JPH0562877U - Subsystem control evaluation device - Google Patents

Abstract

(57) [Summary] [Objective] To obtain a subsystem control evaluation device for evaluating the control method of the radio wave radiation subsystem and the sound wave radiation subsystem in various war situations. [Configuration] A data input / output unit 1, an environment simulation unit 2, an event generation unit 3, a pseudo target generation unit 4, a coverage evaluation unit 5, a detection simulation unit 6, a subsystem control unit 7, a subsystem control status display unit 8, It is composed of a radio wave radiation subsystem simulation unit 20 and a sound wave radiation subsystem simulation unit 21. [Effect] By properly setting the data, it is possible to evaluate the control of the radio wave radiating subsystem and the sonic wave radiating subsystem according to various war situations, so it is possible to evaluate the control method of the subsystem studied variously. it can.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention simulates the control of the subsystem that performs radio wave radiation in various tactical environments, simulates the control method of the subsystem that performs acoustic wave radiation, and displays the results to efficiently perform the evaluation. The present invention relates to a device that makes it possible.

[0002]

[Prior Art]

 Conventionally, as shown in the thinking process in Fig. 2, humans make judgments based on the rules related to subsystem control from the environmental conditions and target information displayed on a display device such as a console, and the console. Controlling the subsystem that radiates radio waves and the subsystem that radiates sound waves was performed by operations such as.

[0003]

[Problems to be solved by the device]

 As shown above, conventionally, there is no specially developed device for controlling the subsystem, and therefore, there is no device for evaluating the method, and it is evaluated when developing the control method for the subsystem. There was nothing.

The present invention has been made in order to solve such a problem, and simulates various battle situations and displays the control results for responding to them to evaluate the comprehensive control method of the subsystem. It makes it possible to do.

[0005]

[Means for Solving the Problems]

 The subsystem control evaluation device according to the present invention, as shown in FIG. 2, evaluates the coverage area of the subsystem that generates a pseudo target, simulates the atmospheric environment, generates an event, and radiates radio waves. It simulates target detection, controls the subsystem that radiates radio waves, and displays the results.

In addition, the underwater environment is simulated, the coverage area of the subsystem that emits sound waves is evaluated, and the subsystem that emits sound waves is controlled.

[0007]

[Action]

 With this device, it becomes possible to simulate the control of subsystems according to various war situations, and it becomes possible to make a comprehensive evaluation of the control of radio wave radiation subsystems and acoustic wave radiation subsystems.

[0008]

【Example】

 FIG. 1 is a block diagram showing a subsystem control evaluation device according to the present invention, which includes a data input / output unit 1, an environment simulation unit 2 for simulating atmospheric and underwater environments, an event for generating an event such as target generation, communication satellite passage, etc. Generation unit 3, pseudo target generation unit 4 that creates specifications of pseudo target, coverage evaluation unit 5 that calculates coverage of the radio wave radiating subsystem and sonic radiation subsystem, and determines whether the pseudo target has been detected Target detection simulation unit 6, subsystem control unit 7 that calculates subsystem control data, subsystem control status display unit 8 that displays the control status of the subsystem, radio emission subsystem that creates the specifications of the radio emission subsystem. The simulation unit 20 includes a sonic radiating subsystem simulating unit 21 that creates specifications of the sonic radiating subsystem.

