KR20220121473A - Apparatus and Method for evaluating realtime Hit Probabilities to Antiair Target based on Shot Groups Proability Model - Google Patents

Abstract

The present invention relates to a method and apparatus for real-time evaluation of anti-aircraft target hits based on a shot group probability model. The method includes the steps of: estimating a radar cross-section (RCS) of an anti-aircraft target; using a tracking radar of the close-in weapons system to assume positions of impact points; calculating a distribution area of the impact points based on an impact range of the fired projectiles and an error in the impact points on the anti-aircraft target; calculating hit probabilities on the anti-aircraft target using the calculated distribution area of the impact points; calculating an interception probability on the anti-aircraft target using a cumulative probability of the calculated hit probabilities; and switching the target to a lower-priority anti-aircraft target if the calculated interception probability exceeds a predetermined threshold. The evaluation of hits on the anti-aircraft target is performed based on the distribution area of the impact points of the individual projectiles fired toward the anti-aircraft target, without the intervention of an operator. This allows for minimizing time to respond to nearby lower-priority anti-aircraft targets in a multiple-target response scenario.

Description

Apparatus and Method for evaluating realtime Hit Probabilities to Antiair Target based on Shot Groups Proability Model

The present invention relates to a real-time anti-aircraft target hit evaluation method and apparatus based on an impact group probability model for performing hit evaluation on the anti-aircraft target without operator intervention based on the impact point distribution area.

Korean warships pursue ship survivability as an anti-aircraft target, the main threat target, through the installation of a close-range defense weapon system (CIWS). ) and ii) It is composed of 30mm Gatling guns armed to shoot down close targets and a fire control system that controls them.

It is important that the steps necessary for engagement (detection/identification, threat assessment, target designation, engagement, hit assessment, end of engagement, target conversion) proceed quickly in the close defense weapon system. According to the engagement procedure in general battleships, in most cases, in the method of detection, identification, threat assessment, tracking, and hit evaluation necessary after engagement, the information from the available sensors (optical sensor, radar, etc.) After confirming with , manually evaluate the hit/intercept of the target.

Looking at Korean Patent Application Laid-Open No. 2008-0013376, which is a shell hit evaluation system and method for evaluating whether a shell hits a target area when firing an artillery as a prior art related to hit evaluation, the position coordinates of at least two light sources and a plurality of The steps of receiving the position coordinates of the light receiving sensor unit including the light receiving sensor, setting the effective impact area center point based on the position coordinates of the light source and the light receiving sensor unit position coordinates, and setting the effective impact area based on the center point, and the shell A step of recognizing a light receiving sensor that a part of the light received by the light receiving sensor unit is blocked while passing, and calculating the passing position of the shell based on the positional coordinates of the light source and the positional coordinates of the light receiving sensor recognized by the light receiving sensor unit And by comparing the effective impact area and the passing position, it is possible to accurately evaluate whether the shell is hit or not, regardless of the skill of the observer, including the step of determining whether or not the shell hits, and it is possible to perform the hit assessment at night easily and inexpensively. A system that can be implemented can be implemented. In addition, the system operation of the evaluator is easy and the measurement error can be minimized.

The limitation of the conventional hit evaluation technique is that the survivability of the ship is lacking due to the lack of response time to the next-ranked threat target when the operator manually evaluates the target's hit/intercept when engaging the simultaneous approaching target, and the operator's manual hit evaluation of the target The point is that whether or not the target is intercepted is determined by a qualitative judgment rather than a quantitative numerical value.

The present invention aims to provide a real-time anti-aircraft target hit evaluation method and apparatus based on an impact group probability model that performs hit evaluation on the anti-aircraft target without operator intervention based on the distribution area of the impact point of each bullet fired toward the anti-aircraft target. There is this.

In addition, an object of the present invention is to provide a method and apparatus for real-time hit evaluation of an anti-aircraft target based on an impact group probability model that minimizes the response time to the next-ranked adjacent anti-aircraft target when responding to multiple anti-aircraft targets.

The anti-aircraft target real-time hit evaluation method based on the impact group probability model according to an embodiment of the present invention is an anti-aircraft target hit evaluation method, based on the impact point distribution area of individual bullets fired toward the anti-aircraft target without operator intervention. It is possible to minimize the response time to the next closest anti-aircraft target when responding to multiple anti-aircraft targets based on this.

