JP6653392B2 - Shooting training system - Google Patents

Description

  The present invention relates to a shooting training system that performs shooting training using live ammunition.

  A shooting training system that performs shooting training using conventional live ammunition, for example, a trainee fires at a target using a firearm, and when a bullet hits the target, it detects vibration of the target and detects the target May fall down, or a sensor may be used to detect a shock wave or the like due to a bullet passing to detect a hit position (coordinates) and display the hit position on a target on a display.

  For example, Patent Literature 1 includes a target device 1 and a target control device 30. The target device 1 includes an area detection sensor unit 220 that detects an impact in a predetermined range wider than a target. The target control device 30 includes: An impact position calculating unit 312 for calculating the impact coordinates and area within a predetermined range from the value of the area detection sensor unit 220, and the impact coordinates corresponding to the order of impact are displayed in the coordinates corresponding to the area 410 of the display field 710. There is disclosed a shooting training system that includes an impact rendering unit 313 that displays the image in a mark format and displays the impact direction outside the screen display range.

  Further, in Patent Document 2, in a shooting training system including a target device and a target control device, the target device includes a sensor that detects an impact in a predetermined range wider than the target, and the target control device determines a value based on the value of the sensor. An impact position calculating means for calculating an impact coordinate and an area within a predetermined range, a list of the impact coordinates in the order of impact, and a mark format display within the coordinates of the predetermined range corresponding to the area of the impact coordinates. Refers to a scoring table in which scores and display colors are set according to the type of target and the level of the trainee, and displays the background color and mark of the list in a predetermined display color in accordance with the landing coordinates. Means, and a shooting training system is disclosed.

JP 2013-174425 A JP 2014-126257 A

  In the shooting training systems of Patent Literatures 1 and 2, when a bullet is fired toward a target of a target device, the bullet passes through a detection range of a sensor provided in the target device, so that the sensor passes the bullet through the position (coordinates). ), The target device communicates with the target control device, and the bullet passage position information is transmitted to the target control device. Based on the bullet passage position information, the target control device determines whether the bullet hits or hits the target. The location where the vehicle passed outside the vicinity was displayed on the display.

  However, in the above-mentioned conventional shooting training system using live ammunition, for example, when a plurality of trainees participate in training at the same time, there is no problem if the trainers perform shooting training one by one in order. If multiple trainees fire at random, each of the trainees will individually determine which bullets they fired at and where they fired (hit) on the target. It was difficult to do.

  The present invention has been made in view of such a situation, when a plurality of trainees participate and shoot at random, who shoots at which target, when, by the shooting, by the shooting, By judging whether the bullet hits (hits) the target and displaying the result of the shooting in real time on a display that can be visually recognized by the trainee, the trainee can immediately confirm the shooting result of the trainee. Therefore, an object of the present invention is to provide a shooting training system capable of improving the shooting training accuracy and improving the efficiency of shooting training.

  In order to achieve the above object, a shooting training system of the present invention includes a shooting device equipped with at least one trainer performing shooting training using a firearm, at least one target device provided with a target, and a shooting device. A control device for analyzing a result of the training, wherein the shooting device and the control device, and the target device and the control device are each a shooting training system connected to each other by a communication line. The shooting device may further include a bullet firing detection unit configured to detect a bullet firing from the firearm, a position detection unit configured to detect a three-dimensional position coordinate of the firearm, bullet firing information and a bullet detected by the bullet firing detection unit. Launch time information, and a firearm position information detected by the position detection unit, with an identification code of the shooting device, and a control unit that transmits to the control device, the target device, An area detection sensor unit that has a detection area disposed in front of the target between the trainee and the target, and detects a two-dimensional position coordinate of a bullet passing point in the detection area; A position detection unit that detects three-dimensional position coordinates, and two-dimensional position coordinates of the bullet passing point in the area detection sensor unit and three-dimensional position coordinates of the bullet passing point based on the three-dimensional position coordinates of the target device. And a control unit for calculating and adding the bullet passing point coordinate information and the bullet passing time information, and the target device position information to the control device with the identification code of the target device attached thereto, and transmitting the control device to the control device. A control unit having a trainee determination unit that determines a trainee who has fired based on bullet firing time information obtained from the shooting device and bullet passage time information obtained from the target device. And it features.

  In order to achieve the above object, in the shooting training system of the present invention, in the above-described shooting training system, the area detection sensor unit of the target device is disposed with a predetermined gap in front of the target. An area detection sensor unit having two detection areas and detecting two-dimensional position coordinates of a bullet passing point at two locations, wherein the control unit of the target device detects the two locations detected by the area detection sensor unit. The control unit calculates a bullet approach angle based on the two-dimensional position coordinates of the bullet passing point in the detection area and the numerical value of the predetermined gap, and transmits the bullet approach angle information to the control device. The trainee determination means is, before the bullet passing time acquired from the target device, and, if there is a plurality of shooting devices that fired within a predetermined time, the firearm position of the plurality of shooting devices Based on the information and the bullet passing point coordinate information, calculate the approach angle of each firearm with respect to the bullet passing point of each firearm, compare with the bullet approach angle information obtained from the target device, and determine the trainee who fired. It is a trainee determination means for determination.

  In order to achieve the above object, in the shooting training system of the present invention, in the above-mentioned shooting training system, the control device is configured such that, in the detection area of the area detection sensor unit of the target device, Based on a target impact area coordinate table in which two-dimensional position coordinates in a corresponding range are registered, and shooting device information obtained from the shooting device and bullet passage information obtained from the target device, based on the determination result by the trainee determining means. A training result registration table in which training result information is registered, and the control unit of the control device refers to the target impact area coordinate table of the storage unit and obtains from the target device. A target impact determination that determines whether a bullet has impacted the target based on the two-dimensional position coordinates of the bullet passing point in the detection area close to the target Based on the training result information of the training result registration table and the coordinate data of the target impact area coordinate table, shooting result drawing data including a diagram showing detailed training contents and a bullet passing position with respect to the target is created. And transmitting the shooting result drawing data to a shooting device equipped by the trainee specified by the trainee determining means.

  Further, in order to achieve the above object, the shooting training system of the present invention includes a shooting device equipped with at least one trainer who performs shooting training using a firearm, and at least one target device provided with a target. And a control device for analyzing the result of shooting training, a shooting training system connected between the shooting device and the control device, and between the target device and the control device by a communication line. The shooting device, a bullet firing detection unit that detects a bullet firing from the firearm, and based on a bullet firing signal from the bullet firing detection unit, toward the target device, the shooting device of the shooting device An identification code, firearms information, trainee information, a laser transmission unit that transmits laser light including shooting information of the shooting time, and the target device, between the trainee and the target, the target An area detection sensor unit having a detection area arranged on the front side and detecting two-dimensional position coordinates of a bullet passing point in the detection area; and a laser light transmitted from the shooting device, and a shot included in the laser light. A predetermined two-dimensional position is obtained from a laser receiving unit that outputs information, a storage unit having a shooting result registration table for registering shooting result information, and two-dimensional position coordinates of a bullet passing point obtained from the area detection sensor unit. Having a bullet passing coordinate calculating means for calculating coordinates, storing the predetermined two-dimensional position coordinates of the bullet passing point calculated by the bullet passing coordinate calculating means in the shooting result registration table in association with the bullet passing time, Further, the shooting information acquired from the laser receiving unit is stored in the shooting result registration table, and the shooting result information is read from the shooting result registration table. A control unit for attaching the identification code of the target device and transmitting the control device to the control device, wherein the control device refers to the shooting result information acquired from the target device, and determines the trainee who performed the shooting. A control unit having a trainee determining means for performing the training.

  In order to achieve the above object, in the shooting training system of the present invention, in the above-mentioned shooting training system, the control device is configured such that, in the detection area of the area detection sensor unit of the target device, The control unit of the control device includes a storage unit having a target impact area coordinate table in which two-dimensional position coordinates in a corresponding range are registered, and a training result registration table for registering training result information. Means for registering the shooting result information obtained from the target device in the training result registration table in association with the identification code of the target device, and referring to the target hitting area coordinate table in the storage unit and obtaining from the target device. Target hit determination means for determining whether or not a bullet has hit the target based on the two-dimensional position coordinates of the bullet passing point included in the shooting result information. Based on the training result information in the training result registration table and the coordinate data in the target hitting area coordinate table, shooting result drawing that creates shooting result drawing data including a diagram showing details of training and a bullet passing position with respect to the target And transmitting the shooting result drawing data to a shooting device equipped by the trainee identified by the trainee determination means.

  According to the present invention, when a plurality of trainees participate and shoot randomly, who shoots at which target, and when the bullet hits (hits) the target by the shooting By judging whether or not the result of the shooting is displayed in real time on a display that can be visually recognized by the trainee, the trainee can immediately confirm his own shooting result, so that the training accuracy of shooting can be improved. Thus, the efficiency of shooting training can be improved.

1 is a system configuration diagram of a shooting training system according to a first embodiment of the present invention. FIG. 2 is a diagram illustrating a positional relationship between a firearm possessed by a trainee and a target device when the shooting training system of FIG. 1 is viewed from above. FIG. 2 is a block diagram illustrating a control configuration of the shooting device according to the first embodiment of the present invention. It is a figure showing an example of a shooting information registration table of a shooting device. FIG. 2 is a block diagram illustrating a control configuration of the target device according to the first embodiment of the present invention. FIG. 1 is a schematic diagram illustrating an example of a target device according to a first embodiment of the present invention. It is a figure for explaining an impact area of an area detection sensor part of a target device. It is a figure showing an example of a bullet passage information registration table of a target device. FIG. 3 is a block diagram illustrating a control configuration of the control device according to the first embodiment of the present invention. It is a figure showing an example of a target control directions table of a control device. It is a figure showing an example of a training result registration table of a control device. It is a sequence diagram showing operation of a shooting training system concerning Embodiment 1 of the present invention. It is a figure showing the example of a display screen of a shooting result displayed on a display of a shooting device concerning Embodiment 1 of the present invention. It is a figure showing the example of a list display screen of the shooting result displayed on the display of the control device concerning Embodiment 1 of the present invention. It is a system configuration diagram of a shooting training system according to a second embodiment of the present invention. It is a block diagram showing a control configuration of a shooting device according to a second embodiment of the present invention. It is a figure which shows an example of the transmission information registration table of a shooting device. It is a block diagram showing a control configuration of a target device according to a second embodiment of the present invention. It is an outline view showing an example of a target device concerning Embodiment 2 of the present invention. It is a figure showing an example of a shooting device information registration table of a target device. It is a figure showing an example of a shooting result registration table of a target device. It is a block diagram showing a control configuration of a control device according to a second embodiment of the present invention. It is a figure showing an example of a training result information registration table of a control device. It is a sequence diagram showing operation of the shooting training system concerning Embodiment 2 of the present invention.

Embodiment 1 Hereinafter, a shooting training system according to Embodiment 1 of the present invention will be described.
In the shooting training system according to the first embodiment of the present invention, when a plurality of trainees participate and perform shooting at random, who shoots at which target, and when the shooting is performed, a bullet is applied to the target by the shooting. By judging whether or not a shot (hit) has been made and displaying the result of the shooting in real time on a display that can be visually recognized by the trainee, the trainee can immediately confirm his own shooting result. The training accuracy can be improved, and the efficiency of shooting training can be improved.

