RU190098U1 - DEVICE FOR EVALUATING THE EFFICIENCY OF A ZENIT ROCKET COMPLEX - Google Patents

Abstract

The utility model relates to special-purpose digital devices and can be used to quantify the performance indicators of anti-aircraft missile systems when targets are detected and hit. The device contains a knowledge base, an inference engine, a working memory, an explanation unit, a user interface, a knowledge acquisition unit, and an output the knowledge base and the first output of the working memory are connected to the first and second inputs of the logic output machine, the third input of the logic output machine is connected to the second one The output of the knowledge acquisition unit, the first and second outputs of the logic output machine are connected to the knowledge base input and the working memory input, the third output of the logic output machine is connected to the first input of the explanation block, the output of the explanation block and the first output of the knowledge acquisition unit are connected to the first and second user inputs interface, the first and second outputs of the user interface are connected to the second input of the explanation block and the input of the knowledge acquisition block, the third input and the third output of the user interface they are the input and output of a device for evaluating the effectiveness of an anti-aircraft missile system in detecting and hitting targets. According to the utility model, the device additionally includes a target probability detection unit, a target missile error calculation unit, a target target probability calculation unit, an effective target dispersion surface calculation unit, a target trajectory characteristics calculation unit, a target vulnerability calculation unit, with the fourth output of the logic output machine with the second input of the block for calculating the probability of target detection, the third input of the block for calculating errors of the missile defense system, the third input for the block for calculating the probability of hitting the target, ohm block calculating trajectory characteristics of the target, the fourth input of the logic output machine is connected to the output of the block calculating the target's vulnerability, the fifth input is connected to the output of the block calculating the effective target scattering surface, the output and the third input of the block calculating the probability of detection of the target missile pointing errors, the second output and the fourth input of the missile guided error calculation unit are connected to the first input and the first output of the target probability calculation module, the second output of the calculated The probability of hitting a target is connected to the second input of the target vulnerability calculation unit, the first input of the target vulnerability calculation unit is connected to the third output of the target trajectory characteristics calculation unit, the first output of the target trajectory characteristics calculation block is connected to the input of the effective scattering target calculation unit, the second output is connected to the first input of the unit for calculating the probability of detecting a target, the second input of the unit for calculating errors of the missile guidance, the second input of the unit for calculating the probability of hitting the target. 1 il.

Description

The utility model relates to special-purpose digital devices and can be used to quantify the performance indicators of anti-aircraft missile systems when targets are detected and hit.

Known devices [RU 2633169, publ. 11.10.2017; 2585724, publ. 06/10/2016; 161982, publ. 05/20/2016; 126168, publ. 03/20/2013; 103412, publ. 04/10/2011; 2009141308, publ. 02/10/2010; 73092, publ. 05/10/2008; 2003112587, publ. 12/20/2004; 30205, publ. 06.20.2003; 29598, publ. May 20, 2003; 24886, publ. 08.27.2002; 99114299, publ. 10.04.2001], designed to assess the effectiveness of armament samples in various conditions.

A common drawback of the known devices is the impossibility of their use for the quantitative evaluation of the effectiveness indicators of an anti-aircraft missile complex in detecting and hitting targets.

The prototype of the claimed utility model is the system [D. Dzharatano, G. Riley. Expert systems. Principles of development and programming. - M .: Publishing house "Williams", 2007, fig. 1.6, s. 70], which includes a knowledge base, an inference machine, a working memory, an explanatory unit, a user interface, a knowledge acquisition unit, the outputs of the knowledge base and the working memory are connected to the first and second inputs of the logical output machine, the third input of the logical output machine is connected with the second output of the knowledge acquisition unit, the first and second outputs of the logic output machine are connected to the inputs of the knowledge base and the working memory, the third output of the logic output machine is connected to the first input of the explanation block, the output of the block As the explanations and the first output of the knowledge acquisition block are connected to the first and second inputs of the user interface, the first and second outputs of the user interface are connected to the second input of the explanation block and the input of the knowledge acquisition block, the third input and the third output of the user interface are connected to the external user. (are the input and output of the system).

The disadvantage of the known system is that it does not take into account the change in the effective dispersion surface and the target's vulnerability in different parts of its flight path.

The task of the utility model is to provide the possibility of a quantitative assessment of the effectiveness indicators of the anti-aircraft missile complex when targets are detected and hit, taking into account changes in the effective dispersion surface and vulnerability depending on the flight path.