In one embodiment, the method comprising: estimating a radar reflection area (RCS) for the anti-aircraft target; estimating the location of the impact point using the tracking radar of the proximity defense weapon system; calculating a distribution area of an impact point using an impact range of the fired bullet and an impact point error with respect to the anti-aircraft target; calculating a hit probability for the anti-aircraft target using the calculated distribution area of the impact point; calculating an intercept probability for the anti-aircraft target by using the accumulated probability of the calculated hit probability; And when the calculated interception probability is greater than or equal to a preset threshold, it is possible to include the step of switching the target to the next-ranking target.

As an embodiment, in the step of calculating the impact point distribution area, it is possible to calculate the distribution area of the impact point proportional to the square of a value obtained by multiplying the impact range of the individual bullet by the impact point error of the individual bullet.

As an embodiment, each of the radar reflection area of the target and the stochastic distribution area of the impact point may be formed so that the position of the anti-aircraft target exists therein.

As an embodiment, in the step of calculating the hit probability, it is possible to calculate the hit probability as a ratio of the radar reflection area of the anti-aircraft target to the distribution area of the impact point.

As an embodiment, in the step of calculating the hit probability, when the probability distribution area of the impact point of the individual bullet is smaller than the radar reflection area of the target, it is possible to calculate the hit probability as 1.

As an embodiment, in the step of calculating the interception probability, the interception probability is calculated as a ratio of the cumulative probability of the hit probability to the cumulative hit probability parameter, and when the cumulative probability of the hit probability is greater than the cumulative hit probability parameter, the It is possible to calculate the interception probability as 1.

As an embodiment, in the interception probability calculation step, if the calculated interception probability is equal to or greater than a preset interception probability threshold, it is possible to determine that the fired bullet intercepts the anti-aircraft target as success.

In one embodiment, the anti-aircraft target is an anti-aircraft target flying at a high speed between subsonic speed and supersonic speed, and the impact point error for the anti-aircraft target is an error when the position of the individual bullet is close to the anti-aircraft target by the shortest distance. characterized by being.

An anti-aircraft target real-time hit evaluation apparatus based on an impact group probability model according to an embodiment of the present invention includes: a target RCS estimator for estimating a radar reflection area (RCS) for an anti-aircraft target; an impact point location estimator for estimating the location of the impact point of each bullet with respect to the anti-aircraft target using the tracking radar of the proximity defense weapon system; an impact point distribution area calculation unit for calculating an impact point distribution area that is proportional to the square of the impact range of the individual bullet fired toward the anti-aircraft target and the impact point error of the individual bullet with respect to the anti-aircraft target; a hit probability calculator for calculating a hit probability for the anti-aircraft target by a ratio of the radar reflection area of the anti-aircraft target to the distribution area of the impact point; an interception probability calculator configured to calculate an interception probability for the anti-aircraft target by a ratio of the cumulative probability of the hit probability to the cumulative accuracy parameter; And when the calculated interception probability is greater than or equal to a preset threshold, it includes a target switching unit for switching the target to the next-ranked target.

As an embodiment, the hit probability calculator may calculate the hit probability as 1 when the probability distribution area of the impact point of the individual bullet is smaller than the radar reflection area of the target.

In an embodiment, the interception probability calculator may calculate the interception probability as 1 when the cumulative probability of the hit probability is greater than the cumulative hit probability parameter.

In one embodiment, the interception probability calculation unit, when the calculated interception probability is equal to or greater than a preset interception probability threshold, it is possible to determine that the fired bullet intercepts the anti-aircraft target as a success.

As an embodiment, the anti-aircraft target is an anti-aircraft target flying at a high speed between subsonic speed and supersonic speed, and the impact point error for the anti-aircraft target is when the position of the individual bullet is close to the anti-aircraft target by the shortest distance. It is possible that it is an error.

An anti-aircraft target real-time hit evaluation method and apparatus based on an impact group probability model according to an embodiment of the present invention can perform hit evaluation on an anti-aircraft target based on the distribution area of the impact point of each bullet fired toward the anti-aircraft target without operator intervention. there is an effect

In addition, the real-time anti-aircraft target hit evaluation method and apparatus based on the impact group probability model according to an embodiment of the present invention has the effect of minimizing the response time for the next-ranked anti-aircraft target when responding to multiple anti-aircraft targets.

