraft protection zone from the damaging effects of the missile with an IR homing head, included in the MANPADS, in azimuth and elevation. The number of directional emitters, identical in terms of lighting characteristics, forming a group and included in the actuator unit of the onboard PPE of the aircraft, is determined individually in each specific case. The control action generation unit of the specified onboard PPE of the aircraft is made in the form of an electronic device for processing and analyzing signals from the output of the master block and, in accordance with the program embedded in it, controls the time and energy characteristics of the incoherent IR radiation generated by directional emitters that are part of the actuator unit of the onboard PPE of the aircraft, within the time interval of being in the spatial functioning zone of each of them of the attacking aircraft of the missile defense system.

The design of the specified onboard PPE of the aircraft [8], taking into account its functional purpose (counteracting the damaging effects on the aircraft from the missile with an IR homing head at the second stage of the operation of the MANPADS), is completely justified, but taking into account the specifics of the hardware use as part of the onboard equipment of the aircraft, it is not optimal. Indeed, each of the directional emitters identical in lighting characteristics, included in the executive unit of the aircraft PPE [8], is designed with the possibility of generating radiation simulating active interference of the IR homing head of the attacking missile, the peak power of which exceeds the value of the protected aircraft's own thermal (IR) radiation by a given number of times, and, therefore, the functioning of the executive unit of such an aircraft PPE under conditions of simultaneous multidirectional attack action of a missile with an IR homing head is very energy-intensive, especially when used as part of the on-board equipment of an aircraft with a high level of its own thermal (IR) radiation, and, therefore, the use of such an aircraft PPE is advisable only if the aircraft's on-board power plant has a sufficient energy reserve.

That is why there is a need to implement individual protection of aircraft from the damaging effects of MANPADS at the first stage of the system operation by using an active interference subsystem in the MANPADS target guidance control system as part of the aircraft onboard PPE, the effect of which on the visual organs of the MANPADS operator-gunner significantly reduces the probability of the operator-gunner's aimed launch of the missile. The human vision function is a multifactorial psychophysiological process of converting primary optical (light) excitation into visual sensations (the fact of awareness) and is carried out by the so-called visual analyzer, which consists of three interconnected links - peripheral, connecting and central [10-12]. The peripheral link of the visual analyzer is the human eye, which is a combination of optical and light-perceiving systems. The spectral sensitivity range of the peripheral link of the human visual analyzer is from 0.4 μm to 0.76 μm (the visible range of the optical spectrum). The central link (coordinating and analyzing) of the visual analyzer, located in the occipital lobe of the cerebral hemispheres of the human brain. The peripheral link and the central link of the visual analyzer are connected by an afferent nerve, which performs the function of a connecting link of the visual analyzer. Optical radiation of the visible range of the optical spectrum perceived by the peripheral link of the human visual analyzer is converted by it into primary electrical impulses, which through the connecting link enter the central link of the visual analyzer and are transformed by it into visual images. In the works [10-12] it is indicated that, firstly, visual images in the central link of the human visual analyzer do not arise instantly, but with some delay relative to the moment of occurrence and termination of light stimulation of the peripheral link of the visual analyzer, and, secondly, the electrical activity of the central link of the human visual analyzer in the absence of light stimulation of the peripheral link is characterized by the so-called α-rhythm of the human brain. The numerical values of the inertia time of the human visual organs and the frequency of the α-rhythm of the human brain vary to some extent for individual human beings and range from 0.05 s to 0.2 s and from 8 Hz to 13 Hz, respectively. The performance of the human visual analyzer is maintained under the condition of consistent provision of visual perception by all three links, with the normal functioning of the peripheral link being determined by the spectral and energy aspects of the influencing optical signal, and the normal functioning of the central link being determined by the information component of the perceived optical signal. During direct visual perception of an optical signal in the visible range of the optical spectrum, the peripheral link of the human visual analyzer reacts directly to the brightness of the source forming the light signal in a fairly wide range - from 2 10 ^-6 cd / m ² (the so-called sensitivity threshold) to 2⋅10 ⁵ cd / m ² (the so-called absolute next blinding brightness) [11], and, therefore, for the normal functioning of the peripheral link of the human visual analyzer, the magnitude of the radiation brightness during light stimulation should exceed the sensitivity threshold, but should not exceed the level of absolute blinding brightness. It is known [10] that disruption of the normal functioning of the central link of the human visual analyzer is caused by stimulation of the peripheral link of the visual analyzer with a pulsating light flux, the pulse repetition frequency of which corresponds to the α-rhythm of the human brain, and the pulse duration corresponds to the inertia time of the human visual organs. Such light stimulation of the peripheral link of the human visual analyzer necessarily leads to a violation of the psychomotor functions of the subject of the impact, in particular, leads to the loss of spatial orientation and causes, as a rule, a condition preceding an epileptic seizure. At the same time, the said light stimulation of the peripheral link of the human visual analyzer causes a psychotronic effect - the person is seized by a feeling of panic fear, which significantly reduces his ability to act.