[Configuration of shooting training system]
The configuration of the shooting training system S according to the first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a system configuration diagram of the shooting training system according to the first embodiment of the present invention. FIG. 2 is a diagram showing a positional relationship between a firearm possessed by a trainee and a target device when the shooting training system of FIG. 1 is viewed from above.
As shown in FIG. 1, the shooting training system S according to the first embodiment of the present invention is equipped with the trainees 80-1 and 80-2 and the trainees 80-1 and 80-2, each of which performs shooting in shooting training. And the target devices 20-1, 20-2 and the control device 10. As shown in FIG. 1 and FIG. 2, the shooting training system S is configured such that the trainee 80-1 or the trainee 80-2 sets the target 24a-1 of the target device 20-1 or the target 24a-2 of the target device 20-2. Fire at random. In this embodiment, first, the trainee 80-1 fires at the target 24a-1 as indicated by the trajectory R1, and then the trainee 80-2 moves the target 24a-2 at the trajectory R2. It is assumed that the trainee 80-2 and the trainee 80-1 have performed the shooting indicated by the trajectory R3 and the trajectory R4. In addition, when the trainees 80-1 and 80-2 are not distinguished from each other, when the trainee 80 is not distinguished from the shooting devices 30-1 and 30-2, simply the shooting device 30 and the target device 20- When there is no need to distinguish between 1, 20-2, the target device 20 is simply referred to.
The shooting device 30 and the control device 10 and the target device 20 and the control device 10 are connected to each other by, for example, wireless communication.
In FIG. 1, the shooting device 30 and the target device 20 are each configured as two units. However, one or three or more shooting devices 30 or the target devices 20 are connected to one control device 10 by signal connection. It is also possible to configure so that

The shooting device 30 is equipped and used by the trainee 80 when performing shooting training.
The target device 20 is a target device for shooting training using live ammunition. The target device 20 causes the target 24a to perform a concealing operation in accordance with schedule information created in advance or an instruction from the control device 10. The target 24a is a detachable target main body that is driven and controlled by the control unit 21, and is a target of shooting training. The area detection sensor unit 25 detects a value related to the two-dimensional position coordinates (XY coordinates) of the bullet passing point. The detection area 400 is a range in which the area detection sensor unit 25 can detect the two-dimensional position coordinates of the bullet passing point. Details of the detection area 400 and other areas will be described later.

  The control device 10 is a controller of the target device 20 that displays a control instruction to the target device 20, a display of an operation state, a result of landing on the target 24a, and the like. Further, the control device 10 acquires the operation state and the bullet passage information from the target device 20. In addition, the control device 10 uses the two-dimensional and three-dimensional position coordinates and the bullet passage time of the bullet passage point acquired from the target device 20 and the bullet passage information such as the bullet entry angle to control the target device 20 and the bullet. The display method of the arrival result can be improved. Further, the control device 10 performs shooting based on shooting information and firearm position information such as bullet firing and bullet firing time obtained from the shooting device 30 and bullet passage information and target device position information obtained from the target device 20. The trainee who performed the training is determined, and the training result information is transmitted to the shooting device 30 equipped by the trainee who performed the shooting.

[Control configuration of shooting device]
Next, a control configuration of the shooting device 30 of the shooting training system S according to the first embodiment of the present invention will be described in detail with reference to FIG. FIG. 3 is a block diagram illustrating a control configuration of the shooting device according to the first embodiment of the present invention.
As shown in FIG. 3, the shooting device 30 includes a control unit 31, a storage unit 32, a communication unit 33, a firearm 34, a position detection unit 35, a bullet firing detection unit 36, a display unit 37, a power supply And a unit 38. The control unit 31 is signal-connected to the storage unit 32, the communication unit 33, the position detection unit 35, the bullet emission detection unit 36, the display unit 37, the power supply unit 38, and other components constituting the shooting device 30 to configure the shooting device 30. Each part and the entire shooting device 30 are controlled.
The firearm 34 is, for example, a rifle carried by a trainee 80 performing shooting training and operated by the trainee 80 to fire a live ammunition such as a bullet.
The position detector 35 is attached to the firearm 34, and uses GPS (Global Positioning System) or the like, and three-dimensional position coordinate data of latitude, longitude, and altitude at the firearm position points PF1, PF2 (see FIG. 2) of the firearm 34. Are sequentially obtained and transmitted to the control unit 31.

The bullet firing detection unit 36 is a vibration sensor that is attached to the firearm 34 and, when the trainee 80 fires a bullet from the firearm 34, detects the vibration of the firearm 34 and detects the firing of the bullet. When detecting the vibration of the firearm 34, the bullet firing detection unit 36 transmits a bullet firing signal to the control unit 31 based on the detected vibration data. The bullet firing detection unit 36 may be, for example, a shock wave sensor that detects a shock wave due to bullet passage and transmits a bullet firing signal to the control unit 31 based on the detected shock wave.
The display unit 37 is a monitor carried by the trainee 80 and for displaying the training result information for the target 24a by the bullets fired from the firearm 34 owned by the trainee and transmitted from the control device 10.

The control unit 31 has a clock function, sequentially receives firearm position coordinate data from the position detection unit 35, and associates the received firearm position coordinate data with the time information at the time of reception, and stores the firearm position information in the storage unit 32. It is stored in the table 32a. Further, the control unit 31 receives the bullet firing signal from the bullet firing detection unit 36 and associates the data related to the shooting with the time information at the time of receiving (that is, the shooting time information), It is stored in the registration table 32b.
The control unit 31 sequentially reads out the firearm position information from the firearm position information table 32a of the storage unit 32, attaches an identification code for identifying the shooting device 30, and transmits the information to the control device 10 via the communication unit 33. . Further, the control unit 31 reads out the shooting information from the shooting information registration table 32b of the storage unit 32, attaches an identification code for identifying the shooting device 30, and transmits the same to the control device 10 via the communication unit 33. .

The storage unit 32 includes a firearm position information table 32a and a shooting information registration table 32b. The storage unit 32 stores the firearm position coordinate data acquired from the position detection unit 35 together with the time information in the firearm position information table 32a according to an instruction from the control unit 31. Further, the storage unit 32 stores the data relating to the shooting and the shooting time information in the shooting information registration table 32b in association with the shooting data based on the bullet firing signal acquired from the bullet firing detecting unit 36 in accordance with an instruction from the control unit 31. . Here, the shooting information registration table 32b of the storage unit 32 will be described in detail. FIG. 4 is a diagram illustrating an example of a shooting information registration table of the shooting device. The shooting information registration table 32b includes a shooting code for identifying a shooting action, a firearm code for identifying a firearm 34 used for shooting, a trainer code for identifying a trainee 80 who fired, and a bullet from the firearm 34. And the shooting time indicating the time at which the is fired.
The communication unit 33 performs wireless communication with the communication unit 13 of the control device 10 via the antenna 33a.
The power supply unit 38 supplies power to each unit constituting the shooting device 30.

[Control configuration of target device]
Next, a control configuration of the target device 20 of the shooting training system S according to the first embodiment of the present invention will be described in detail with reference to FIGS. FIG. 5 is a block diagram illustrating a control configuration of the target device according to the first embodiment of the present invention. FIG. 6 is a schematic diagram illustrating an example of the target device according to the first embodiment of the present invention. FIG. 7 is a diagram for explaining an impact area of the area detection sensor unit of the target device.
As shown in FIG. 5, the target device 20 includes a control unit 21, a storage unit 22, a communication unit 23, a target driving unit 24 connected to the target 24a, an area detection sensor unit 25, and a position detection unit 26. , A presenting unit 27, a truck driving unit 28 connected to the truck 28 a, and a power supply unit 29. The control unit 21 includes the storage unit 22, the communication unit 23, the target drive unit 24, the area detection sensor unit 25, the position detection unit 26, the display unit 27, the bogie drive unit 28, and the power supply unit 29. , And controls each unit constituting the target device 20 and the entire target device 20.
The target device 20 can perform autonomous control by the built-in control unit 21, wireless or wired program control from the control device 10, or manual control by an operator (not shown).

The target driving unit 24 is a part including a motor, an encoder, an electromagnetic actuator, and the like for driving the target 24a. The target drive unit 24 is configured to be able to detach and replace the target 24a. The target drive unit 24 performs various expressions corresponding to the body motion of the enemy (trainer 80) using the connection unit, the motor, and the like. As shown in FIG. 6, the target drive unit 24 responds to an instruction from the control unit 21 according to, for example, position coordinate information of the firearm 34 or bullet passage information from the area detection sensor unit 25 described below. An operation such as lifting, rotating, standing, or falling is performed.
The area detection sensor unit 25 arranges two detection areas 400 side by side with a predetermined interval h1 (for example, 20 cm, see FIG. 2) in front of the target 24a to be driven, and fires from the firearm 34 carried by the trainee 80. The value relating to the two-dimensional position coordinates (XY coordinates) of the bullet passing point detected is detected at two places, and data relating to the bullet passing is transmitted to the control unit 21. The area detection sensor unit 25 detects a bullet passage in a predetermined range (detection area 400 in FIG. 7) wider than the target 24a. Therefore, even when the bullet does not land on the target 24a, a value relating to the two-dimensional position coordinates (XY coordinates) of the bullet passing point can be obtained. In the case of an actual ammunition, the area detection sensor unit 25 may use a sensor that detects a shock wave, an ultrasonic sensor, or the like, as a means for detecting bullet passage. As will be described later, the control unit 21 performs control based on a value relating to the two-dimensional position coordinates (XY coordinates) of the bullet passing points in the two detection areas 400 detected by the area detection sensor unit 25 and a predetermined interval h1. The bullet approach angle calculating means 21b calculates the approach angle of the bullet.
The position detection unit 26 sequentially obtains three-dimensional position coordinate data of the latitude, longitude, and altitude of the target position points PT1, PT2 (see FIG. 2) of the target device 20 using GPS or the like, and transmits the coordinate data to the control unit 21. .

The control unit 21 includes a bullet passage coordinate calculation unit 21a and a bullet entry angle calculation unit 21b. The bullet passing coordinate calculating means 21a calculates the bullet passing point (for example, the bullet in FIG. 2) from the target device position information acquired from the position detecting section 26 and the value related to the two-dimensional position coordinates of the bullet passing point acquired from the area detecting sensor section 25. Predetermined two-dimensional position coordinates (XY coordinates) and three-dimensional position coordinates at the passing points PS1-1 and PS1-2) are calculated, and are associated with time information at the time of reception (that is, bullet passing time), and are associated with bullets. The information is registered in the passage information registration table 22b. The bullet entry angle calculation unit 21b calculates the three-dimensional position coordinates of the two bullet passage points (for example, the bullet passage points PS1-1 and PS1-2 in FIG. 2) calculated by the bullet passage coordinate calculation unit 21a and a predetermined interval h1. Is calculated on the basis of the above, and registered in the bullet passage information registration table 22b. Further, the control unit 21 sequentially receives the target device position coordinate data from the position detection unit 26, and associates the received target device position coordinate data with the time information at the time of reception, and stores the target device position coordinate data in the storage unit 22. It is stored in the table 22a. Note that the target position points PT1 and PT2 of the target device 20 in FIG. 2 and an XY coordinate position base point 450 serving as a base point of predetermined two-dimensional position coordinates (XY coordinates) of a bullet passing point in the area detection sensor unit 25, which will be described later. Is a preset value.
The control unit 21 sequentially reads out the target device position information from the target device position information table 22a of the storage unit 22 and attaches an identification code for identifying the target device 20 to the control device 10 via the communication unit 23. Send. Further, the control unit 21 reads the bullet passage information from the bullet passage information registration table 22b of the storage unit 22 and attaches an identification code for identifying the target device 20 to the control device 10 via the communication unit 23. Send.