1 is a schematic diagram of an anti-aircraft target real-time hit evaluation device based on a probability model of an impact group according to an embodiment of the present invention.
2 is a flowchart of a real-time anti-aircraft target hit evaluation method based on an impact group probability model according to an embodiment of the present invention.
3 shows the correlation between the impact point error of the bullet, the impact range of the bullet, the radar reflection area of the target, and the partial surface area of the impact point when calculating the partial surface area of the impact point;
4 shows the correlation between the target position, the radar reflection area of the target, and the partial surface area of the impact point when calculating the hit probability.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments published below, but may be implemented in various different forms, and only these embodiments make the publication of the present invention complete, and common knowledge in the art to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

Unless otherwise defined, all terms (including technical and scientific terms) used herein may be used with the meaning commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in a commonly used dictionary are not to be interpreted ideally or excessively unless clearly defined in particular.

In the present specification, terms such as “first” and “second” are for distinguishing one component from other components, and the scope of rights should not be limited by these terms. For example, a first component may be termed a second component, and similarly, a second component may also be termed a first component.

In the present specification, identification symbols (eg, a, b, c, etc.) in each step are used for convenience of description, and identification symbols do not describe the order of each step, and each step is clearly Unless a specific order is specified, the order may differ from the specified order. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the reverse order.

In this specification, expressions such as “have”, “may have”, “include” or “may include” indicate the existence of a corresponding feature (eg, a numerical value, function, operation, or component such as a part). and does not exclude the presence of additional features.

In addition, the term '~ unit' as used herein means software or a hardware component such as a field-programmable gate array (FPGA) or ASIC, and '~ unit' performs certain roles. However, '-part' is not limited to software or hardware. '~unit' may be configured to reside on an addressable storage medium or may be configured to refresh one or more processors. Thus, as an example, '~' denotes components such as software components, object-oriented software components, class components, and task components, and processes, functions, properties, and procedures. , subroutines, segments of program code, drivers, firmware, microcode, circuitry, data structures and variables. The functions provided in the components and '~ units' may be combined into a smaller number of components and '~ units' or further separated into additional components and '~ units'.

Hereinafter, a method and apparatus for real-time hit evaluation of an anti-aircraft target based on an impact group probability model according to an embodiment of the present invention will be described in detail with reference to the related drawings.

1 is a schematic diagram of an anti-aircraft target real-time hit evaluation apparatus based on an impact group probability model according to an embodiment of the present invention, and FIG. 2 is a flowchart of a real-time anti-aircraft target hit evaluation method based on an impact group probability model according to an embodiment of the present invention; 3 shows the correlation between the impact point error of the bullet, the impact range of the bullet, the radar reflection area of the target, and the partial surface area of the impact point when calculating the partial surface area of the impact point. It shows the correlation between the radar reflection area of

In this embodiment, continuous shooting is made from the gun to the anti-aircraft target, and the current i-th shot is fired toward the anti-aircraft target, and the accuracy evaluation of the i-th shot is progressed. In addition, in this embodiment, the target of the close defense weapon system is mainly a high-speed (subsonic ~ supersonic) anti-aircraft target.

1, the real-time anti-aircraft target hit evaluation apparatus 100 based on the impact group probability model according to an embodiment of the present invention is a target RCS estimation unit ( 110), the impact point location estimation unit 120 for estimating the location of the impact point of each bullet on the anti-aircraft target using the tracking radar of the proximity defense weapon system, the impact point using the impact range of each bullet and the impact point error of each bullet Impact point distribution area calculation unit 130 for calculating the distribution area of the hit probability calculation unit 140 for calculating the probability of hitting the anti-aircraft target using the calculated impact point distribution area and the radar reflection area 140, cumulative hit An interception probability calculator 150 that calculates the interception probability for the anti-aircraft target by using the probability parameter and the cumulative probability of the hit probability, and when the calculated interception probability is greater than or equal to a preset threshold, the target is switched to the next-ranked anti-aircraft target and a target conversion unit 160 .

1 to 4, the real-time anti-aircraft target hit evaluation method based on the impact group probability model according to an embodiment of the present invention will be described in more detail with reference to FIGS. Result) stage, the hit evaluation procedure starts at the same time as the guns, the weapons of the close defense weapon system, fire (engagement) on the target, and the calculation or estimation of the radar reflection area (RCS) of the target is required to calculate the probability of hit. need.