A known on-board PPE of an aircraft against the damaging effects of MANPADS [13] comprises a subsystem for generating an imitation active interference of the IR homing head of an attacking aircraft of a missile and a subsystem for generating active interference in the MANPADS guidance control system at a target equipped with a TVP, which includes a master block, a control action generation block and an actuator block. The actuator block of the subsystem for generating active interference in the MANPADS guidance system of the specified PPE of an aircraft is designed as an emitter that operates continuously during the entire time the aircraft is in the attack-hazardous zone and is directed towards the lower hemisphere of the space surrounding the aircraft in a 360° azimuth zone of incoherent IR radiation, the spectral range of which corresponds to the spectral range of the TVP functioning, which is part of the MANPADS guidance system and is 3.0-5.0 μm. The driving unit of the specified subsystem of the aircraft PPE is made in the form of a brightness meter oriented in the direction of the sky background in the IR range of the optical spectrum, corresponding to the spectral range of the functioning of the TVP, and the control action generation unit is an electronic device and is made with the possibility of generating by the actuator unit of the specified subsystem incoherent IR radiation in the form of pulses repeating in time and constant in amplitude, the fixed repetition frequency of which corresponds to the α-rhythm of the human brain, and the brightness value is not less than 1.5⋅V _f cd/m ² , but not more where Bf is the brightness of the sky background in the combat zone in the IR range of the operation of the TVP, which is part of the MANPADS OVT.

The design of the specified subsystem for generating active interference in the MANPADS guidance control system equipped with a TVP, which is part of the aircraft's onboard PPE against the damaging effects of the MANPADS, is completely justified, since the specified subsystem reduces the likelihood of the MANPADS operator-gunner performing an aimed launch of the missile during the entire time the aircraft is in the attack-hazardous zone during the day and night. It should be noted, however, that the presence of the specified subsystem in the aircraft's onboard PPE reduces, but does not eliminate, the probability of the MANPADS operator-gunner's carrying out an aimed launch of a guided missile and, consequently, the guaranteed effectiveness of the aircraft's individual protection from the damaging effects of MANPADS can only be achieved if the aircraft's onboard PPE includes two subsystems, one of which generates active interference in the MANPADS guidance control system equipped with a TVP [13] and functions continuously during the entire time the aircraft is in the combat zone, while the other generates an imitation active interference in the homing head of the attacking aircraft's guided missile [8] and functions discretely upon registration of the attacking missile in the aircraft's protection zone from the damaging effects of MANPADS.

Thus, the implementation of the onboard PPE of the aircraft in the form of a combination of two subsystems for generating active interference from the point of view of the functional purpose of each of them is completely justified, since it increases the effectiveness of the aircraft protection from the damaging effects of MANPADS in the absence of reliable information about the type of guided missile used in the MANPADS, but its design implementation in the form of autonomous, independently functioning devices is not optimal, since it leads to a decrease in the utilization factor of the executive unit of the subsystem for generating the simulating active interference of the homing head of the attacking aircraft of the guided missile, i.e. to a decrease in the total operating time of the said unit in the active interference generation mode in relation to the time interval of the aircraft's location in the combat zone.

The task, which the utility model is aimed at solving, consists in eliminating the said drawback by combining the subsystem for generating active interference in the control system for guiding the MANPADS to the target, which are part of the aircraft's onboard PPE, and the subsystem for generating simulating active interference in the IR homing head of the missile into a single integrated system consisting of three functional blocks - the master block, the actuator block, and the control action block.