Here, referring to FIG. 7, in the bullet passing coordinate calculating means 21 a of the control unit 21, a predetermined two-dimensional value at the bullet passing point is obtained from the value related to the two-dimensional position coordinates of the bullet passing point acquired from the area detection sensor unit 25. A method for calculating the position coordinates (XY coordinates) will be described. In this example, based on the signal from the area detection sensor unit 25, the control unit 21 sets predetermined left and right X-coordinates and up and down Y-coordinates at predetermined two-dimensional position coordinates of a bullet passage point in a direction directly facing the target 24a ( XY coordinates).
More specifically, the control unit 21 calculates the XY coordinates on the vertical plane from the center of the area detection sensor unit 25. The control unit 21 sets the coordinates of the XY coordinate position base point 450 with respect to the center of the detection range as (X, Y) = (0, 0), and determines the area based on the distance between the X coordinate and the Y coordinate.
Specifically, the control unit 21 can determine an area such as the area 400 to the area 420 from predetermined two-dimensional position coordinates (XY coordinates) of the calculated bullet passing point.
The detection area 400 is, for example, a rectangular area having a length of about 5 m and a width of about 5 m, and indicates a predetermined range that can be detected by the area detection sensor unit 25.
The area 410 is, for example, a square area having a length of about 120 cm and a width of about 120 cm, and shows a target 24a displayed on the display unit 14 of the control device 10 described later and a predetermined range around the target 24a. The area 410 is an area corresponding to the closest bullet.
The area 420 is a target area substantially corresponding to the coordinates of the range of the target 24a. If a bullet passes through this area 420, it will be hit (hit).

When the bullet fired from the firearm 34 of the shooting device 30 hits the target 24a, the presenting unit 27 performs a presenting operation such as smoking, light emission, and sound generation in accordance with an instruction from the control unit 21.
The carriage drive unit 28 is a part that moves the entire target device 20 mounted on the carriage 28a by a predetermined distance in the front-rear or left-right direction using a motor, wheels, and the like in accordance with an instruction from the control unit 21 (FIG. 6). reference). The carriage driving unit 28 may be configured to move on rails and cables (not shown) laid on the front, rear, left, and right.

The storage unit 22 includes a target device position information table 22a and a bullet passage information registration table 22b. The storage unit 22 stores the three-dimensional position coordinate data of the target device 20 acquired from the position detection unit 26 together with the time information in the target device position information table 22a according to an instruction from the control unit 21. The storage unit 22 calculates predetermined two-dimensional position coordinates (XY coordinates), three-dimensional position coordinates, and a bullet entry angle of the bullet passage point calculated by the bullet passage coordinate calculation unit 21a of the control unit 21 according to an instruction from the control unit 21. The bullet entry angle calculated by the means 21b is stored in the bullet passage information registration table 22b together with the bullet passage time. Here, the bullet passage information registration table 22b of the storage unit 22 will be described in detail. FIG. 8 is a diagram illustrating an example of the bullet passage information registration table of the target device. The bullet passage information registration table 22b stores an identification code for identifying bullet passage information and a bullet passage point in the detection area 400 (for example, the detection area 400-1-2 in FIG. 2) close to the target 24a. The passing time indicating the passing time, the three-dimensional position coordinates of the bullet passing point in each of the two detection areas 400 (for example, the detection areas 400-1-1 and 400-1-2 in FIG. 2), and the target 24a The two-dimensional position coordinates of the bullet passing point in the detection area 400 (for example, the detection area 400-1-2 in FIG. 2) approaching the target and the approach angle of the bullet.
The communication unit 23 performs wireless communication with the communication unit 13 of the control device 10 via the antenna 23a.
The power supply unit 29 supplies power to each unit configuring the target device 20.

[Control configuration of control device]
Next, a control configuration of the control device 10 of the shooting training system S according to the first embodiment of the present invention will be described in detail with reference to FIG. FIG. 9 is a block diagram illustrating a control configuration of the control device according to the first embodiment of the present invention.
As shown in FIG. 9, the control device 10 includes a control unit 11, a storage unit 12, a communication unit 13, a display unit 14, an input unit 15, and a power supply unit 16. The control unit 11 is signal-connected to each unit of the control device 10 such as the storage unit 12, the communication unit 13, the display unit 14, the input unit 15, and the power supply unit 16, and controls each unit of the control device 10 and the entire control device 10. Control.

The control unit 11 is a CPU, a GPU, a DSP, or the like, and executes a program or the like stored in the storage unit 12 using hardware resources. The control unit 11 issues an instruction to the target device 20 and controls to display various data on the display unit 14. The control unit 11 sequentially obtains the firearm position information from the shooting device 30 and stores the obtained firearm position information in the firearm position registration table 124 of the storage unit 12 in association with the identification code of the shooting device 30. The control unit 11 acquires the shooting information from the shooting device 30 and stores the obtained shooting information in the shooting training DB 121 of the storage unit 12 in association with the identification code of the shooting device 30. Further, the control unit 11 sequentially acquires the target device position information from the target device 20 and stores the acquired target device position information in the target device position registration table 125 of the storage unit 12 in association with the identification code of the target device 20. . Further, the control unit 11 acquires bullet passage information from the target device 20 and stores the acquired bullet passage information in the shooting training DB 121 of the storage unit 12 in association with the identification code of the target device 20. Further, the control unit 11 determines the trainee who has fired based on the shooting information and the firearm position information obtained from the shooting device 30 and the bullet passage information and the target device position information obtained from the target device 20. At the same time, the training result information is registered in the training result registration table 126 based on the determination result of the trainee, shooting result drawing data is created based on the training result information, and the shooting device 30 provided by the trainee who fired is equipped. , The shooting result drawing data is transmitted.
The storage unit 12 is a storage unit including a RAM, a ROM, a HDD, a flash memory, and the like. The storage unit 12 stores programs, data, and the like for controlling the target device 20 and analyzing landing. Details of the program and data will be described later. The storage unit 12 also stores a general-purpose OS (Operating System), firmware, and the like.
The display unit 14 is a unit that outputs images / characters of a general-purpose liquid crystal or organic EL display, a projector, an inkjet printer, a laser printer, or the like. The display unit 14 displays and outputs various information including training result information described later.

The input unit 15 is an input unit such as a switch, a keyboard, a mouse, and a touch panel. The input unit 15 can mainly detect an instruction from a manager (user) of the control device 10.
The communication unit 13 performs wireless communication with the communication unit 33 of the shooting device 30 and the communication unit 23 of the target device 20 via the antenna 13a.
The power supply unit 16 supplies power to each unit configuring the control device 10.

  The control unit 11 also includes a target impact determination unit 111, a trainee determination unit 112, a shooting result drawing unit 113, a target operation instruction unit 114, and a present operation instruction unit 115.

  The target impact determination unit 111 refers to the target impact area coordinate table 122 of the storage unit 12 and refers to the two-dimensional bullet passing point of the detection area 400 close to the target 24a included in the bullet passing information acquired from the target device 20. Based on the position coordinates (two-dimensional position coordinates of the detection area 2 in FIG. 8), it is determined whether or not the bullet hits (hits) the target 24a.

The trainee determining means 112 is a trainee (shooting device) that has fired based on the shooting information and the firearm position information obtained from the shooting device 30, and the bullet passage information and the target device position information obtained from the target device 20. Is determined.
Here, a method of determining a trainee by the trainee determination unit 112 of the control unit 11 will be specifically described with reference to FIGS. 1 and 2.
As shown in FIGS. 1 and 2, for example, when the target 24 a-1 of the target device 20-1 is fired by the trajectory R 1, the trainee determination unit 112 first With reference to the shooting training DB 121, a shooting device that fires before the bullet passing time T3 at the bullet passing point PS1-2 acquired from the target device 20-1 and within a predetermined time t1 (for example, 10 seconds). Search for 30. If the number of the shooting devices 30 corresponding to the condition is one (the shooting time T1 of the shooting device 30-1 is (T3-t1) <T1 <T3), the shooting device that performed the shooting is the shooting device. 30-1 and the trainee is determined to be the trainee 80-1 (trainer code A). The time t1 is appropriately set according to the performance of the firearm 34 to be used (the firing speed of the bullet, etc.), the interval of the shooting training, and the like.
However, if the shooting device 30-1 and the shooting device 30-2 satisfy the above temporal conditions, the trainee determination unit 112 determines that the shooting device 30-1 (equipped with the trainee 80-1) and the target Based on the weapon position information, the target device position information, and the bullet passage information acquired from the device 20-1 (M1), the bullet passage point from the weapon position point PF1 (position coordinates (X1, Y1, Z1)) of the firearm 34-1. A horizontal distance L1 in the Z-axis direction to PS1-2 (position coordinates (x3, y3, z3)), and a horizontal distance H1 in the X-axis direction to the firearm position point PF1 and the bullet passing point PS1-2 of the firearm 34-1. Is calculated from L1 and H1, the approach angle θ1 from the firearm position point PF1 of the firearm 34-1 to the bullet passage point PS1-2. Similarly, based on the firearm position information, the target device position information, and the bullet passage information acquired from the shooting device 30-2 (equipped by the trainee 80-2) and the target device 20-1 (M1), the firearm 34- 2 and the horizontal distance L2 in the Z-axis direction from the weapon position point PF2 (position coordinates (X3, Y3, Z3)) to the bullet passing point PS1-2 (position coordinates (x3, y3, z3)). The horizontal distance H2 in the X-axis direction between the firearm position point PF2 and the bullet passing point PS1-2 is determined, and from L2 and H2, the approach angle θ2 from the weapon position point RF2 of the firearm 34-2 to the bullet passing point PS1-2 is calculated. calculate.
Then, the trainee determination unit 112 calculates the respective approach angles θ1 and θ2 obtained above and the bullet approach angle α1 (see FIG. 8) included in the bullet passage information acquired from the target device 20-1 (M1). In comparison, since the bullet entry angle α1 matches the entry angle θ1 of the firearm 34-1, it is determined that the shooting indicated by the trajectory R1 was performed by the trainee 80-1 equipped with the shooting device 30-1. I do.
In addition, the control unit 11 stores the shooting information and the bullet passage information of the shooting training DB 121 and the target device position information of the target device position registration table 125 based on the determination results by the target impact determination unit 111 and the trainee determination unit 112. The training result information is registered in the training result registration table 126 with reference to the training result registration table 126.