The target RCS estimation unit 110 may be a tracking radar of the close defense weapon system, and it is possible to estimate and calculate the radar cross section (RCS) of the target for the anti-aircraft target through the tracking radar ( S110).

Here, the radar cross section (RCS) of the target is a value expressed in units of area by which electromagnetic waves radiated from the radar are reflected back to the object. RCS is defined as the projected area of a sphere that reflects electromagnetic waves of the same size as the target. It can be expressed as the ratio of the power of the transmitted electromagnetic wave to the power of the transmitted electromagnetic wave (Knott et al., 1993).

------------------------------(1)

------------------------------(One)

Here, E _i is an incident wave in which the electromagnetic wave transmitted from the radar is incident on the target, E _s is the scattered wave that is scattered from the target and returns to the radar direction, and R is the distance between the radar and the target.

The impact point location estimator 120 is, after the target RCS estimator 110 estimates the radar cross section (RCS) of the target, the i-th shot among the shots fired through the artillery and the closest proximity to the target target Estimate the distance (S120). That is, it is necessary to estimate the spatial positions of individual bullets in order to determine whether the bullets fired from the guns hit the target.

In the proximity defense weapon system, the tracking radar tracks the position of individual bullets in real time, while tracking the position according to the movement of the target in real time. To calculate the probability of hitting an individual bullet, the position of the bullet's impact point (the position of the bullet at the point where the relative distance between the target and the individual bullet is the shortest) is calculated through the tracking radar.

That is, the impact point location estimation unit 120 may be a tracking radar of the proximity defense weapon system. In this case, the tracking radar tracks the location of the i-th bullet in real time, and also tracks the location of the target in real time. The error is calculated when the target and the position of the i-th shot are close to each other by the shortest distance.

The impact point distribution area calculation unit 130 calculates an impact point distribution area that is proportional to the square of a value obtained by multiplying an impact range of an individual bullet by an impact point error of an individual bullet (S130). The impact point distribution area calculation unit 130 calculates the probabilistic distribution area of the impact point of the ith bullet based on the closest distance between the ith bullet and the target target.

The distribution area (B(i)) of the impact points of individual bullets is calculated by Equation (2).

B(i) = π x (R _Impact (i) x σ(i) x 0.5) ² -----------------------(2)

Here, σ(i) is the impact point error of the i-th bullet, and R _Impact (i) is the distance between the target where the i-th bullet encounters the target closest to the target by σ(i). R _Impact (i) is the estimated hit point, which can be calculated via PHP.

B(i) is calculated as a probabilistic area in space where the impact point distribution at the impact point location of the ith shot is based on the impact point error (σ(i)) of the ith shot. The impact point error of the i-th bullet can be interpreted/defined from various viewpoints, but in this embodiment, real-time calculation is possible, and probabilistic modeling is easy.

The distribution area (B(i)) of the impact point from the distance (R _Impact (i)) of the target at which an individual bullet encounters the target closest to the target due to the impact point error (σ(i)) of the i-th bullet is calculated by Equation (2) follow

The impact point error (σ(i)) of the i-th bullet is modeled with a probability distribution such as a Gaussian/Rayleigh that effectively represents a natural phenomenon and a method that uses the value measured through the tracking radar as it is. have.

The hit probability calculator 140 calculates the hit probability as the ratio of the radar reflection area of the anti-aircraft target to the distribution area of the impact point (S140), and when the distribution area of the impact point of the i-th bullet is smaller than the radar reflection area of the target, the Accuracy is calculated as 1.

Hitting Probability is defined as the probability that the i-th shot fired from the gun can hit the target, and is calculated by Equation (3). This is a variable that can be calculated in the tracking radar of the close defense weapon system.

Pro(Hit, i) = T(i) / B(i)

= T(i)/B(i) = T(i)/{π x (R _Impact (i) x σ(i) x 0.5) ² }----(3)

Here, T(i) is the radar reflection area (RCS) of the target, and B(i) is the distribution area of the i-th impact point.

If the value of B(i) is less than T(i) (B(i) ≤ T(i)), the accuracy Pro(Hit, i) is 1. That is, the probability value cannot exceed 1.

T(i) is a constant as the RCS of the target, and can be expressed as, for example, 0.1m ² , 0.5m ² , and the like.