The technical result achieved by implementing the proposed solution consists, accordingly, in ensuring the operational reliability of the aircraft's onboard PPE, since even if one of the directional emitters forming the group in the PPE actuator unit fails, the aircraft's onboard PPE retains its operational capability in the mode of generating active interference radiation in the control system for guiding the MANPADS to the target.

The implementation of the specified task is best suited to the design implementation of the actuator unit of the aircraft onboard PPE according to [8], selected as a prototype.

The claimed onboard PPE of an aircraft against the damaging effects of MANPADS, like the onboard PPE of an aircraft selected as a prototype, comprises an actuator unit which is configured to form, in the direction of the attacking aircraft, a missile with an IR homing head of the MANPADS, a simulating active interference in the form of modulated non-coherent IR radiation in the spectral sensitivity range of the IR homing head of the missile and is equipped with a group of directional emitters installed motionless relative to the aircraft body, identical in lighting characteristics, the combined radiation indicatrix of which covers the aircraft protection zone against the damaging effects of the MANPADS in azimuth and elevation, a setting unit configured to detect and track the attacking aircraft with a missile in the form of a passive optoelectronic device for remotely recording the UV component of the radiation from the torch of the jet propulsion system of the attacking missile, the sensitivity zone of which covers the aircraft protection zone in azimuth and elevation, and a control action generating unit which is designed as an electronic device with the ability to provide a specified pulse-periodic structure and intensity of non-coherent IR radiation generated by directional emitters within the time interval of being in the spatial operating zone of each of them of the attacking missile defense system, and is equipped with a number of control action outputs corresponding to the number of directional emitters of the actuator block forming the group, each of which is connected via an autonomous control command transmission line to the corresponding directional emitter.

The difference between the claimed onboard PPE of an aircraft and the prototype is that the actuator unit is designed with the possibility of functioning in an additional mode, which is the formation of active interference in the control system of the guidance of the MANPADS to the target, which includes a TVP, and the setting unit is additionally equipped with a brightness meter oriented in the direction of the sky background in the spectral range of the operation of the TVP of the MANPADS, which is identical to the spectral range of the sensitivity of the IR homing head of the attacking aircraft of the MANPADS missile, and the control action generation unit is designed with the possibility of generating by directional emitters included in the actuator unit, within the time interval of absence in the zone of spatial operation of each of them of the attacking aircraft of the missile, pulses of incoherent IR radiation repeating in time and constant in amplitude in the spectral range of the operation of the TVP, the fixed repetition frequency of which corresponds to the α-rhythm of the human brain, the duration corresponds to the inertia time of the human visual organs, and the brightness value is not less than 1.5⋅V _f cd/ ^m2 , but not more cd/ ^m2 , where B _f is the brightness of the sky background in the combat zone in the IR range of the operation of the TVP, which is part of the control system for guiding the MANPADS to the target.