  The shooting result drawing means 113 is based on the training result information in the training result registration table 126 and the coordinate data in the target hitting area coordinate table 122, and includes shooting details including a diagram showing a bullet passing position with respect to the target 24a. Create data. Further, the shooting result drawing means 113 creates shooting result drawing data summarizing the results of the shooting training at the end of the shooting training based on an instruction from the input unit 15 by the administrator.

  The target operation instructing means 114 refers to a target control instruction table 123 described later in the storage unit 12 and issues an operation instruction such as standing up / falling down of the target 24a of the target device 20.

  The presenting operation instructing means 115, when the bullet fired from the firearm 34 of the shooting device 30 hits (hits) the target 24a as a result of the determination by the target hit determination unit 111, The present instruction signal is transmitted.

The storage unit 12 includes a shooting training DB 121, a target impact area coordinate table 122, a target control instruction table 123, a firearm position registration table 124, a target device position registration table 125, and a training result registration table 126. I have.
The shooting training DB 121 is a database such as SQL. The shooting training DB 121 stores the shooting information acquired from the shooting device 30 in association with the identification code of the shooting device 30. In addition, the shooting training DB 121 stores the bullet passage information acquired from the target device 20 in association with the identification code of the target device 20.

The target impact area coordinate table 122 includes two-dimensional position coordinates of the range of the target 24a (the area 420 in FIG. 7) in a predetermined range (the detection area 400 in FIG. 7) that can be detected by the area detection sensor unit 25 of the target device 20. Is a table in which is registered.
The target control instruction table 123 is a table indicating the distance between the trainee 80 and the target device 20 and the control content of the target device 20. FIG. 10 is a diagram illustrating an example of a target control instruction table of the control device. The target control instruction table 123 includes a target device identification ID for identifying the target device 20, a distance between a trainee (shooting device) and the target device, and control contents according to the distance.

The firearm position registration table 124 stores the firearm position information sequentially transmitted from the shooting device 30 in accordance with an instruction from the control unit 11 in association with the identification code of the shooting device 30.
The target device position registration table 125 stores target device position information sequentially transmitted from the target device 20 in accordance with an instruction from the control unit 11 in association with the identification code of the target device 20.
The training result registration table 126 includes, based on an instruction from the control unit 11, a determination result by the target impact determination unit 111 and the trainee determination unit 112, shooting information and bullet passage information of the shooting training DB 121, and a target device position registration table 125. The training result information is stored based on the target device position information.
Here, the training result registration table 126 of the storage unit 12 will be described in detail. FIG. 11 is a diagram illustrating an example of a training result registration table of the control device. The training result registration table 126 includes a trainee code for identifying the trainee 80 who fired, the shooting time at which the bullet was fired from the firearm 34 (similar to the shooting time in the shooting information registration table 32b in FIG. 4), and the target. The passage time indicating the time when the bullet has passed through the detection area 400 of the area detection sensor unit 25 of the device 20 (similar to the passage time in the bullet passage information registration table 22b in FIG. 8), the result of impact on the target 24a, and the target The target code for identifying the device 20 and the two-dimensional XY coordinates of the bullet passage point in the detection area 400 of the area detection sensor unit 25 of the target device 20 (the two-dimensional coordinates of the bullet passage point in the bullet passage information registration table 22b in FIG. 8) And the same).

[Operation of shooting training system]
Next, the operation of the shooting training system S according to the first embodiment of the present invention will be described with reference to FIGS. FIG. 12 is a sequence diagram illustrating an operation of the shooting training system according to the first embodiment of the present invention. In FIG. 1 and FIG. 2, first, the trainee 80-1 fires from the firearm 34-1 and, as shown by the trajectory R1, the bullet hits the target 24a-1 of the target device 20-1. It is assumed that the trainer 80-2 fires from the firearm 34-2, and the bullet hits the target 24a-2 of the target device 20-2 as shown by the trajectory R2. .
1 and 2, when the trainee 80-1 fires a bullet from the firearm 34-1 of the shooting device 30-1 toward the target 24a-1 of the target device 20-1, as shown by the trajectory R1, the shooting is performed. In the device 30-1, the bullet firing detection unit 36 detects the vibration of the firearm 34-1 and transmits a bullet firing signal to the control unit 31 based on the detected vibration data (step S101).
The control unit 31 of the shooting device 30-1 receives the bullet firing signal from the bullet firing detection unit 36, and stores the data related to the shooting in the shooting information registration table 32b of the storage unit 32 in association with the shooting time information. At the same time, it attaches an identification code for identifying the shooting device 30 to the shooting information, and transmits the shooting information to the control device 10 via the communication unit 33 (step S102).
The control unit 31 of the shooting device 30-1 sequentially reads out the firearm position information from the firearm position information table 32a of the storage unit 32, attaches an identification code for identifying the shooting device 30 to the communication unit 23, Is transmitted to the control device 10 via the control unit 10.

On the other hand, in the target device 20-1, a predetermined interval h1 (for example, 20 cm) is provided in front of the target 24a-1, and two detection areas 400-1-1 and 400-1-2 are arranged side by side. The area detection sensor unit 25 detects values related to the two-dimensional position coordinates (XY coordinates) at the bullet passing points PS1-1 and PS1-2 by the bullets fired from the firearm 34-1, and converts the data related to the bullet passing. The information is transmitted to the control unit 21 (step S103).
The control unit 21 of the target device 20-1 uses the bullet passing coordinate calculation unit 21a to calculate the target device position information acquired from the position detecting unit 26 and the value related to the two-dimensional position coordinates of the bullet passing point acquired from the area detecting sensor unit 25. The predetermined two-dimensional position coordinates (XY coordinates) and three-dimensional position coordinates at the bullet passing points PS1-1 and PS1-2 are calculated and associated with the time information at the time of reception (that is, the bullet passing time). It is registered in the bullet passage information registration table 22b. Further, the control unit 21 uses the bullet entry angle calculation unit 21b to enter the bullet based on the three-dimensional position coordinates of the bullet passage points PS1-1 and PS1-2 calculated by the bullet passage coordinate calculation unit 21a and the predetermined interval h1. The angle is calculated and registered in the bullet passage information registration table 22b.
The control unit 21 reads the bullet passage information from the bullet passage information registration table 22b of the storage unit 22 and attaches an identification code for identifying the target device 20-1, to the control device 10 via the communication unit 23. It transmits (step S104).
The control unit 21 sequentially reads out the target device position information from the target device position information table 22a of the storage unit 22 and attaches an identification code for identifying the target device 20 to the control device 21 via the communication unit 23. 10.

  The control unit 11 of the control device 10 stores the bullet passage information transmitted from the target device 20-1 in the shooting training DB 121 of the storage unit 12 in association with the identification code of the target device 20-1. Then, the control unit 11 of the control device 10 causes the target impact determination unit 111 to refer to the target impact area coordinate table 122 of the storage unit 12 and to execute the bullet passage included in the bullet passage information acquired from the target device 20-1. Based on the predetermined two-dimensional position coordinates of the point (two-dimensional coordinates of the bullet passage point in the bullet passage information registration table 22b in FIG. 8), it is determined whether or not the bullet hits (hits) the target 24a.

The control unit 11 of the control device 10 uses the trainee determination means 112 to obtain the firearm position information previously obtained from the shooting devices 30-1 and 30-2, the bullet firing information obtained from the shooting device 30-1, and the target Based on the target device position information acquired in advance from the device 20-1 and the bullet passage information acquired from the target device 20-1, the trainee (shooting device) that fired is determined (step S105).
That is, as shown in FIGS. 1 and 2, when the target 24 a-1 of the target device 20-1 is shot by the trajectory R 1, in the control device 10, the trainee determination unit 112 first With reference to the shooting training DB 121 of the storage unit 12, the shooting is performed before the bullet passing time T3 at the bullet passing point PS1-2 acquired from the target device 20-1 and within a predetermined time t1 (for example, 10 seconds). A search is made for the shooting device 30 that has performed. If one shooting device 30 satisfies the condition (the shooting time T1 of the shooting device 30-1 is (T3-t1) <T1 <T3), the shooting device that fired is the shooting device 30-1 and the trainee is determined to be the trainee 80-1 (trainer code A). Note that t1 is appropriately set according to the performance of the firearm 34 to be used (the firing speed of bullets, etc.), the interval of shooting training, and the like.
However, if the shooting device 30-1 and the shooting device 30-2 satisfy the above-mentioned temporal condition, in the control device 10, the trainee determination unit 112 determines that the shooting device 30-1 (the trainee 80-1). ) And the firearm position point PF1 of the firearm 34-1 (position coordinates (X1, Y1, Z1)) based on the firearm position information, the target apparatus position information, and the bullet passage information acquired from the target apparatus 20-1 (M1). ) To the bullet passage point PS1-2 (position coordinates (x3, y3, z3)) in the Z-axis direction, and the X-axis from the weapon position point PF1 of the firearm 34-1 to the bullet passage point PS1-2. The horizontal distance H1 in the direction is obtained, and the entry angle θ1 from the firearm position point PF1 of the firearm 34-1 to the bullet passing point PS1-2 is calculated from L1 and H1. Similarly, based on the firearm position information, the target device position information, and the bullet passage information acquired from the shooting device 30-2 (equipped by the trainee 80-2) and the target device 20-1 (M1), the firearm 34- 2 and the horizontal distance L2 in the Z-axis direction from the weapon position point PF2 (position coordinates (X3, Y3, Z3)) to the bullet passing point PS1-2 (position coordinates (x3, y3, z3)). The horizontal distance H2 in the X-axis direction between the firearm position point PF2 and the bullet passing point PS1-2 is determined, and from L2 and H2, the approach angle θ2 from the weapon position point RF2 of the firearm 34-2 to the bullet passing point PS1-2 is calculated. calculate.
Then, in the control device 10, the trainee determination means 112 uses the respective approach angles θ1 and θ2 obtained above and the bullet approach angle α1 included in the bullet passage information acquired from the target device 20-1 (M1) (FIG. 8), the bullet entry angle α1 matches the entry angle θ1 of the firearm 34-1. Therefore, the shooting indicated by the trajectory R1 was performed by the trainee 80-1 equipped with the shooting device 30-1. Is determined.
In addition, the control unit 11 stores the shooting information and the bullet passage information of the shooting training DB 121 and the target device position information of the target device position registration table 125 based on the determination results by the target impact determination unit 111 and the trainee determination unit 112. The training result information is registered in the training result registration table 126 with reference to the training result registration table 126.

In the control unit 11 of the control device 10, the shooting result drawing means 113 uses the training result information of the training result registration table 126 and the coordinate data of the target hitting area coordinate table 122 to execute the detailed shooting and the bullet for the target 24 a-1. Then, shooting result drawing data including a diagram showing the passing position of is created (step S106).
Then, the control unit 11 of the control device 10 transmits the shooting result drawing data created by the shooting result drawing unit 113 to the shooting device 30-1 specified by the trainee determination unit 112 (Step S107).

The control unit 31 of the shooting device 30-1 displays the shooting result for the target 24a-1 on the display unit 37 based on the shooting result drawing data transmitted from the control device 10 (step S108).
FIG. 13 is a diagram illustrating an example of a display screen of a shooting result displayed on the display unit of the shooting device according to the first embodiment of the present invention.
The control unit 31 of the shooting device 30-1 arranges and displays the display elements such as the button group 600 and the display columns 700 and 710 on the dedicated window of the program of the display unit 37, for example, as in the display screen example 500. I do. The control unit 31 can detect an instruction from the trainee 80 by a GUI (Graphical User Interface) of the OS using an input unit (not shown).