In the subsystem control evaluation device configured as described above, the subsystem control is evaluated by operating as follows. The scenario data 12, the environment data 9, the simulated target data 18, the radio wave radiation subsystem data 22, and the sound wave radiation subsystem data 24 which are arbitrarily set in the data input / output unit 1 are the event generation unit 3 and the environment simulation unit, respectively. 2, the pseudo target generator 4, the radio wave radiation subsystem 20, and the sound wave radiation subsystem 21. When the event generator 3 inputs the scenario data 9 from the data input / output unit 1, the pseudo target generator 4 receives scenarios such as target types, target generation patterns, target motion specifications, and ship motion specifications. Target generation control data 13 indicating data is transmitted, and event data 17 such as passage of a communication satellite is transmitted to the subsystem control unit. When the target generation control data 13 is input from the event generation unit 3, the pseudo target generation unit 4 generates a target based on the specifications and sends the pseudo target data 14 to the target detection simulation unit 6. When the environment data 12 is input from the data input / output unit 1, the environment simulation unit 2 creates environment data based on the specifications and sends the environment specification data 10 to the coverage evaluation unit 5. The coverage evaluation unit 5 inputs the environmental specification data 10 from the environment simulation unit 2, the radio emission subsystem specification data 19 from the radio wave emission subsystem simulation unit 20, and the sound wave emission subsystem simulation unit 21. The acoustic radiation subsystem specification data 23 is input, the detectable regions of the electromagnetic radiation subsystem and the acoustic radiation subsystem are calculated, and the coverage data 11 is transmitted to the target detection simulation unit 6. The radio wave radiating subsystem simulation unit 20 receives the radio wave radiating subsystem data 22 from the data input / output unit 1, sets the specifications of the radio wave radiating subsystem based on the data, and covers the radio wave radiating subsystem specification data 19. It transmits to the evaluation unit 5. When the acoustic wave emission subsystem simulation unit 21 receives the acoustic wave emission subsystem data 24 from the data input / output unit 1, it sets the specifications of the acoustic wave emission subsystem based on the data, and covers the acoustic wave emission subsystem data 23. It is transmitted to the area evaluation unit 5. The target detection simulation unit 6 inputs the pseudo target data 14 from the pseudo target generation unit 4, the coverage data 11 from the coverage evaluation unit 5, and the subsystem control data 16 from the subsystem control unit 7. Then, it is determined whether or not the simulated target is detected, and if detected, the target detection data 15 is transmitted to the subsystem control unit 7. The subsystem control unit 7 inputs the event data 17 from the event generation unit 3, the target detection data 15 from the target detection simulation unit 6, and the radio emission subsystem subsystem data from the radio emission subsystem simulation unit 20. 19 is input, and the acoustic wave emission subsystem specification data 23 is input from the acoustic wave emission subsystem simulation unit 21 to compare / verify various current battle situations with database-based radio wave and acoustic wave emission rules, etc. The optimum subsystem control is determined, and the control data 16 is transmitted to the target detection simulation section 6 and the subsystem control status display section 8. The subsystem control status display section 8 inputs the control data 16 from the subsystem control section 7 and displays the control status of each subsystem.

[0010]

[Effect of the device]

 As described above, the present invention makes it possible to evaluate the control of the radio wave radiating subsystem and the sonic wave radiating subsystem according to various war situations by appropriately setting the data. The control method can be evaluated.

[Brief description of drawings]

FIG. 1 is a diagram showing an embodiment of the present invention.

FIG. 2 is a diagram showing a thinking process in the case of performing conventional subsystem control.

[Explanation of symbols]

 1 Data Input Section 2 Environment Simulation Section 3 Event Generation Section 4 Pseudo Target Generation Section 5 Coverage Evaluation Section 6 Target Detection Simulation Section 7 Subsystem Control Section 8 Subsystem Control Status Display Section 9 Environmental Data 10 Environmental Specifications Data 11 Coverage Area Data 12 Scenario data 13 Target generation control data 14 Pseudo target data 15 Target detection data 16 Control data 17 Event data 18 Pseudo target data 19 Radio wave radiating subsystem specification data 20 Radio wave radiating subsystem simulation unit 21 Sonic radiation subsystem simulating unit 22 Radio emission subsystem data 23 Sonic emission subsystem specifications data 24 Sonic emission subsystem data 25 START 26 Display of environmental conditions 27 Reference of radio / sonic emission subsystem usage rules 28 Control operation 29 END

Claims (1)

[Scope of utility model registration request] 1. A pseudo target generation unit that generates a plurality of targets at arbitrary times based on an arbitrarily set scenario, an environment simulation unit that arbitrarily sets the atmospheric environment, and an event generation unit that arbitrarily generates an event. , The coverage area evaluation unit that calculates the detectable distance under the environmental conditions set by the environment simulation unit based on the specifications of the radar set arbitrarily, the radar detection data and the radio wave from the target data generated by the pseudo target generation unit. Target detection simulation unit that sets detection data, simulated event generated by the event generation unit, radar detection data generated by the target detection simulation unit, and subsystem control that generates optimal subsystem control data from radio wave detection data And how each subsystem is controlled based on the subsystem control data generated by the subsystem and subsystem control section Subsystem control that is composed of a subsystem control status display unit that displays whether or not, and is capable of evaluating the optimal control method for the subsystem that radiates radio waves including radar and radio wave jamming devices according to the situation such as an event. Evaluation device.