The technical result of the utility model is the creation of a device for evaluating the effectiveness of an anti-aircraft missile complex in detecting and hitting targets, taking into account the change in the effective scattering surface when calculating the probability of target detection and the change in vulnerability when calculating the probability of hitting the target, depending on its flight path.

The achievement of the stated technical result and the solution of the task is ensured by the fact that the device for evaluating the effectiveness of an anti-aircraft missile complex when detecting and hitting targets, contains a knowledge base, an inference machine, a working memory, an explanation unit, a user interface, a knowledge acquisition unit, and the output base knowledge and the first output of the working memory is connected to the first and second inputs of the logical output machine; the third input of the logical output machine is connected to the second output of the block; knowledge, the first and second outputs of the logic output machine are connected to the knowledge base input and the working memory input, the third output of the logic output machine is connected to the first input of the explanation block, the output of the explanation block and the first output of the knowledge acquisition block are connected to the first and second inputs of the user interface, the first and second outputs of the user interface are connected to the second input of the explanation block and the input of the knowledge acquisition block, the third input and the third output of the user interface are the input and you the device for evaluating the effectiveness of an anti-aircraft missile system in detecting and hitting targets, additionally included a block for calculating the probability of detecting a target, a block for calculating missile guidance errors, a block for calculating the probability of hitting a target, a block for calculating the effective target dispersion surface, a block for calculating the trajectory characteristics of the target, a block for calculating vulnerability the target, the fourth output of the logic output machine is connected to the second input of the block for calculating the probability of target detection, the third input of the block for calculating errors Zurich, the third input of the target probability calculation unit, the input of the target trajectory characteristics calculation unit, the fourth input of the logic output machine is connected to the output of the target vulnerability calculation unit, the fifth input is connected to the output of the effective scattering surface calculation unit, the output and the third input of the probability calculation unit target detection is connected to the first input and the first output of the error calculation module, the ZUR guidance, the second output and the fourth input of the error calculation module, the ZUR guidance module are connected to the first input and the first output the house of the target probability calculation unit, the second output of the target probability calculation unit is connected to the second input of the target vulnerability calculation unit, the first input of the target vulnerability calculation unit is connected to the third output of the target trajectory characteristics calculation unit, the first output of the target trajectory characteristics calculation unit is connected to the block input calculation of the effective surface of the scattering of the target, the second output is connected to the first input of the block for calculating the probability of target detection, the second input of the block for calculating errors of the missile defense, the second m input block calculating the probability of hitting the target.

The proposed execution of the device allows you to quantify the performance indicators of an anti-aircraft missile complex when a target is detected by calculating the detection probability, linking the track and taking a target tracking taking into account the change in the effective scattering surface and hitting the target by calculating the probability of hitting the target taking into account the change in target vulnerability depending on its trajectory flight. An additional result of the use of the device is to improve the accuracy of quantitative estimates of the effectiveness of the anti-aircraft missile system in detecting and hitting targets and, as a consequence, the effectiveness of decisions taken in substantiating the characteristics of promising complexes.

The utility model is illustrated in the drawing, which shows a block diagram of a device for evaluating the effectiveness of an anti-aircraft missile system (Fig. 1).

In the drawing, the following notation:

1 - knowledge base;

2 - logical inference machine;

3 - working memory;

4 - block explanation;

5 - user interface;

6 - unit of knowledge acquisition;

7 - unit for calculating the probability of target detection;

8 - unit for calculating missile guidance errors;

9 - unit for calculating the probability of hitting the target;

10 is a block for calculating the effective surface scattering target;

11 - unit for calculating the trajectory characteristics of the target;

12 - block calculation of the vulnerability of the target.

Knowledge Base 1 is designed to store in memory the rules for calculating the effective scattering surface depending on the target location angle, the composition of the initial compartments and logic of target vulnerability depending on the sections of its flight trajectory, the rules for calculating target vulnerability depending on the angle of approach to the target. The input and output of the knowledge base 1 is connected to output 2.6 and input 2.1 of machine 2 logical inference.