  Button group 600 is a button for a user interface for changing and ending the content of the screen displayed on display screen example 500. Here, a state is shown in which the button for displaying the result of landing of the target device 20 on the target 24a and the shooting result related to the analysis are selected. The button group 600 can also select buttons for displaying training information, terminating a program, and the like.

The display column 700 is a part for displaying the details of shooting.
Based on the shooting result drawing data transmitted from the control device 10, the control unit 31 of the shooting device 30-1 determines a predetermined two-dimensional X of the trainee, the shot time, the shot result, the target, and the bullet passing point. The coordinates and Y coordinates are displayed in a table format.

The display field 710 is a part for drawing a region corresponding to the above-described area 410 (see FIG. 7) among the XY coordinates at which the bullet detection point can be detected by the area detection sensor unit 25 of the target device 20, and the target 24a-1. The bullet passing point for the area 420 is displayed.
The control unit 31 draws the area 420 as an image diagram or the like corresponding to the actual shape and size of the target 24a around the XY coordinate position base point 450 in the display field 710. Then, the control unit 31 displays a mark format such as a mark 801 in the display column 710 on the XY coordinate of the corresponding bullet passing point on the screen based on the information of the predetermined two-dimensional XY coordinates of the bullet passing point. Use to display the shooting result.

  Further, the control unit 11 of the control device 10 displays the shooting result for the target 24a-1 on the display unit 14 based on the shooting result drawing data created by the shooting result drawing unit 113, similarly to FIG. 13 (step S109). ).

Next, in FIGS. 1 and 2, the trainee 80-2 fires a bullet from the firearm 34-2 of the shooting device 30-2 toward the target 24a-2 of the target device 20-2 as indicated by a trajectory R2. Then, in the shooting device 30-2, the bullet firing detection unit 36 detects the vibration of the firearm 34-2, and transmits a bullet firing signal to the control unit 31 based on the detected vibration data (step S110). The control unit 31 of the shooting device 30-2 receives the bullet firing signal from the bullet firing detection unit 36, and stores the data related to the shooting in the shooting information registration table 32b of the storage unit 32 in association with the shooting time information. At the same time, an identification code for identifying the shooting device 30 is attached to the shooting information and transmitted to the control device 10 via the communication unit 33 (step S111).
The control unit 31 of the shooting device 30-2 sequentially reads out the firearm position information from the firearm position information table 32a of the storage unit 22 and attaches an identification code for identifying the shooting device 30 to the communication unit 23. Is transmitted to the control device 10 via the control unit 10.

On the other hand, in the target device 20-2, a predetermined interval h1 (for example, 20 cm) is provided on the near side of the target 24a-2, and two detection areas 400-2-1 and 400-2-2 are arranged side by side. The detection sensor unit 25 detects values related to the two-dimensional position coordinates (XY coordinates) at the bullet passing points PS2-1 and PS2-2 by the bullets fired from the firearm 34-2, and controls the data related to the bullet passing. It is transmitted to the unit 21 (step S112).
The control unit 21 of the target device 20-2 uses the bullet passing coordinate calculation unit 21a to calculate the target device position information acquired from the position detecting unit 26 and the value related to the two-dimensional position coordinates of the bullet passing point acquired from the area detecting sensor unit 25. The predetermined two-dimensional position coordinates (XY coordinates) and three-dimensional position coordinates at the bullet passing points PS2-1 and PS2-2 are calculated, and are associated with the time information at the time of reception (that is, the bullet passing time). It is registered in the bullet passage information registration table 22b. Further, the control unit 21 uses the bullet approach angle calculation unit 21b to enter the bullet based on the three-dimensional position coordinates of the bullet passage points PS2-1 and PS2-2 calculated by the bullet passage coordinate calculation unit 21a and the predetermined interval h1. The angle is calculated and registered in the bullet passage information registration table 22b.
The control unit 21 reads the bullet passage information from the bullet passage information registration table 22b of the storage unit 22 and attaches an identification code for identifying the target device 20-2 to the control device 10 via the communication unit 23. It transmits (step S113).
The control unit 21 sequentially reads out the target device position information from the target device position information table 22a of the storage unit 22 and attaches an identification code for identifying the target device 20 to the control device 21 via the communication unit 23. 10.

  The control unit 11 of the control device 10 stores the bullet passage information transmitted from the target device 20-2 in the shooting training DB 121 of the storage unit 12 in association with the identification code of the target device 20-2. Then, the control unit 11 of the control device 10 causes the target impact determination unit 111 to refer to the target impact area coordinate table 122 of the storage unit 12 and to execute the bullet passage included in the bullet passage information acquired from the target device 20-2. Based on the predetermined two-dimensional position coordinates of the point (two-dimensional coordinates of the bullet passage point in the bullet passage information registration table 22b in FIG. 8), it is determined whether or not the bullet hits (hits) the target 24a.

The control unit 11 of the control device 10 uses the trainee determination means 112 to obtain the respective firearm position information previously obtained from the shooting devices 30-1 and 30-2, the bullet firing information obtained from the shooting device 30-2, and the target Based on the target device position information acquired in advance from the device 20-2 and the bullet passage information acquired from the target device 20-2, the trainee (shooting device) that fired is determined (step S114).
That is, as shown in FIGS. 1 and 2, when the target 24 a-2 of the target device 20-2 is fired at the trajectory R 2, in the control device 10, the trainee determination unit 112 first With reference to the shooting training DB 121 of the storage unit 12, the shooting is performed before the bullet passing time T6 at the bullet passing point PS2-2 acquired from the target device 20-2 and within a predetermined time t1 (for example, 10 seconds). A search is made for the shooting device 30 that has performed. If the number of the shooting devices 30 corresponding to the condition is one (the shooting time T4 of the shooting device 30-2 is in the relationship of (T6−t1) <T4 <T6), the shooting device that performed the shooting is the shooting device. 30-2, and the trainee determines that the trainee is the trainee 80-2 (trainer code B). The time t1 is appropriately set according to the performance of the firearm 34 to be used (the firing speed of the bullet, etc.), the interval of the shooting training, and the like.
However, if the shooting device 30-1 and the shooting device 30-2 satisfy the above-mentioned temporal condition, in the control device 10, the trainee determination unit 112 determines that the shooting device 30-1 (the trainee 80-1). ) And the firearm position information PF1 of the firearm 34-1 (position coordinates (X1, Y1, Z1)) based on the firearm position information, the target device position information, and the bullet passage information acquired from the target device 20-2 (M2). ) To the bullet passing point PS2-2 (position coordinates (x5, y5, z5)) in the Z-axis direction, and the X-axis from the weapon position point PF1 of the firearm 34-1 to the bullet passing point PS2-2. The horizontal distance H3 in the direction is obtained, and the approach angle θ3 from the weapon position point PF1 of the firearm 34-1 to the bullet passing point PS2-2 is calculated from L3 and H3. Similarly, based on the firearm position information, the target device position information, and the bullet passage information acquired from the shooting device 30-2 (equipped by the trainee 80-2) and the target device 20-2 (M2), the firearm 34- is used. 2 and the horizontal distance L4 in the Z-axis direction from the weapon position point PF2 (position coordinates (X3, Y3, Z3)) to the bullet passage point PS2-2 (position coordinates (x5, y5, z5)). The horizontal distance H4 in the X-axis direction between the firearm position point PF2 and the bullet passing point PS2-2 is determined, and from L4 and H4, the approach angle θ4 from the weapon position point RF2 of the firearm 34-2 to the bullet passing point PS2-2 is calculated. calculate.
Then, in the control device 10, the trainee determination means 112 uses the respective approach angles θ3 and θ4 determined above and the bullet approach angle α2 included in the bullet passage information acquired from the target device 20-2 (M2) (see FIG. 8), the bullet entry angle α2 coincides with the entry angle θ4 of the firearm 34-2. Therefore, the shooting indicated by the trajectory R2 was performed by the trainee 80-2 equipped with the shooting device 30-2. Is determined.
In addition, based on the determination results by the target impact determination unit 111 and the trainee determination unit 112, the control unit 11 transmits the shooting information and the bullet passage information of the shooting training DB 121, and the target device position information of the target device position registration table 125. The training result information is registered in the training result registration table 126 with reference to the training result registration table 126.

In the control unit 11 of the control device 10, the shooting result drawing means 113 uses the training result information of the training result registration table 126 and the coordinate data of the target impact area coordinate table 122 to execute the detailed shooting and the bullet for the target 24 a-2. Then, shooting result drawing data including a diagram showing the passing position of is created (step S115).
Then, the control unit 11 of the control device 10 transmits the shooting result drawing data created by the shooting result drawing unit 113 to the shooting device 30-2 specified by the trainee determination unit 112 (Step S116).

  The control unit 31 of the shooting device 30-2 displays the shooting result on the target 24a-2 on the display unit 37 on the basis of the shooting result drawing data transmitted from the control device 10, as in FIG. 13 (step S117). .

  Further, the control unit 11 of the control device 10 displays the shooting result for the target 24a-2 on the display unit 14 on the display unit 14 based on the shooting result drawing data created by the shooting result drawing unit 113 (step S118). ).

By the way, in the control device 10, at the end of the shooting training, the shooting result drawing means 113 of the control unit 11 creates shooting result drawing data reflecting all the results of the shooting training in accordance with an instruction from the input unit 15 by the administrator. , Can be displayed on the display unit 14.
FIG. 14 is a diagram illustrating an example of a list display screen of shooting results displayed on the display unit of the control device according to the first embodiment of the present invention.
The control unit 11 of the control device 10 arranges and displays the display elements such as the button groups 610 and 620 and the display columns 730 to 760 on the dedicated window of the program of the display unit 14 as in the display screen example 510, for example. I do. The control unit 11 can detect a user's instruction for these display elements by a GUI (Graphical User Interface) of the OS using the input unit 15.

The button group 610 is a button for a user interface for controlling the target device 20 and the shooting device 30 to call various processes. Here, a state is shown in which the button of “display result” relating to the result of landing on the target 24a by the shooting training and the analysis is selected. The button group 610 also includes functions for monitoring raw data of the target device 20, setting a schedule such as standing up / falling down, performing control processing divided into groups, displaying training information, detecting an impact position, and calling a function for maintenance. And buttons for printing the result, terminating the program, and the like.
The button group 620 is an operation button for selecting whether or not to render the shooting result information of the entire list displayed in the display field 750 described later in the display field 760, and for clearing the drawing content of the display field 760.

The display field 730 is a button for displaying the name of the trainee performing the shooting training and for selecting the trainee for displaying the shooting results in a list.
The display field 740 is a button for displaying the name of the target to be used and for selecting a target to be displayed when displaying the shooting results in a list.
The display field 750 is a part for displaying only information on the impact from the data registered in the training result registration table 126 of the storage unit 12 in a list format.
The control unit 11 of the control device 10 adds, in the list of the display field 750, the order of firing (No.), the trainee who fired, the time of impact (bullet passage), the result of impact on the target, the impact on the target, Information such as a name and predetermined two-dimensional XY coordinates of a bullet passing point in the detection area 400 of the area detection sensor unit 25 of the target device 20 is displayed.