Fig. 1 shows a block diagram of a specific embodiment of the claimed design of the onboard PPE for aircraft against the damaging effects of MANPADS. The onboard PPE for aircraft contains an actuator unit 1, a setting unit 2 and a control action generating unit 3. Unit 1 is made in the form of a group of directional emitters of amplitude-modulated incoherent IR radiation in the spectral range of 3.0-5.0 μm, identical in lighting characteristics. In this specific case, unit 1 includes four directional emitters - 4, 5, 6 and 7, however, it should be noted that in real conditions the number of directional emitters in unit 1 may be greater, and the number of emitters shown in this specific case in Fig. 1 is chosen to simplify the perception of the general principle embedded in the design of the claimed onboard PPE for aircraft. Emitters 4, 5, 6 and 7 of block 1 are mounted fixedly on the outer surface of the aircraft body, and their spatial orientation is performed so that together they form a radiation indicatrix that is circular in azimuth and with a radiation angle of about 170° in elevation, which is directed into the lower hemisphere of the space surrounding the aircraft and ensures guaranteed coverage of the attack-hazardous zone from the side of the earth's surface, the radius of which, as was indicated above, is about 4 km. Emitters 4, 5, 6 and 7 of block 1 have a typical functional structure inherent in emitters of incoherent optical radiation of directional action, i.e. each of them contains a radiating element (not shown in Fig. 1) ensuring the generation of incoherent optical radiation in a given spectral range, and a light-redistributing optical element ensuring the concentration of optical radiation in a limited spatial angle (not shown in Fig. 1). The emitting element included in each directional emitter (4, 5, 6 and 7) of block 1 is made in the form of a combination of a pulsed gas-discharge lamp (GDL) with a plasma-forming medium based on cesium, the burner of which is equipped with a straight tubular shell made of colorless leucosapphire, an IR filter designed to isolate the IR component (3.0-5.0 μm) of the incoherent optical radiation generated by the GDL, and a GDL discharge current modulator by frequency, the law of change of which is specified by a control action generating unit 3, external with respect to the emitting element of each of the directional emitters 4, 5, 6 and 7 of block 1. The design of a cesium GDL intended for use in the actuator unit of the aircraft PPE is known [14] and does not require special explanation. The design of the discharge current modulator of the cesium GDL by frequency is made according to the scheme usual for pulsed GDLs. The IR filter is an absorption optical filter in the form of a hollow cylinder made of silicon, which is installed coaxially with the cesium GRL. The use of an optical filter made of the specified material, together with the specified GRL in the actuator unit of the aircraft PPE is known [15]. The light-redistributing optical element, which is part of each of the directional emitters 4, 5, 6 and 7 of block 1, is made in the form of a paraboloid mirror reflector, since, as follows from work [16], when using such a reflector, the highest angular concentration of the optical radiation flux is ensured in comparison with other optical systems with the same size output apertures. The active surface of the specified mirror reflectors is made of aluminum, since the value of its reflection coefficient in the spectral range of 3.0-5.0 μm is about 0.87 - 0.92 [17]. The composition of block 2 of the onboard PPE of the aircraft includes two autonomously functioning elements 8 and 9. The master element 8 of block 2 performs the function of detecting and tracking the attacking aircraft of the missile and is made in the form of a combination of passive optoelectronic sensors of instantaneous visibility operating in the UV range of the optical spectrum for remote recording of the UV component of the radiation of the jet propulsion system of the attacking aircraft of the missile. The design implementation and use of these sensors in the master block of the PPE of the aircraft is known [9, 18]. It should only be noted that in the claimed version of the design implementation of the onboard PPE of the aircraft, the sensitivity zone of the master element 8 of block 2 overlaps the protection zone of the aircraft in azimuth and elevation. It should also be noted that the instantaneous viewing UV sensors included in the setting element 8 of block 2 provide tracking of the attacking aircraft of the missile defense system with an accuracy of up to a tenth of an angular degree, which makes it possible to increase the spatial selection of the operation of individual directional emitters of block 1 by narrowing the radiation indicatrix of each of them, but increasing, accordingly, their number in block 1. The setting element 9 of block 2 is made in the form of a brightness meter oriented in the direction of the sky background in the IR range of the optical spectrum of 3.0-5.0 μm, which corresponds to the spectral range of operation of the TVP included in the OVT of the MANPADS. As indicated in [13], a radiometer of the Argus series [19] can be used as such a meter, the operation of which is based on the principle of optoelectronic conversion. The setting elements 8 and 9 of block 2 are connected to the corresponding inputs of block 3 for generating the control action via autonomous lines for transmitting an electrical signal from the output of the corresponding setting element. The control action generation unit 3 is made in the form of an electronic device for processing and analyzing signals from the output of the setting elements 8 and 9 of unit 2 and, in accordance with the program embedded in it, operates the directional emitters 4, 5, 6 and 7 of unit 1, each of which is coupled via an autonomous control command transmission line to the corresponding output of unit 3. In accordance with the control signal received from unit 2, each of the directional emitters 4, 5, 6 and 7 of unit 1 operates during the entire time the aircraft is in the attack hazard zone or in the mode of generating active interference radiation in the OVT equipped with a TVP, controlling the guidance of the MANPADS at the target, the pulse-periodic structure and the radiation brightness value of which take into account, as was indicated above, the peculiarities of the perception of visual information by the gunner-operator of the MANPADS, the OVT of which is equipped with a TVP, taking into account the brightness value of the sky background in the spectral range of 3.0-5.0 μm, which corresponds to the spectral range of the TVP operation, in the combat zone, or in the mode of generating radiation of the simulating active interference of the IR homing head of the guided missile, the pulse-periodic structure of which is close to the frequency mode of operation of the IR homing head of the guided missile, and the power value of which exceeds the radiation power of the aircraft propulsion system in the spectral sensitivity range of the IR homing head of the guided missile (3.0-5.0 μm), within the time interval of being in the spatial operation zone of each of them of the attacking aircraft of the guided missile. Various embodiments of such an electronic device and the functional elements forming it, intended for the implementation of generation by the radiating element included in the directional emitter, of optical radiation, the pulse-periodic structure, energy characteristics and time interval of operation of which are set by a control signal from a device external to the radiation source, are sufficiently well known and do not require detailed explanation.