The logical inference machine 2 is designed to perform logical and arithmetic operations with the data stored in working memory 3, in accordance with the rules stored in the knowledge base 1. Inputs 2.1 and 2.2 of the logical inference machine 2 are connected to the output of knowledge base 1 and the output of working memory 3 The input 2.3 is connected to the output 6.2 of the knowledge acquisition unit 6, the input 2.4 of the logic output machine 2 is connected to the output of the target vulnerability calculation unit 12, the input 2.5 is connected to the output of the effective dispersion surface calculation unit 10 of the target. Output 2.6 of logic output 2 is connected to the input of knowledge base 1, output 2.7 is connected to input of working memory 3, output 2.8 is connected to input 4.1 of explanation block 4, output 2.9 is connected to inputs 7.1 of block 7 for calculating the probability of target detection, 8.3 for block 8 for calculating errors guidance SAM, 9.3 block 9 calculate the probability of hitting the target, the input unit 11 calculate the trajectory characteristics of the target.

Working memory 3 is designed for storing in-memory digital maps of the terrain, data on tactical and technical characteristics of anti-aircraft missile systems, flight paths of targets, diagrams of the back reflection of targets, characteristics of vulnerability of the initial compartments and logic schemes of targets vulnerability. The input and output of the working memory 3 is connected to the output 2.7 and the input 2.2 of the logical output 2 machine.

Unit 4 of the explanation is designed to memorize and transfer information in transit by quantitative estimates of the effectiveness indicators of the anti-aircraft missile system when targets are detected and hit. Input 4.1 block 4 explanations connected to the output 2.8 of the machine 2 logical conclusion. Input 4.2 and output of block 4 explanations are connected to output 5.4 of user interface 5 and input 5.1 of user interface 5.

User interface 5 is designed to communicate with the user through the use of a standard set of hardware and software (display, keyboard, etc.). Input 5.1 of the user interface 5 is connected to the output of the explanatory unit 4, input 5.2 is connected to the output 6.1 of the knowledge acquisition unit 6, input 5.3 is the input of the device for evaluating the effectiveness of the anti-aircraft missile system for detecting and hitting targets and is connected to the system user. The output 5.4 of the user interface 5 is connected to the input 4.2 of the unit 4 of the explanation. Output 5.5 of the user interface is connected to the input of the knowledge acquisition unit 6. The output 5.6 of the user interface 5 is the output of the device for evaluating the effectiveness of the anti-aircraft missile system in detecting and hitting targets and is connected to the user of the system.

Unit 6 of knowledge acquisition is designed to organize a dialogue procedure, the purpose of which is to approve control actions to determine the effective surface and target vulnerability. The input of the knowledge acquisition unit 6 is connected to the output 5.5 of the user interface 5. The output 6.1 of the knowledge acquisition unit 6 is connected to the input 5.2 of the user interface 5, the output 6.2 of the knowledge acquisition unit 6 is connected to the input 2.3 of the logic output machine 2.

Unit 7 for calculating the probability of detecting a target is designed to simulate the functioning of a detection radar and target designation, which is part of an anti-aircraft missile system, by viewing the space, detecting the target, linking the route and issuing target indications. Input 7.2 of block 7 for calculating the probability of detecting a target is connected to the output 2.9 of logic output machine 2, input 7.1 is connected to output 11.2 of block 11 for calculating the trajectory characteristics of the target, input 7.3 is connected to output 8.5 for block 8 for calculating guided error errors. The output of the unit 7 for calculating the probability of detecting a target is connected to the input 8.1 of the unit 8 for calculating pointing errors of the missile defense system.

Block 8 of the calculation of guided missile guidance errors is intended to simulate the operation of a missile guidance radar for guiding missiles in telecontrol mode during the implementation of the three-point guidance method. Input 8.2 of block 8 for calculating guidance errors is connected to the output 11.2 of block 11 for calculating the trajectory characteristics of the target, input 8.3 is connected to output 2.9 of the logic output machine 2, input 8.4 is connected to output 9.4 of block 9 for calculating the probability of hitting the target. The output 8.5 of the unit 8 for calculating errors of the missile guidance is connected to the input 7.3 of the unit 7 for calculating the probability of target detection, the output 8.6 is connected to the input 9.1 for the unit 9 for calculating the probability of hitting the target.