The display column 760 is a part for drawing an area corresponding to the above-described area 410 (see FIG. 7) among the coordinates at which the area detection sensor unit 25 of the target device 20 can detect the passage of a bullet.
The control unit 11 draws the area 420 as an image diagram or the like corresponding to the actual shape and size of the target 24a around the XY coordinate position base point 450 in the display field 760. Then, the control unit 11 displays, in the display field 760, marks 802, 803, etc. on the XY coordinates of the corresponding bullet passing point on the screen based on the information of the predetermined two-dimensional XY coordinates of each bullet passing point. In this way, a plurality of shooting results are displayed in a mark format.
In the display column 760, the shooting result of the trainee 80-1 is displayed in, for example, black, and the shooting result of the trainee 80-2 is displayed in a color other than black, so that the training result with the trainee 80-1 is displayed. The result of the shooting by the person 80-2 can be easily compared.
Further, the control unit 11 draws the shooting order of the list display in the display field 750 next to the circle in the marks 802, 803, and the like. As a result, it is possible to easily know the number of the impact position.

  As described above, according to the shooting training system according to the first embodiment of the present invention, when a plurality of trainees participate and perform shooting at random, who shoots at which target, and when, By judging whether the bullet hits (hits) the target by shooting and displaying the result of the shooting in real time on a display that can be visually recognized by the trainee, the trainee can immediately see his own shooting result. Therefore, the accuracy of shooting training can be improved, and the efficiency of shooting training can be improved.

Embodiment 2 Hereinafter, a shooting training system according to Embodiment 2 of the present invention will be described.
In the shooting training system Q according to the second embodiment of the present invention, when a plurality of trainees participate and perform shooting at random, who shoots at which target, and when the shooting is performed, By judging whether or not the vehicle has hit (hit), the result of the shooting is displayed in real time on a display that can be visually recognized by the trainee, so that the trainee can immediately confirm the shooting result of the user. Training accuracy can be improved, and the efficiency of shooting training can be improved.
The shooting training system Q according to the second embodiment of the present invention differs from the shooting training system S according to the first embodiment in a method for specifying a trainee who has fired.

[Configuration of shooting training system]
The configuration of the shooting training system Q according to the second embodiment of the present invention will be described with reference to FIG. FIG. 15 is a system configuration diagram of the shooting training system according to the second embodiment of the present invention. In FIG. 15, the same components as those in FIG. 1 are denoted by the same reference numerals, and description thereof is omitted.
As shown in FIG. 15, the shooting training system Q according to the second embodiment of the present invention is equipped with the trainees 80-1 and 80-2 and the trainees 80-1 and 80-2, each of which performs shooting in the shooting training. The shooting devices 70-1 and 70-2, the target devices 60-1 and 60-2, and the control device 50. As shown in FIG. 15, the shooting training system Q is configured such that the trainee 80-1 or the trainee 80-2 randomly moves toward the target 24a-1 of the target device 60-1 or the target 24a-2 of the target device 60-2. Is to fire. In this embodiment, first, the trainee 80-1 fires at the target 24a-1 as indicated by the trajectory R1, and then the trainee 80-2 moves the target 24a-2 at the trajectory R2. , And the trainee 80-2 fires the trajectory R3. When the trainees 80-1 and 80-2 are not distinguished from each other, when the trainee 80 is not distinguished from the shooting devices 70-1 and 70-2, the shooting device 70 and the target device 60- In the case where 1,60-2 is not distinguished, it is simply referred to as the target device 60.
The shooting device 70 and the control device 50 and the target device 60 and the control device 50 are connected to each other by, for example, wireless communication.
In FIG. 15, the shooting device 70 and the target device 60 are each configured as two units, but one or three or more shooting devices 70 or the target devices 60 are connected to one control device 50 by signal connection. It is also possible to configure so that

The shooting device 70 is equipped and used by the trainee 80 when performing shooting training. In addition, the shooting device 70 transmits shooting information (firearm information, trainee information, shooting time, and the like) from the laser light transmission unit 75 to the target device 60 using a laser.
The target device 60 is a device that is a target of shooting training using live ammunition. The target device 60 causes the target 24a to perform the concealing operation according to schedule information created in advance or an instruction from the control device 50. The target 24a is a detachable target main body that is driven and controlled by the control unit 61, and is a target for shooting training. The area detection sensor unit 65 detects a value related to the two-dimensional position coordinates (XY coordinates) of the bullet passing point. The detection area 400 is a range in which the area detection sensor unit 65 can detect the two-dimensional position coordinates of the bullet passing point.

  The control device 50 is a controller of the target device 60 that displays a control instruction to the target device 60, a display of an operation state, a result of landing on the target 24a, and the like. Further, the control device 50 acquires the operating state and the bullet passage information from the target device 60. Further, the control device 50 uses the bullet passing information such as the predetermined two-dimensional position coordinates (XY coordinates) of the bullet passing point acquired from the target device 60 and the bullet passing time, and controls the target device 60 and the bullet landing result. Can be improved. Further, the control device 50 determines the trainee who has fired based on shooting information such as bullet firing and bullet firing time obtained from the target device 60 and bullet passing information, and also determines the trainee who has performed the shooting. The training result information is transmitted to the shooting device 70 equipped with.

[Control configuration of shooting device]
Next, a control configuration of the shooting device 70 of the shooting training system Q according to the second embodiment of the present invention will be described in detail with reference to FIG. FIG. 16 is a block diagram illustrating a control configuration of the shooting device according to the second embodiment of the present invention. Note that, in FIG. 16, the same components as those in FIG. 3 are denoted by the same reference numerals, and description thereof will be omitted.
As shown in FIG. 16, the shooting device 70 includes a control unit 71, a storage unit 72, a communication unit 33, a firearm 34, a laser transmission unit 75, a bullet firing detection unit 36, a display unit 37, a power supply And a unit 38. The control unit 71 is signal-connected to the storage unit 72, the communication unit 33, the laser transmission unit 75, the bullet firing detection unit 36, the display unit 37, the power supply unit 38, and other components constituting the shooting device 70, and forms the shooting device 70. Each part and the entire shooting device 70 are controlled.
Based on the bullet firing signal from the bullet firing detecting unit 36, the laser transmitting unit 75 transmits the information regarding the shooting toward the target device 60 as indicated by the laser pattern LP1 in FIG. Laser light including firearm information, trainee information, shooting time, etc.).

The control unit 71 receives the bullet firing signal from the bullet firing detection unit 36, and associates the data relating to the shooting with the time information at the time of reception (that is, the shooting time information), 72a.
Further, the control unit 71 reads out the transmission information relating to the shooting from the transmission information registration table 72a of the storage unit 72, attaches the identification code for identifying the shooting device 70 to the laser transmission unit 75, and outputs the information to the laser transmission unit 75. To the target device 60 to transmit a laser beam including transmission information regarding shooting.

  The storage unit 72 includes a transmission information registration table 72a. The storage unit 72 stores the data relating to the shooting and the shooting time information in the transmission information registration table 72a in association with the shooting time information based on the bullet firing signal acquired from the bullet firing detection unit 36 in accordance with an instruction from the control unit 71. Here, the transmission information registration table 72a of the storage unit 72 will be described in detail. FIG. 17 is a diagram illustrating an example of a transmission information registration table of the shooting device. The transmission information registration table 72a includes a shooting code for identifying a shooting action, a firearm code for identifying a firearm 34 used for shooting, a trainer code for identifying a trainee 80 that fired, and a bullet from the firearm 34. And the shooting time indicating the time at which the is fired.

[Control configuration of target device]
Next, a control configuration of the target device 60 of the shooting training system Q according to the second embodiment of the present invention will be described in detail with reference to FIGS. FIG. 18 is a block diagram illustrating a control configuration of the target device according to the second embodiment of the present invention. FIG. 19 is a schematic diagram illustrating an example of the target device according to the second embodiment of the present invention. In FIGS. 18 and 19, the same components as those in FIGS. 5 and 6 are denoted by the same reference numerals and description thereof is omitted.
As shown in FIG. 18, the target device 60 includes a control unit 61, a storage unit 62, a communication unit 23, a target driving unit 24 connected to the target 24a, an area detection sensor unit 65, and a laser receiving unit 66. , A presenting unit 27, a truck driving unit 28 connected to the truck 28 a, and a power supply unit 29. The control unit 61 includes the storage unit 62, the communication unit 23, the target driving unit 24, the area detection sensor unit 65, the laser receiving unit 66, the display unit 27, the bogie driving unit 28, and the power supply unit 29. , And controls each unit constituting the target device 60 and the entire target device 60.
Further, the target device 60 can perform autonomous control by the built-in control unit 61, wireless or wired program control from the control device 50, or control by manual operation by an operator (not shown).

The target driving unit 24 is a part including a motor, an encoder, an electromagnetic actuator, and the like for driving the target 24a. The target drive unit 24 is configured to be able to detach and replace the target 24a. The target drive unit 24 performs various expressions corresponding to the body motion of the enemy (trainer 80) using the connection unit, the motor, and the like. The target driving unit 24 moves up, down, rotates, rises, or falls down on the target 24a according to an instruction from the control unit 71, for example, according to bullet passage information from an area detection sensor unit 65 described later, as shown in FIG. Such an operation is performed.
The area detection sensor unit 65 arranges the detection area 400 in front of the target 24a to be driven, and calculates a value related to the two-dimensional position coordinates (XY coordinates) of the bullet passing point fired from the firearm 34 held by the trainee 80. It detects and transmits data relating to bullet passage to the control unit 61. The area detection sensor unit 65 detects passage of a bullet in a predetermined range (detection area 400 in FIG. 7) wider than the target 24a. Therefore, even when the bullet does not land on the target 24a, a value relating to the two-dimensional position coordinates (XY coordinates) of the bullet passing point can be obtained. In the case of an actual bullet, the area detection sensor unit 65 may use a sensor that detects a shock wave, an ultrasonic sensor, or the like, as a means for detecting bullet passage.
The laser receiving unit 66 receives the laser light transmitted from the shooting device 70 and outputs transmission information on the shooting included in the laser light to the control unit 61.

The control unit 61 includes a bullet passing coordinate calculation unit 61a. The bullet passing coordinate calculation means 61a calculates predetermined two-dimensional position coordinates (XY coordinates) from values related to the two-dimensional position coordinates of the bullet passing point acquired from the area detection sensor unit 65, and receives time information at the time of reception (that is, time information). , Bullet passing time) in the shooting result registration table 62b. In addition, the control unit 61 causes the transmission information regarding the shooting acquired from the laser receiving unit 66 to be stored in the shooting device information registration table 62a of the storage unit 62 together with the identification code of the shooting device 70.
The control unit 61 reads out the shooting result information from the shooting result registration table 62b of the storage unit 62, attaches an identification code for identifying the target device 60, and transmits it to the control device 50 via the communication unit 23.

