RU2472095C1 - Method of training tank weapons operators - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: guided projectile light source simulator is placed on target simulator while guided projectile model is arranged on sight, simulators of shot, lock-in and dynamics of projectile part to target. Guided projectile light source simulator is switched on to be clocked-in by control system. Operator aligns aiming line with aiming mark on target simulator to measure range thereto and to define projectile flight time. Projectile start is simulated to keep aiming line at aiming mark and simulate projectile flight dynamics in sight field of vision. Departure of said line from said mark is continuously measured and registered. Measured deviations are compared to target simulator sizes. Deviations exceeding said sizes are considered misses. Those in flight are considered loss of control while weapons control algorithm failure is considered the operator fault.

EFFECT: higher training efficiency, improved performances.

Description

The invention relates to the military field, in particular to methods for training operators of high-precision weapons in firing guided projectiles. It is intended to increase the efficiency of education and training of operators in guiding and firing techniques using standard equipment for guided missile systems of combat vehicles (tanks, infantry fighting vehicles, etc.), anti-tank missile systems (ATGMs) and other installations with optical guidance devices for launching guided missiles and shells.

The process of training operators should ensure that they are taught the right skills to use weapons and that the conditions for aiming weapons at the target are taken into account, taking into account the specifics of real controls, including the static and dynamic characteristics of moving controls in weapons and auxiliary equipment, with the conditions of real aiming.

There is a method of training operators of high-precision weapons of missile launch and firing weapons and machine guns of BMP type TKNO-675 developed in 1995 [1], which provides for simulating the rotation of missile launch systems, optical guidance devices, computers that generate signals for visible movement of the image of the area, and targets relative to the targeted brands of imitators of optical guidance devices, allowing for guidance of missile launch installations or firing at targets. The disadvantage of this method is the lack of the possibility of direct observation of the terrain and the target without an optical observation device, as well as a significant difference in the perception of the image of the terrain, targets and aim marks from the perception through the real device of guidance of the real terrain, targets and aim marks.

A known method of training operators of precision weapons, implemented in the simulator according to US patent 5215465 from June 1, 1993 [2], according to which the aiming is carried out using a source of information infrared beam, which creates an aiming point on the screen. Its disadvantage is the small distance from the screen to the student, which does not allow him to correctly orient and determine the range, since accommodation corresponds to the distance to the screen, and not the real distance to the simulated objects and terrain. The small distance to the screen also does not allow the use of standard optical sights for training aimed at aiming at long ranges to targets, namely such optical guidance devices are used in missile launch devices and guns.

By the totality of common essential features, the closest to the claimed method is the method of training high-precision weapon operators for the T-80 B [3] 9K112-1 "Cobra" guided missile system (see, for example, Tank - T-80B. Technical description and instructions on operation. M., Military Publishing House, 1984, S.95-127).

This method according to the technical essence and essential features is the closest to the claimed and adopted for its prototype. At the same time, it is also the basic object of the proposed method.

A method of training the shooting of tank weapons operators with an artillery fire control system and a semi-automatic missile projectile control system using a radio command communication line and a modulated light source located on a guided missile projectile, including using standard equipment to form a stable aiming line and an information channel aligned with it coordinator, simulating a target, loading, firing, tracking a line first sight of the goal and evaluate the results of shooting.

The described method can be used at the initial stage of training for acquiring skills in weapons, studying the material and the algorithm of the operation of the equipment. In this case, the goal of training is achieved with negligible material costs.

In subsequent stages, the method can be transformed into a training method with real shooting. In this case, instead of simulated functions, the real functions of the equipment and the entire complex are performed.

The disadvantage of training through the production of real launches is the high cost of guided missiles and missiles, which are launched during training firing, and, as a result, the inability to provide a large number of training sessions for economic reasons.

The problem solved by the invention is to reduce the economic costs of training gunner-operators of tanks in firing guided projectiles (missiles).