Referring to FIGS. 4A and 4B , it can be seen that the position of the anti-aircraft target exists inside the area calculated by the radar reflection area and the area calculated by the distribution area of the impact point.

The interception probability calculation unit 150 calculates the interception probability as the ratio of the cumulative probability of the hit probability to the cumulative hit probability parameter as shown in Equation (4) (S150), and the calculated intercept probability is greater than or equal to the preset interception probability threshold or It is determined by comparing whether it is less than (S160).

Pro(Kill, i) = ∑Pro(Hit, j) / λ ---------------------(4)

where j = 1, 2, ... , i, and λ is the cumulative accuracy parameter.

In addition, the cumulative accuracy parameter (λ) and the intercept probability threshold value (δ) represent the probability values of how many hits a 30mm Gatling bullet must hit an anti-aircraft target for the target to be shot down. For example, if the cumulative accuracy parameter (λ) is '3' and the intercept probability threshold value (δ) is '0.95', if a 30mm Gatling bullet hits three anti-aircraft targets, the probability that the target target will be shot down is 0.95. That is, the cumulative accuracy parameter (λ) and the intercept probability threshold (δ) are determined by the type of 30mm Gatling bullet (penetrating type, detonation type, etc.), the kinetic energy of the bullet, the amount of impact and the kinetic energy of the anti-aircraft target, and the kinetic energy of the anti-aircraft target. Considering the mechanical structure, etc., a separate shooting effect can also be determined through analysis and simulation.

The interception probability calculation unit 150 determines that the fired ith shot successfully intercepts the anti-aircraft target when the calculated interception probability is equal to or greater than a preset interception probability threshold value (δ), and a preset interception probability threshold value If it is less than (δ), in order to calculate the intercept probability of the next bullet (i+1th bullet), the estimation of the impact point of the i+1th bullet and subsequent procedures are performed again.

If the cumulative probability of hit probability is greater than the cumulative hit probability parameter, the interception probability is calculated as 1.

If the interception probability Pro(Kill, i) ≥ δ, it is determined that the target is intercepted.

Here, since the probability cannot exceed 1, if ∑Pro(Hit, j) ≥ λ, it is defined as ∑Pro(Hit, j) = λ. That is, Pro(Kill, i) = 1.

The cumulative accuracy parameter λ varies depending on the type of anti-aircraft target, and it means that the target will be intercepted if a bullet hits the target as much as λ.

In the final step of the hit evaluation, the target switching unit 160 determines whether or not to end the engagement according to the intercept determination and switches the target for allocating the sensor/arming resources of the proximity defense weapon system to the next priority target (S170). When responding to multiple targets, by terminating the hit evaluation of the i-th shot and automatically designating the target as the next threat target, it is possible to respond to the next-ranked close-range anti-aircraft target with the minimum response time without operator intervention. .

When using the hit evaluation apparatus and method according to the embodiment of the present invention described above, the anti-aircraft target hit evaluation through the firing of 30mm guns of the close defense weapon system is performed automatically by the system rather than a manual method by the operator, and thus hits during simultaneous target engagement It is possible to minimize the system latency in evaluation and target switching.

In addition, the hit evaluation apparatus and method according to the embodiment of the present invention described above is a hit evaluation method in a defense system against a short-range anti-aircraft target at sea and a hit evaluation method in a defense system against a short-range anti-aircraft high-speed target on land. can be used

The real-time anti-aircraft target hit evaluation method and apparatus based on the impact group probability model according to the present invention can contribute to the automation and effective operation of the close defense weapon system by performing the hit evaluation of the target based on the mathematical/probabilistic model without operator intervention. It is possible to present a standard for effectively operating the resources (sensors, armaments, etc.) of the close defense weapon system by calculating the accuracy of each shot in real time and providing it to the operator. When responding to multiple targets, the system automatically determines the hit evaluation, minimizing the response time delay for the next-order close anti-aircraft target.