The declared onboard PPE for aircraft against the damaging effects of MANPADS works as follows.

When the aircraft enters the attack-hazardous zone, the master block 2 and the actuator block 1 operate in combat mode for the entire time the aircraft is in the attack-hazardous zone. The master element 8 of block 2 performs an "instant" review of the space in the aircraft's protection zone, and the master element 9 of block 2 generates an electrical signal proportional to the value of the brightness level of the sky background in the IR range (3.0-5.0 μm) in the combat zone. In the absence of a missile attack, but only in the event of a threat thereof, the signal to the input of the electronic unit 3 comes only from the output of the setting element 9. Unit 3, in the absence of a signal from the output of the setting element 8 and taking into account the program embedded in it, generates a control signal, which is sent through autonomous control command transmission lines to the inputs of directional emitters 4, 5, 6 and 7 of unit 1. Directional emitters 4, 5, 6 and 7, in accordance with the control signal received at their input, simultaneously generate an active interference emission directed into the lower hemisphere of the space surrounding the aircraft in the control system for guiding the MANPADS to the target in the spectral range of operation of the TVP (3.0-5.0 μm), the combined radiation indicatrix of which covers in azimuth and elevation the aircraft protection zone from the damaging effects of the MANPADS from the attack-hazardous zone of the earth's surface, the pulse-periodic structure of which takes into account the features of the information perception of visual information by the visual analyzer of the MANPADS operator-gunner equipped with a TVP, and the brightness value, taking into account the value of the sky background brightness level (B _f ) in the IR range of the optical spectrum (3.0-5.0 μm), recorded by the setting element 9 of block 2, is not less than 1.5⋅B _f cd/m ² , but not more than cd/ ^m2 . When an attacking aircraft of a guided missile with an IR seeker, the torch of the jet propulsion system of which is a source of radiation in the UV range of the optical spectrum, enters the sensitivity zone of the setting element 8 of block 2, the setting element 8 registers the fact of a missile attack, and the electronic unit 3, in accordance with the program embedded in it, generates a control signal that carries information about the fact of a missile attack, the spatial position at a given moment in time of the attacking missile relative to the aircraft, the frequency and energy modes of operation of the corresponding directional emitter of block 1 when generating radiation simulating active interference of the IR seeker of the attacking aircraft of the guided missile during the time interval of the attacking missile being in the zone of its spatial operation. The control signal from block 3 is sent to the input of block 1 via the corresponding autonomous control command transmission line. Let us assume that the attacking aircraft of the missile is in the zone of the space surrounding the aircraft, which is covered by the indicatrix of studying the directional emitter 4 of block 1 in its combat operation mode. In this case, the control signal from block 3 is sent via the corresponding autonomous control command transmission line to the input of the directional emitter 4 of block 1, which switches to the mode of generating radiation simulating active interference of the homing head of the attacking missile, thereby counteracting the process of homing the missile to the attacked aircraft. The remaining emitters of block 1 (5, 6 and 7) remain in the mode of generating radiation of active interference in the control system of the MANPADS guidance to the target in the spectral range of the MANPADS TVP operation. When the attacking missile leaves the sensitivity zone of the setting element 8 of block 2, corresponding to the zone of formation of the radiation of the simulating active interference by the directional emitter 4 of block 1, the said emitter, in accordance with the program embedded in block 3, switches to the mode of formation of the radiation of active interference in the control system of the guidance of the MANPADS to the target. At the same time, upon command from block 3, through the corresponding control command transmission line, a transition to the mode of generating radiation of the imitation active interference of the IR homing head of the attacking aircraft of the guided missile of another directional emitter - 5, the spatial operation zone of which is adjacent to the spatial operation zone of the directional emitter 4, is carried out. Thus, when the attacking aircraft of the guided missile moves in the aircraft protection zone, its homing head is continuously affected by the emitter of imitation active interference from directional emitters 4, 5, 6 and 7 of block 1, successively operating in the mode of generating radiation of imitation active interference, up to the moment of failure of the homing of the attacking aircraft of the guided missile and its exit from the aircraft protection zone, wherein simultaneously the directional emitters of block 1, within the time interval of absence in the zone of their spatial operation of the attacking aircraft, generate radiation of active interference in the control system of the guidance of the MANPADS on the target (the aircraft under attack). When the enemy simultaneously launches a missile from different directions within the attack-hazardous zone, block 3 generates a combination of control signals that are simultaneously fed to the inputs of the corresponding directional emitters of block 1, which simultaneously generate radiation of simulating active interference, the spatial distribution of which in the aircraft protection zone is determined by the joint action of the directional emitters included in block 1, the radiation indicatrices of which overlap those sections of the protection zone of the space surrounding the aircraft in which the attacking aircraft are located with the missile at each moment in time.