This problem is solved by the fact that in the known method of training the shooting of tank weapons operators with an artillery fire control system and a semi-automatic missile projectile control system using a radio command line and a modulated light source located on a guided missile projectile, including the use of standard equipment for forming a stabilized sight aiming line and coordinator’s information channel aligned with it, target imitation, Arming, firing, tracking the aiming line for the target and evaluating the results of the shooting, set the simulator of the light of the guided projectile at the aiming point on the target simulator, and set the electron-optical model of the guided missile at the sight with its inclusion in its standard semi-automatic control system, simulators a shot, launch of a guided missile, its capture and flight dynamics to a target simulator, evaluate the correctness of the operator's actions when performing the established algorithm and arms control, they include a simulated light source of a guided missile, capture it using a semi-automatic control system, combine the operator of the aiming line with the aiming point on the target simulator and measure the distance to it, determine the "flight" time of the projectile, hold the aiming line at the aiming point at for a given time, simulate a shot and launch of a guided missile, hold the line of sight at the aiming point for half a time this projectile to the target, while simulating the dynamics of its flight in the sight’s field of view by introducing into it the implementation of the flight path of a guided missile obtained using an electronic spot at the output of its electron-optical model, it is continuously measured by the coordinator and the deviations of the aiming line from the simulator are recorded the light source of the guided projectile, the measured deviations are compared with the dimensions of the target simulator, deviations at the time of the projectile’s flight of the target simulator, exceeding its dimensions, deviations in t the value of the "flight" time of the projectile beyond the lower edge of the target simulator is estimated as the loss of a guided missile, and the operator’s violation of the weapon control algorithm is estimated as its error, the standard deviation of the aiming line from the simulator of the light source and the probability of the guided missile to hit the target in time and at the condition of its flight to it, which are taken into account during the final assessment of operators and the adjustment of the methodology for their further training.

The introduction of new significant features allows expanding the capabilities of the known methods, provides an increase in training efficiency by reducing the economic costs of training operators of high-precision tank weapons in guided missile shooting and a numerical increase in the number of such trainings during training, without reducing their quality.

Implementation of the proposed method is as follows. A stabilized aiming line is formed by analogy with the prototype. When training operators of high-precision weapons, for example, with a semi-automatic projectile control system using a radio command line and a modulated light source mounted on a guided projectile (see prototype), they include and use the standard equipment of the tank’s fire control system, guided weapons complex and other tank elements ( for example, a power supply system) to form a stabilized aiming line and coordinator information channel aligned with it. Perform (trained) the functions necessary for real firing with a guided projectile: simulate loading by a simulator of a projectile, standard loading controls, simulate using standard firing circuits, firing a shot, and using the standard guidance drives align the aiming line and track it (as directed leader) for the purpose and evaluate the actions of the trainee (by the trainee and the leader) to perform the necessary functions required when firing a guided projectile. At the same time, the reliability of the assessment is not high due to its restriction only to visual control “by eye” both by the trainee and the leader. The methodological level of such training is also low due to the lack of a guided projectile and information about its movement in the field of view of the trained light source. To eliminate these shortcomings on the target (target simulator) at the aiming point, a simulated light source of a guided projectile is installed so that it is “visible” to the standard control system, but not to the learner. This can be achieved by shielding it with a PC filter or polaroids in two planes. An electron-optical model of a guided missile with its inclusion in its full-time semi-automatic control system, simulators of a shot, launch, capture and flight dynamics of a guided projectile to a target is mounted on the sight. It is advisable to perform these simulators on the basis of a common (with an electron-optical model of URS) cathode ray tube, a spot on the screen of which is introduced into the field of view of the operator (student) to simulate the URS light source and its flight path, a sound generator that simulates the sound of a shot when pressed on the firing button and a time relay, which provides a delay in the time for firing a shot and the appearance of a guided projectile in the operator’s field of vision.