Unit 9 for calculating the probability of hitting a target is intended to simulate the guidance of a missile defense system at a target in the telecontrol and homing modes in the final segment, the operation of a proximity firing device and target hitting. Input 9.2 of block 9 for calculating the probability of hitting a target is connected to output 11.2 of block 11 for calculating the trajectory characteristics of a target, input 9.3 is connected to output 2.9 of logic output machine 2. The output 9.4 of the block 9 for calculating the probability of hitting the target is connected to the input 8.4 of the block 8 for calculating guidance missile errors, the output 9.5 is connected to the input 12.2 of the block 12 for calculating the vulnerability of the target.

Block 10 for calculating the effective target scattering surface is designed to calculate the target location angle depending on the position of its center of mass relative to the location means. The input of the block 10 for calculating the effective target scattering surface is connected to the output 11.1 of the block 11 for calculating the trajectory characteristics of the target. The output of the block 10 for calculating the effective surface of the scattering of the target is connected to the input 2.5 of the logical inference machine 2.

The unit 11 for calculating the trajectory characteristics of the target is designed to calculate the position of the center of mass of the target relative to the simulated anti-aircraft missile system means. The input unit 11 of the calculation of the trajectory characteristics of the target is connected to the output 2.9 of the machine 2 logical conclusion. The output 11.1 of the block 11 for calculating the trajectory characteristics of the target is connected to the input of the block 10 for calculating the effective scattering surface of the target, the output 11.2 is connected to the input 7.1 of the block 7 for calculating the probability of target detection, the input 8.2 for the block 8 for calculating guidance errors, the input 9.2 for the block 9 for calculating the probability of hitting the target, output 11.3 is connected to input 12.1 of the block 12 for calculating the target's vulnerability.

Block 12 calculation of the vulnerability of the target is designed to calculate the angle of approach of the missile to the goal. Input 12.2 of block 12 for calculating the vulnerability of a target is connected to output 9.5 of block 9 for calculating the probability of hitting a target. The output of the block 12 for calculating the vulnerability of the target is connected to the input 2.4 of the logical inference machine 2.

Blocks 1-12 can be made in the form of software and hardware modules on a PC expansion board with an X86-type architecture installed at the workplace (stand) to evaluate the effectiveness of an anti-aircraft missile system.

The device for evaluating the effectiveness of the anti-aircraft missile system operates as follows.

At the preliminary stage, the working memory 3 loads data on tactical and technical characteristics of anti-aircraft missile systems, flight paths of targets, diagrams of inverse reflection of targets, composition, characteristics of vulnerability of the initial compartments and logical patterns of target vulnerability. The knowledge base 1 loads the rules for calculating the effective dispersion surface depending on the angle of target location, the composition of the initial compartments and the logic of target vulnerability depending on the sections of its flight trajectory, the rules for calculating target vulnerability depending on the angle of approach to the target.

After the preliminary stage is completed, the user, using the user interface 5, selects an anti-aircraft missile system, an air attack tool (target) to evaluate its effectiveness, an object of impact, their placement on a digital terrain map, and launch calculations. In the process of modeling, the user can observe the simulated processes of the anti-aircraft missile complex and the flight of targets, after completing the evaluation of the calculation results. After launching the simulation, the trajectory characteristics of the target are calculated by means of logic machine 2 and the initial data on the initial position of the target is calculated and the position is calculated the center of mass of the target relative to the radar detection and targeting in a spherical coordinate system, the coordinates of which and 11.2 is fed to input 7.1 of the block 7 for calculating the probability of target detection, in which the verification of the location of the center of mass of the target in the beam of the antenna pattern of the detection radar and target indications is performed. When the center of mass of the target hits the DND beam, the angle of target location is calculated in block 10 for calculating the effective target scattering surface, for which the input of block 10 from output 11.1 of block 11 receives the coordinates of the current position of the center of mass of the target, and then to input 7.2 of block 7 for calculating the probability target detection using logic inference machine 2 in accordance with the rules for calculating the effective target scattering surface depending on the angle of location, in knowledge base 1, and data on target back-reflection diagrams that are in eyes, memory 3, to the input of 7.2 unit 7 calculating the probability of detection of the target current value fed effective target surface, by which the calculation of the detection probability and target track ties, whereupon the target coordinates are transmitted to the input of 8.1 unit 8 for calculating ZUR pointing errors. If the center of mass of the target does not enter the antenna's DND beam, the next position of the center of mass of the target is calculated in block 11 for calculating the trajectory characteristics of the target and the detection cycle is repeated.