  The storage unit 62 includes a shooting device information registration table 62a and a shooting result registration table 62b. The storage unit 62 stores, in accordance with an instruction from the control unit 61, transmission information on the shooting acquired from the laser receiving unit 66 together with the identification code of the shooting device 70 in the shooting device information registration table 62a. The storage unit 62 stores predetermined two-dimensional position coordinates (XY coordinates) and a bullet passage time of the bullet passage point calculated by the bullet passage coordinate calculation unit 61a, and a target device information registration table 62a in accordance with an instruction from the control unit 61. The information is stored in the shooting result registration table 62b in association with the transmission information on the shooting. Here, the shooting device information registration table 62a and the shooting result registration table 62b of the storage unit 62 will be described in detail. FIG. 20 is a diagram illustrating an example of the shooting device information registration table of the target device. FIG. 21 is a diagram illustrating an example of the shooting result registration table of the target device. As shown in FIG. 20, the shooting device information registration table 22a includes a shooting device code for identifying the shooting device 70, a shooting code for identifying the shooting action, and a firearm code for identifying the firearm 34 used for shooting. And a trainee code identifying the trainee 80 that fired, and a shooting time indicating the time at which the bullet was fired from the firearm 34. As shown in FIG. 21, the shooting result registration table 62b includes a shooting device code for identifying the shooting device 70, a shooting code for identifying the shooting action, and a firearm for identifying the firearm 34 used for shooting. A code, a trainee code identifying the trainee 80 who fired, a firing time indicating the time at which the bullet was fired from the firearm 34, a passing time indicating the time at which the bullet passed, and a bullet passing through the detection area 400. And predetermined two-dimensional position coordinates of the point.

[Control configuration of control device]
Next, a control configuration of the control device 50 of the shooting training system Q according to the second embodiment of the present invention will be described in detail with reference to FIG. FIG. 22 is a block diagram illustrating a control configuration of the control device according to the second embodiment of the present invention.
The control device 50 includes a control unit 51, a storage unit 52, a communication unit 13, a display unit 14, an input unit 15, and a power supply unit 16, as shown in FIG. The control unit 51 is signal-connected to each unit configuring the control device 50 such as the storage unit 52, the communication unit 13, the display unit 14, the input unit 15, and the power supply unit 16, and controls each unit configuring the control device 50 and the entire control device 50. Control. In FIG. 22, the same components as those in FIG. 9 are denoted by the same reference numerals, and description thereof will be omitted.

The control unit 51 is a CPU, a GPU, a DSP, or the like, and executes a program or the like stored in the storage unit 52 using hardware resources. The control unit 51 gives an instruction to the target device 60 and controls to display various data on the display unit 14. Further, the control unit 51 acquires shooting result information from the target device 60 and stores the acquired shooting result information in the training result information registration table 52a of the storage unit 52 in association with the target code of the target device 60. In addition, the control unit 51 refers to the shooting result information acquired from the target device 60, specifies the trainee who performed the shooting, and transmits the shooting result drawing data to the shooting device 70 equipped by the trainee. I do.
The storage unit 52 is a storage unit including a RAM, a ROM, an HDD, a flash memory, and the like. The storage unit 52 stores programs, data, and the like for controlling the target device 60 and analyzing the impact. Details of the program and data will be described later. The storage unit 52 also stores a general-purpose OS (Operating System), firmware, and the like.

  Further, the control unit 51 includes a target impact determination unit 51a, a trainee determination unit 51b, a shooting result drawing unit 51c, a target operation instruction unit 114, and a present operation instruction unit 115.

The target impact determination unit 51a refers to the target impact area coordinate table 122 of the storage unit 52, and refers to the two-dimensional position coordinates of the bullet passing point of the detection area 400 included in the shooting result information acquired from the target device 60 (FIG. 15). It is determined whether or not the bullet has landed (hits) on the target 24a based on the two-dimensional position coordinates of the detection area 400).
The trainee determination unit 52b refers to the shooting result information acquired from the target device 60, and determines the trainee (shooting device) that has fired.
In addition, the control part 51 registers the determination result by the target impact determination means 51a in the training result information registration table 52a.

  The shooting result drawing means 51c is based on the training result information of the training result information registration table 52a and the coordinate data of the target hitting area coordinate table 122, and includes a shooting detail including a diagram showing a bullet passing position with respect to the target 24a. Create drawing data. The shooting result drawing means 51c creates shooting result drawing data summarizing the results of the shooting training at the end of the shooting training, based on the instruction from the input unit 15 by the administrator.

The storage unit 52 includes a shooting training DB 121, a target impact area coordinate table 122, a target control instruction table 123, and a training result information registration table 52a.
The training result information registration table 52a stores the determination result by the target impact determination unit 51a and the shooting result information acquired from the target device 60 according to an instruction from the control unit 51.
Here, the training result information registration table 52a of the storage unit 52 will be described in detail with reference to FIG. FIG. 23 is a diagram illustrating an example of a training result information registration table of the control device. The training result information registration table 52a includes a trainee code for identifying the trainee 80 who fired, a shooting time at which a bullet was fired from the firearm 34 (similar to the shooting time in the shooting result registration table 62b in FIG. 21), A passing time indicating the time when the bullet has passed through the detection area 400 of the area detection sensor unit 65 of the target device 60 (similar to the passing time in the shooting result registration table 62b in FIG. 21), the result of impact on the target 24a, and the target The target code for identifying the device 60 and the two-dimensional XY coordinates of the bullet passing point in the detection area 400 of the area detection sensor unit 65 of the target device 60 (the two-dimensional coordinates of the bullet passing point in the shooting result registration table 62b in FIG. The same).

[Operation of shooting training system]
Next, the operation of the shooting training system Q according to the second embodiment of the present invention will be described with reference to FIGS. FIG. 24 is a sequence diagram illustrating an operation of the shooting training system according to the second embodiment of the present invention. In FIG. 15, first, the trainee 80-1 fires from the firearm 34-1 and a bullet hits the target 24a-1 of the target device 60-1, as shown by the trajectory R1. Further, it is assumed that the trainee 80-2 shoots from the firearm 34-2, and the bullet hits the target 24a-2 of the target device 60-2 as indicated by the trajectory R2.
In FIG. 15, when the trainee 80-1 fires a bullet from the firearm 34-1 of the shooting device 70-1 toward the target 24a-1 of the target device 60-1, as shown by the trajectory R1, the shooting device 70- In 1, the bullet firing detection unit 36 detects the vibration of the firearm 34-1 and transmits a bullet firing signal to the control unit 71 based on the detected vibration data (step S201).
The control unit 71 of the shooting device 70-1 receives the bullet firing signal from the bullet firing detection unit 36, and stores the data related to the shooting in the transmission information registration table 72a of the storage unit 72 in association with the shooting time information. At the same time, the information on the shooting is attached to the laser transmission unit 75 with an identification code for identifying the shooting device 70-1, and is output from the laser transmission unit 75 to the target device 60-1 as indicated by the laser pattern LP1. A laser beam including transmission information regarding shooting is transmitted (step S202).

On the other hand, in the target device 60-1, the area detection sensor unit 65-1 having the detection area 400-1 provided on the front side of the target 24a-1 is used at the bullet passing point by the bullet fired from the firearm 34-1. A value related to two-dimensional position coordinates (XY coordinates) is detected, and data related to bullet passage is transmitted to the control unit 61 (step S203).
The control unit 61 of the target device 60-1 determines predetermined two-dimensional position coordinates (XY coordinates) from the values related to the two-dimensional position coordinates of the bullet passing point acquired from the area detection sensor unit 65-1 by the bullet passing coordinate calculation unit 61a. ) Is calculated and registered in the shooting result registration table 62b in association with the time information at the time of reception (ie, the bullet passing time). Further, the control unit 61 registers the transmission information regarding the shooting acquired from the laser receiving unit 66 together with the identification code of the shooting device 70-1 in the shooting device information registration table 62a and the shooting result registration table 62b of the storage unit 62 ( Step S204).
Then, the control unit 61 reads the shooting result information from the shooting result registration table 62b of the storage unit 62, attaches an identification code for identifying the target device 60-1, and adds the identification code to the control device 50 via the communication unit 23. (Step S205).

The control unit 51 of the control device 50 stores the shooting result information transmitted from the target device 60-1 in the training result information registration table 52a of the storage unit 52 in association with the identification code of the target device 60-1. Then, the control unit 51 of the control device 50 refers to the target impact area coordinate table 122 of the storage unit 52 with the target impact determination unit 51a, and the bullet passage included in the shooting result information acquired from the target device 60-1. Based on the predetermined two-dimensional position coordinates of the point (the XY coordinates of the bullet passing through the detection area 400-1 in FIG. 15), it is determined whether or not the bullet hits (hits) the target 24a, and the determination result is trained. The result is registered in the result information registration table 52a.
Further, the control unit 51 of the control device 50 uses the shooting result drawing means 51c based on the training result information of the training result information registration table 52a and the coordinate data of the target landing area coordinate table 122 to set the details of the shooting and the target 24a- The shooting result drawing data including the figure showing the passing position of the bullet with respect to 1 is created (step S206).
Then, the control unit 51 of the control device 50 transmits the shooting result drawing data created by the shooting result drawing unit 51c to the shooting device 70-1 specified by the trainee determination unit 52b (Step S207).

The control unit 71 of the shooting device 70-1 displays the shooting result for the target 24a-1 on the display unit 37 on the display unit 37 based on the shooting result drawing data transmitted from the control device 50 (step S208). .
Further, the control unit 51 of the control device 50 displays the shooting result for the target 24a-1 on the display unit 14 on the display unit 14 based on the shooting result drawing data created by the shooting result drawing unit 51c as in FIG. 13 (step S209). ).

Next, in FIG. 15, when the trainee 80-2 fires a bullet from the firearm 34-2 of the shooting device 70-2 toward the target 24a-2 of the target device 60-2 as shown by a trajectory R2, the firing is performed. In the device 70-2, the bullet firing detection unit 36 detects the vibration of the firearm 34-2, and transmits a bullet firing signal to the control unit 71 based on the detected vibration data (step S210).
The control unit 71 of the shooting device 70-2 receives the bullet firing signal from the bullet firing detection unit 36, and stores the data related to the shooting in the transmission information registration table 72a of the storage unit 72 in association with the shooting time information. At the same time, information on the shooting is attached to the laser transmission unit 75 with an identification code for identifying the shooting device 70-2, and is output from the laser transmission unit 75 to the target device 60-2 in a laser pattern (not shown). A laser beam including transmission information on shooting is transmitted (step S211).

On the other hand, in the target device 60-2, the area detection sensor unit 65-2 having the detection area 400-2 provided on the front side of the target 24a-2 causes the area at the bullet passing point by the bullet fired from the firearm 34-2. A value related to two-dimensional position coordinates (XY coordinates) is detected, and data related to bullet passage is transmitted to the control unit 61 (step S212).
The control unit 61 of the target device 60-2 determines predetermined two-dimensional position coordinates (XY coordinates) from the values related to the two-dimensional position coordinates of the bullet passing point acquired from the area detection sensor unit 65-2 by the bullet passing coordinate calculation unit 61a. ) Is calculated and registered in the shooting result registration table 62b in association with the time information at the time of reception (ie, the bullet passing time). Further, the control unit 61 registers the transmission information on the shooting acquired from the laser receiving unit 66 together with the identification code of the shooting device 70-2 in the shooting device information registration table 62a and the shooting result registration table 62b of the storage unit 62 ( Step S213).
Then, the control unit 61 reads out the shooting result information from the shooting result registration table 62b of the storage unit 62, attaches an identification code for identifying the target device 60-2, and attaches the control device 50 via the communication unit 23. (Step S214).