110: target RCS estimation unit
120: impact point location estimation unit
130: impact point distribution area calculation unit
140: hit probability calculator
150: interception probability calculator

Claims (13)

As a method for evaluating the accuracy of an anti-aircraft target,
Based on the distribution area of the impact points of individual bullets fired toward the anti-aircraft target, the hit evaluation is performed on the anti-aircraft target without operator intervention, and based on this, when responding to multiple anti-aircraft targets, the response time to the next-ranked closest anti-aircraft target is minimized. An anti-aircraft target real-time hit evaluation method based on the impact group probability model. According to claim 1,
estimating a radar reflection area (RCS) for the anti-aircraft target;
estimating the location of the impact point using the tracking radar of the proximity defense weapon system;
calculating a distribution area of an impact point using an impact range of the fired bullet and an impact point error with respect to the anti-aircraft target;
calculating a hit probability for the anti-aircraft target using the calculated distribution area of the impact point;
calculating an intercept probability for the anti-aircraft target by using the accumulated probability of the calculated hit probability; and
When the calculated interception probability is greater than or equal to a preset threshold, switching the target to the next-ranking public target
A real-time anti-aircraft target hit evaluation method based on the impact group probability model, including 3. The method of claim 2,
In the step of calculating the distribution area of the impact point,
A real-time anti-aircraft target hit evaluation method based on an impact group probability model, characterized in that the distribution area of the impact point is calculated in proportion to the square of a value obtained by multiplying the impact range of each bullet and the impact point error of each bullet. 3. The method of claim 2,
In the step of calculating the hit probability,
A real-time hit evaluation method based on an impact group probability model, characterized in that the hit probability is calculated as a ratio of the radar reflection area of the anti-aircraft target to the distribution area of the impact point. 5. The method of claim 4,
In the step of calculating the hit probability,
When the probability distribution area of the impact point of the individual bullet is smaller than the radar reflection area of the target, the hit probability is calculated as 1. 3. The method of claim 2,
In the interception probability calculation step,
The interception probability is calculated as the ratio of the cumulative probability of the hit probability to the cumulative hit probability parameter, and when the cumulative probability of the hit probability is greater than the cumulative hit probability parameter, the interception probability is calculated as 1. A real-time hit evaluation method based on a probabilistic model. 7. The method of claim 6,
In the interception probability calculation step,
When the calculated interception probability is greater than or equal to a preset interception probability threshold, the shot group probability model-based real-time anti-aircraft target hit evaluation method, characterized in that it is determined that the fired bullet intercepts the anti-aircraft target as a success. 3. The method of claim 2,
The anti-aircraft target is an anti-aircraft target real-time hit evaluation method based on an impact group probability model, characterized in that it is an anti-aircraft target that flies at a high speed between subsonic speed and supersonic speed. a target RCS estimation unit for estimating a radar reflection area (RCS) for an anti-aircraft target;
an impact point location estimator for estimating the location of the impact point of each bullet with respect to the anti-aircraft target using the tracking radar of the proximity defense weapon system;
an impact point distribution area calculation unit for calculating an impact point distribution area that is proportional to the square of the impact range of the individual bullet fired toward the anti-aircraft target and the impact point error of the individual bullet with respect to the anti-aircraft target;
a hit probability calculator for calculating a hit probability for the anti-aircraft target by a ratio of the radar reflection area of the anti-aircraft target to the distribution area of the impact point;
an interception probability calculator configured to calculate an interception probability for the anti-aircraft target by a ratio of the cumulative probability of the hit probability to the cumulative accuracy parameter; and
When the calculated interception probability is greater than or equal to a preset threshold, an impact group probability model-based anti-aircraft target real-time hit evaluation device including a target switching unit for switching the target to the next-ranked anti-aircraft target. 10. The method of claim 9,
The hit probability calculation unit,
When the stochastic distribution area of the impact point of the individual bullet is smaller than the radar reflection area of the target, the hit probability is calculated as 1. 10. The method of claim 9,
The interception probability calculation unit,
When the cumulative probability of the hit probability is greater than the cumulative hit probability parameter, the intercept probability is calculated as 1. 12. The method of claim 11,
The interception probability calculation unit,
When the calculated interception probability is greater than or equal to a preset interception probability threshold, the shot group probability model-based anti-aircraft target real-time hit evaluation apparatus, characterized in that it is determined that the fired bullet intercepts the anti-aircraft target as a success. 10. The method of claim 9,
The anti-aircraft target is an anti-aircraft target flying at a high speed between subsonic speed and supersonic speed, and the impact point error for the anti-aircraft target is the error when the position of the individual bullet is close to the anti-aircraft target by the shortest distance. An anti-aircraft target real-time hit evaluation device based on the probability model of the impact group.

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