In block 8 of the calculation of errors in the ZUR guidance, the calculation of the probability of detecting and taking on target tracking is carried out according to target indications, similarly to the algorithm implemented in block 7 of calculating the probability of target detection. After successfully solving the problem of detecting and taking on target tracking, launching and pointing the missile defense to the target and calculating guidance errors are performed, for which the input 8.2 from the output 11.2 of block 11 receives the coordinates of the current position of the center of mass of the target and the input 8.3 the current values of the effective target scattering surface . The calculated values of guidance errors are fed to the input 9.1 of the block 9 for calculating the probability of hitting the target.

In block 9 of calculating the probability of hitting a target, the probability of detecting a target is calculated similarly to the algorithm implemented in block 7 of calculating the probability of target detection, the homing head of the missile defense, the calculation of the likelihood of the proximity fuse triggering, taking into account the missile targeting errors, for which input 9.2 from output 11.2 of block 11 Coordinates of the current position of the center of mass of the target are received, and input 9.3 contains the current values of the effective scattering surface of the target. When triggered proximity fuse from the output of 9.5 to the input 12.2 of the block 12 for calculating the vulnerability of the target, the coordinates and the speed of the missiles are received.

In block 12 of calculating the characteristics of the target’s vulnerability, the angles of the approach to the target are calculated, for which the input coordinates 12.1 from the output 11.3 of the block 11 for calculating the trajectory characteristics of the target receive the current center of mass coordinates and the target velocity. Then, by means of logical inference machine 2 in accordance with the rules for calculating the vulnerability of the target design depending on the angle of approach of the missile defense system to the target, the composition of the initial compartments and the logical vulnerability of the target depending on the section of its flight path located in knowledge base 1, and data on the composition, characteristics the vulnerability of the initial compartments and the logic of the vulnerability of targets located in working memory 3, input 9.3 of block 9 for calculating the probability of hitting a target receives data on the vulnerability of the target structure, according to which bubbled performed calculation of the probability of hitting the target.

In order to inform the user about the list of rules that were used in the device when calculating the effective dispersion surface and target vulnerability, use explanation block 4. Adjustment of calculation rules is carried out through the knowledge acquisition block 6.

Claims (1)

A device for quantifying the performance indicators of an anti-aircraft missile system for detecting and hitting targets, containing a knowledge base, an inference engine, a working memory, an explanatory unit, a user interface, a knowledge acquisition unit, the knowledge base output and the first working memory output connected to the first and second the inputs of the logic output machine, the third input of the logic output machine is connected to the second output of the knowledge acquisition unit, the first and second outputs of the logic output machine are connected to the knowledge base and the working memory input, the third output of the logic output machine is connected to the first input of the explanation block, the output of the explanation block and the first output of the knowledge acquisition block are connected to the first and second inputs of the user interface, the first and second outputs of the user interface are connected to the second input of the explanation block and the input of the knowledge acquisition unit, the third input and the third output of the user interface are the input and output of the device for evaluating the effectiveness of the anti-aircraft missile system, from characterized in that it additionally contains a block for calculating the probability of detecting a target, a block for calculating errors of the missile defense, a block for calculating the probability of hitting the target, a block for calculating the effective target scattering surface, a block for calculating the trajectory characteristics of the target, a block for calculating the target’s vulnerability with the second input of the block for calculating the probability of detecting a target, the third input of the block for calculating errors of the missile defense system, the third input of the block for calculating the probability of hitting the target, the input for the calculation block and the trajectory characteristics of the target, the fourth input of the logic output machine is connected to the output of the target vulnerability calculation unit, the fifth input is connected to the output of the effective target dispersion surface calculation unit, the output and the third input of the target detection probability calculation unit are connected to the first input and the first output of the pointing error calculation unit The missile defense system, the second output and the fourth input of the error calculation module of the missile warning system are connected to the first input and the first output of the probability calculation module to hit the target; the second output of the probability calculation module target hit is connected to the second input of the target vulnerability calculation unit, the first input of the target vulnerability calculation block is connected to the third output of the target trajectory characteristics calculation block, the first output of the target trajectory characteristics calculation block is connected to the input of the effective target scatter surface calculation block, the second output is connected to the first input the unit for calculating the probability of detecting a target, the second input of the unit for calculating errors of the missile guidance, the second input of the unit for calculating the probability of hitting the target

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