The control unit 51 of the control device 50 stores the shooting result information transmitted from the target device 60-2 in the training result information registration table 52a of the storage unit 52 in association with the identification code of the target device 60-2. Then, the control unit 51 of the control device 50 refers to the target impact area coordinate table 122 of the storage unit 52 with the target impact determination unit 51a, and the bullet passage included in the shooting result information acquired from the target device 60-2. Based on the predetermined two-dimensional position coordinates of the point (the XY coordinates of the bullet passing through the detection area 400-1 in FIG. 15), it is determined whether or not the bullet hits (hits) the target 24a, and the determination result is trained. The result is registered in the result information registration table 52a.
Further, the control unit 51 of the control device 50 uses the shooting result drawing means 51c based on the training result information of the training result information registration table 52a and the coordinate data of the target landing area coordinate table 122 to set the details of the shooting and the target 24a- The shooting result drawing data including the figure showing the passing position of the bullet with respect to No. 2 is created (step S215).
Then, the control unit 51 of the control device 50 transmits the shooting result drawing data created by the shooting result drawing unit 51c to the shooting device 70-2 specified by the trainee determination unit 52b (Step S216).

The control unit 71 of the shooting device 70-2 displays the shooting result for the target 24a-2 on the display unit 37 on the display unit 37 based on the shooting result drawing data transmitted from the control device 50 (step S217). .
In addition, the control unit 51 of the control device 50 displays the shooting result for the target 24a-2 on the display unit 14 on the display unit 14 based on the shooting result drawing data created by the shooting result drawing unit 51c (step S218). ).

  By the way, in the control device 50, at the end of the shooting training, the shooting result drawing data reflecting all the results of the shooting training is created by the shooting result drawing unit 51c of the control unit 51 according to the instruction from the input unit 15 by the administrator. Can be displayed on the display unit 14 (see FIG. 14).

  As described above, according to the shooting training system according to Embodiment 2 of the present invention, when a plurality of trainees participate and perform shooting at random, who shoots at which target, and when, By judging whether the bullet hits (hits) the target by shooting and displaying the result of the shooting in real time on a display that can be visually recognized by the trainee, the trainee can immediately see his own shooting result. Therefore, the accuracy of shooting training can be improved, and the efficiency of shooting training can be improved.

  It should be noted that the configuration and operation of the above-described embodiment are examples, and it is needless to say that the configuration and operation can be appropriately modified and executed without departing from the spirit of the present invention.

  INDUSTRIAL APPLICATION This invention is utilized in the industry which builds the shooting training system which performs shooting training using a live bullet. This application claims the benefit of priority based on Japanese Patent Application No. 2006-182765 filed on September 20, 2016, the entire disclosure of which is incorporated herein by reference.

10: control device, 11: control unit, 12: storage unit, 13: communication unit, 13a: antenna, 14: display unit, 15: input unit, 16: power supply unit, 20, 20-1, 20-2: target Device, 21: control unit, 21a: bullet passage coordinate calculation unit, 21b: bullet entry angle calculation unit, 22: storage unit, 22a: target device position information table, 22b: bullet passage information registration table, 23: communication unit, 23a , 23a-1, 23a-2: antenna, 24: target drive unit, 24a, 24a-1, 24a-2: target, 25: area detection sensor unit, 26: position detection unit, 27: presenting unit, 28: Bogie driving unit, 28a: bogie, 29: power supply unit, 30, 30-1, 30-2: shooting device, 31: control unit, 32: storage unit, 32a: firearm position information table, 32b: shooting information registration table, 33: communication unit, 3 a, 33a-1, 33a-2: antenna, 34, 34-1, 34-2: firearm, 35: position detection unit, 36: bullet emission detection unit, 37: display unit, 38: power supply unit, 50: control Apparatus, 51: control unit, 51a: target impact determination unit, 51b: trainee determination unit, 51c: shooting result drawing unit, 52: storage unit, 52a: training result information registration table, 60, 60-1, 60- 2: Target device, 61: control unit, 61a: bullet passing coordinate calculation means, 62: storage unit, 62a: shooting device information registration table, 62b: shooting result registration table, 65, 65-1, 65-2: area detection Sensor unit, 66, 66-1, 66-2: laser receiving unit, 70, 70-1, 70-2: shooting device, 71: control unit, 72: storage unit, 72a: transmission information registration table, 75, 75 -1,75-2: Laser sending , 80, 80-1, 80-2: trainee, 111: target hit determination unit, 112: trainee determination unit, 113: shooting result drawing unit, 114: target operation instruction unit, 115: present operation instruction Means, 121: shooting training DB, 122: target impact area coordinate table, 123: target control instruction table, 124: firearm position registration table, 125: target device position registration table, 126: training result registration table, 400, 400- 1, 400-1-1, 400-1-2, 400-2, 400-2-1, 400-2-2: detection area, 410: area, 420: area, 450: XY coordinate position base point, 500, 510: display screen example, 600, 610, 620: button group, 700, 710, 730, 740, 750, 760: display column, 801, 802: mark.
LP1: laser pattern, PF1, PF2: firearm position point, PS1, PS2: bullet passage point, PT1, PT2: target position point, R1, R2, R3, R4: trajectory, Q, S: shooting training system.

Claims (5)

The shooting device, comprising: a shooting device equipped by at least one trainer who performs shooting training using a firearm; at least one target device including a target; and a control device that analyzes a result of the shooting training. And between the control device, and between the target device and the control device, a shooting training system connected to each other by a communication line,
The shooting device,
A bullet firing detection unit that detects a bullet firing from the firearm,
A position detection unit that detects three-dimensional position coordinates of the firearm;
A control unit that attaches an identification code of the shooting device to the bullet firing information and the bullet firing time information detected by the bullet firing detection unit, and the firearm position information detected by the position detection unit, and transmits the information to the control device. ,
The target device comprises:
Between the trainee and the target, having a detection area arranged in front of the target, an area detection sensor unit that detects the two-dimensional position coordinates of a bullet passing point in the detection area,
A position detection unit that detects three-dimensional position coordinates of the target device;
The three-dimensional position coordinates of the bullet passing point are calculated based on the two-dimensional position coordinates of the bullet passing point in the area detection sensor unit and the three-dimensional position coordinates of the target device, and the bullet passing point coordinate information and the bullet passing point are calculated. Time information, as well as target device position information, with an identification code of the target device, and a control unit that transmits to the control device,
The control device includes:
A shooting unit comprising: a trainer determining unit that determines a trainee who has fired based on bullet firing time information obtained from the shooting device and bullet passage time information obtained from the target device. Training system. The shooting training system according to claim 1,
The area detection sensor unit of the target device has two detection areas arranged with a predetermined gap in front of the target, and an area detection sensor that detects two-dimensional position coordinates of a bullet passing point at two places. Department,
The control unit of the target device, based on the two-dimensional position coordinates of the bullet passing point in the two detection areas detected by the area detection sensor unit and the numerical value of the predetermined gap, to calculate the bullet entry angle, A control unit that transmits the bullet approach angle information to the control device,
The trainee determination means of the control device, before the bullet passing time acquired from the target device, and, if there is a plurality of shooting devices that fired within a predetermined time, the plurality of shooting devices Based on the firearm position information and the bullet passing point coordinate information, the approach angle of each firearm with respect to the bullet passing point was calculated, compared with the bullet approach angle information obtained from the target device, and fired. A shooting training system, which is trainee determination means for determining a trainee. The shooting training system according to claim 1 or 2,
The control device includes:
In the detection area of the area detection sensor unit of the target device, a target landing area coordinate table in which two-dimensional position coordinates of a range corresponding to the target are registered,
A storage unit having a training result registration table in which training result information is registered based on the shooting device information obtained from the shooting device and the bullet passage information obtained from the target device from the determination result by the trainee determination unit. ,
The control unit of the control device,
Referring to the target impact area coordinate table in the storage unit, the bullet impacts the target based on the two-dimensional position coordinates of the bullet passing point in the detection area close to the target acquired from the target device. Target impact determination means for determining whether or not
Based on the training result information of the training result registration table and the coordinate data of the target impact area coordinate table, a shooting result that creates shooting result drawing data including a diagram showing details of training and a bullet passing position with respect to the target Drawing means,
A shooting training system, wherein the shooting result drawing data is transmitted to a shooting device equipped by the trainee specified by the trainee determination unit. The shooting device, comprising: a shooting device equipped by at least one trainer who performs shooting training using a firearm; at least one target device including a target; and a control device that analyzes a result of the shooting training. And between the control device, and between the target device and the control device, a shooting training system connected to each other by a communication line,
The shooting device,
A bullet firing detection unit that detects a bullet firing from the firearm,
Laser transmission for transmitting a laser beam including an identification code of the shooting device, firearm information, trainee information, and shooting information of a shooting time toward the target device based on a bullet firing signal from the bullet firing detection unit. And a part,
The target device comprises:
Between the trainee and the target, having a detection area arranged in front of the target, an area detection sensor unit that detects the two-dimensional position coordinates of a bullet passing point in the detection area,
A laser receiving unit that receives the laser light transmitted from the shooting device and outputs shooting information included in the laser light,
A storage unit having a shooting result registration table for registering shooting result information,
A bullet passing coordinate calculating means for calculating predetermined two-dimensional position coordinates from the two-dimensional position coordinates of the bullet passing point obtained from the area detection sensor unit; and a predetermined bullet passing point calculated by the bullet passing coordinate calculating means. The two-dimensional position coordinates are stored in the shooting result registration table in association with the bullet passing time, and the shooting information acquired from the laser receiving unit is stored in the shooting result registration table, and the shooting result registration table is stored. A control unit that reads out shooting result information from the target device, attaches an identification code of the target device, and transmits the target device to the control device,
The control device includes:
A shooting training system comprising: a control unit having a trainee determination unit that determines a trainee who has fired by referring to shooting result information acquired from the target device. The shooting training system according to claim 4,
The control device includes:
In the detection area of the area detection sensor unit of the target device, a target landing area coordinate table in which two-dimensional position coordinates of a range corresponding to the target are registered,
A training result registration table for registering training result information,
The control unit of the control device includes:
Means for registering the shooting result information acquired from the target device in the training result registration table in association with the identification code of the target device,
Referring to the target impact area coordinate table of the storage unit, based on the two-dimensional position coordinates of the bullet passing point included in the shooting result information acquired from the target device, whether or not the bullet impacts the target. Target impact determination means for determining whether
Based on the training result information of the training result registration table and the coordinate data of the target impact area coordinate table, a shooting result that creates shooting result drawing data including a diagram showing details of training and a bullet passing position with respect to the target Drawing means,
A shooting training system, wherein the shooting result drawing data is transmitted to a shooting device equipped by the trainee specified by the trainee determination unit.

Images