The proposed design of the onboard PPE of an aircraft against the damaging effects of MANPADS allows for the prompt automatic control of the formation of active interference radiation in the control system for the guidance of the MANPADS at the target and the simulating active interference of the IR homing head of the attacking aircraft without the direct participation of the pilot and other members of the aircraft crew, which is extremely important when conducting active combat operations.

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

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Claims (1)

An on-board system for individual protection of an aircraft from the damaging effects of man-portable air defense missile systems, comprising an actuator unit which is configured to form, in the direction of a guided missile with an infrared homing head of a man-portable air defense missile system attacking the aircraft, a simulated active interference in the form of modulated non-coherent infrared radiation in the spectral range of sensitivity of the infrared homing head of the attacking guided missile and is equipped with a group of directional emitters installed motionless relative to the body of the aircraft, identical in lighting characteristics, the combined radiation indicatrix of which covers in azimuth and elevation the protection zone of the aircraft from the damaging effects of man-portable air defense missile systems, a setting unit configured to detect and track the guided missile attacking the aircraft in the form of a passive optoelectronic device for remotely recording the ultraviolet component of the radiation from the torch of the jet propulsion system of the attacking missile, the zone the sensitivity of which covers the protection zone of the aircraft in azimuth and elevation, and a control action generation unit, which is made in the form of an electronic device with the ability to provide a given pulse-periodic structure and intensity of incoherent infrared radiation generated by directional emitters included in the actuator unit, within the time interval of being in the spatial operation zone of each of them of the attacking guided missile, and is equipped with a number of control action outputs according to the number of directional emitters of the actuator unit that form the group, each of which is connected through an autonomous control command transmission line to the corresponding directional emitter, characterized in that the actuator unit is made with the ability to operate in an additional mode, which is the formation of active interference in the optical-visual control path for guiding the portable anti-aircraft missile system to the target, which includes a thermal imaging sight, and the setting unit is additionally equipped with a brightness meter oriented in the direction of the sky background in the spectral range of operation of the thermal imaging sight of the portable anti-aircraft missile system, which is identical to the spectral sensitivity range of the infrared homing head of the attacking aircraft guided missile of the portable anti-aircraft missile system, and the control action generation unit is designed with the possibility of generating, by directional emitters included in the actuator unit, within the time interval of absence in the spatial operation zone of each of them of the attacking guided missile, pulses of incoherent infrared radiation that are repeated in time and constant in amplitude in the spectral operating range of the thermal imaging sight, the fixed repetition frequency of which corresponds to the α-rhythm of the human brain, the duration of which corresponds to the inertia time of the human visual organs, and the brightness value is not less than 1.5⋅V _f cd/m ² , but not more cd/ ^m2 , where B _f is the brightness of the sky background in the combat zone in the infrared range of the thermal imaging sight, which is part of the optical-visual control path for guiding the portable anti-aircraft missile system to the target.

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