A simulated projectile light source is mounted on a target simulator. Real objects (during tactical exercises, exercises, joint tactical and fire exercises, etc.) can be used as target imitators. In this case, the inclusion is made by members of the staff crews of the facilities. At firing ranges and firing camps, targets operated by appropriate personnel may be used. In other cases, the light source simulator may be telecontrolled, for example, by radio.

They include a semi-automatic projectile control system and other standard elements for firing, capture a simulated projectile light source simulator using a semi-automatic missile projectile control system, train the target line with the aiming point on the target simulator and measure the distance to it, recalculate the measured range value into "flight "The time of the projectile, hold the aiming line for a predetermined time on the aiming point (for the prototype - 1-2 s), they simulate a shot and launch of a projectile, hold the aiming line at the aiming point during the projectile’s flight to the target, simulate the dynamics of its flight in the sight’s field of view (for the prototype: the appearance of a light spot in the field of view after 1.5-1.7 s, capture - after 1.7-1.9 s after the shot, and then controlled flight), continuously measured by the coordinator and fix the deviation of the aiming line from the simulated light source of the guided projectile, compare the measured deviations with the dimensions of the target simulator and, if the deviations in The moment of the projectile’s passage over the target’s missile’s contour, then this is estimated as a miss, and each exit of the aiming line during the “flight” time of the projectile beyond the lower edge of the target’s simulator is estimated as its “cutting into the ground”, the standard deviation of the aiming line from the source simulator is determined light and the probability of a guided missile hitting a target, provided it reaches it, which are taken into account during the final assessment and correction of the methodology for further training of operators.

The proposed training method is highly reliable assessment, since the measurement uses high-precision standard equipment for controlling the projectile. Its use can take place in real conditions and can be combined with other classes, exercises, etc., which will reduce educational time by 20-30%, as well as reduce the economic costs of operator training and training by saving expensive shells. The method provides a high coefficient of similarity to the real combat work of operators in the production of guided missile launches.

Information sources

1. Technical description of the training complex TKNO-675. M .: VA BTV (in operation).

2. US patent 5215465, F41G 3/26 of June 1, 1993

3. Tank - T-80B. Technical description and instruction manual. M., Military Publishing, 1984, S.95-127). Prototype.

Claims (1)

A method of training tank weapons operators with an artillery fire control system and a semi-automatic missile control system by using a radio command line and a modulated light source located on a guided missile projectile, including using standard equipment to form a stable aiming line in the sight and coordinator information channel connected to it , simulating a target, loading, firing a shot, tracking with a line of sight aiming and evaluating the results of firing, characterized in that a simulated light source of the guided projectile is installed at the aiming point on the target simulator, and an electron-optical model of the guided missile is included in the sight with its inclusion in its standard semi-automatic control system, firing, launch simulators guided missile, its capture and flight dynamics to the target simulator, evaluate the correctness of the operator’s actions when performing the established weapon control algorithm, include simulator of a light source of a guided missile projectile, capture it by means of a semi-automatic control system, combine the aiming line operator with the aiming point on the target simulator and measure the distance to it, determine the "flight" time of the projectile, hold the aiming line on the aiming point for a given time, simulate the shot and launch of a guided missile, hold the line of sight on the aiming point during the flight time of the projectile to the target, simulate at m in the sight of the sight, the dynamics of its flight by entering into it the implementation of the flight path of a guided missile obtained using an electronic spot at the output of its electron-optical model, is continuously measured by the coordinator and the deviations of the aiming line from the simulated light source of the guided projectile are recorded, the measured deviations with the dimensions of the target simulator, deviations at the time of the projectile’s flight of the target simulator, exceeding its size, extending beyond its contour, are estimated as a miss, an open maneuvers during the "flight" time of the projectile beyond the lower edge of the target simulator are estimated as the loss of a guided missile, and the operator’s violation of the weapon control algorithm is estimated as its error, the standard deviation of the aiming line from the simulator of the light source and the probability that the guided missile hits the target during time and subject to its flight to it, which are taken into account during the final assessment of operators and the adjustment of the methodology for their further training.