KR20190054645A - Live mission training machine, method, system through augmented reality and live virtual constructive - Google Patents

Abstract

The present invention relates to a live mission training device through a live virtual constructive (L-V-C) and an augmented reality, capable of performing a mission training to be similar to a real battlefield situation, and a method and a system thereof. The live mission training device of the present invention comprises: a control module for managing a mission training; and a demonstration module for receiving virtual object data from the control module, and demonstrating an augmented reality.

Description

Technical Field [0001] The present invention relates to a live mission training apparatus, method and system using L-V-C and augmented reality,

The present invention relates to a live mission training apparatus, a method and a system through an LVC and an augmented reality, and more specifically, to a live mission training that realizes a realistic training situation by installing an augmented reality based vision apparatus .

In general, a War Game model (Constructive, C training asset), which is composed of a large number of units and organized as a unit of unit, is often used to simulate complex battlefield situations. The environment consisting of C training assets operated by simulated people in the simulated battlefield is not an independent training system but rather a training aid system to support the training of actual combatants.

On the other hand, Live (L) and Virtual (V) training assets, which are accompanied by real people, provide training environments on their own. In other words, real combatants can master the variety of skills they need in combat under real or realistic environments through L or V training assets. In order to maximize the effectiveness of the training, it is necessary to be able to perform the training similar to the battle in the actual battlefield, and to maximize the effect of the training only when the combatants performing the training recognize the actual battle situation. Therefore, through the L-V-C mission training, commanders and staffs are able to recognize the battlefield situation, command and master the actual decision-making activities, and the actual battlecruiser can practice the actual battlefield situation.

In the conventional LVC mission training, the simulator and the war game model installed on the ground are interfaced with the LVC (War Game) for large-scale actual and virtual joint training outside the country, and the multifunction vision device and the front upper vision It is being researched and operated to perform exhibition and training on the information about the planned battlefield environment and the ground in the cockpit display device such as the device.

In addition, in Korea, VV, VC, and CC concepts are excluded from the Live. Virtual missions in the Live system are implemented in the form of carrying out the mission training Is being studied.

Therefore, in order to generate more practical training effects than the L-V-C concept,

Korean Patent No. 10-1418483

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a flight control system and a control method thereof, in which virtual object data is transmitted to an airplane pilot so that a virtual object is included in the eye of an airplane pilot, Is aimed at conducting mission training in real situations.

In order to achieve the above object, a live mission training apparatus using an LVC and an augmented reality according to the present invention includes: a control module for managing mission training in a mission training based on LVC (Live Virtual Constructive); And a presentation module for receiving virtual object data from at least one of the at least one vehicle or the aircraft and displaying the augmented reality data from the control module, wherein the control module transmits virtual object data for the augmented reality, And the mission training is performed by presenting the augmented reality in the vision module.

Here, the control module may include a position receiver for receiving relative distance information and position information with respect to the vehicle or the aircraft; A data processing unit for processing the distance information and the position information to calculate a distance and a position of the vehicle or the aircraft; An augmented reality determining unit that determines the virtual object data for the augmented reality according to a command from a training manager; And a first data transmission / reception unit for transmitting the determined virtual object data to the vision module, wherein the vision module includes a position transmitter for transmitting relative distance information and position information of the vehicle or the airplane to the position receiver, ; A second data transmission / reception unit receiving the virtual object data from the first data transmission / reception unit; And an augmented reality unit for displaying the augmented reality based on the virtual object data.

Further, the control module may further include a database storing information on the mission training, and the augmented reality determining unit determines the virtual object data stored in the database with reference to the database.

The control module may further include a trainee registering unit for registering the vehicle driver who performs the mission training or the personal information of the aircraft pilot, and the personal information of the registered vehicle driver or the airline pilot is stored in the database .

In addition, the vision module may further include a training record unit for temporarily recording the results of the mission training of the vehicle driver or the aircraft pilot.

The control module may further include a performance record unit for recording and storing the training results of the vehicle driver or the airplane pilot received from the vehicle driver or the aircraft pilot recorded in the training record unit.

Further, the performance record unit is provided with a classification code according to the type of the mission training.

To achieve the above object, there is provided a method for training a live mission through an L-V-C and an augmented reality according to the present invention includes: receiving relative distance information and position information from a control module to a vehicle or an aircraft; Processing the distance information and the position information to calculate a distance and a position of the vehicle or the aircraft from the control module; Determining virtual object data for augmented reality for mission training according to a command of a training manager; Transmitting the virtual object data for the augmented reality to the vehicle or the sight-side module on the aircraft side; Receiving the virtual object data from the view module; And displaying the augmented reality using the virtual object data.

Here, the control module includes a database storing information on the mission training, and the augmented reality determining unit determines the virtual object data stored in the database with reference to the database.

Further, the control module may further include a trainee registration unit for registering the vehicle driver who performs the mission training or the personal information of the airline pilot, and the personal information of the registered driver or the airline pilot is stored in the database .

In addition, the vision module may further include a training recorder for temporarily recording a result of the training of the driver or the pilot of the aircraft.

In addition, the control module may further include a performance record unit for recording and storing the training results of the vehicle driver or the airplane pilot receiving the mission training record of the vehicle driver or the airplane pilot recorded in the training record unit.

Further, the performance record unit is provided with a classification code according to the type of the mission training.

In order to achieve the above object, a live mission training system using LVC and augmented reality according to the present invention receives distance information and location information of a vehicle or an aircraft in mission training based on LVC (Live Virtual Constructive) A control module for calculating a position where the vehicle or the airplane has departed and for transmitting the virtual object data about the augmented reality in the database to manage the mission training; And a demonstration module that is located in at least one of the vehicles or the aircraft and receives virtual object data for the augmented reality from the control module and displays the augmented reality.

The mission training according to the present invention has the following effects.

First, effective training is possible. In the live mission training according to the present invention, an augmented reality can be displayed through a module for creating a virtual object by being installed on a display inside an airplane or a helmet of an airplane pilot in a controller for managing mission training. Such augmented reality can be displayed by setting the target of the mission or the enemy number, formation, arrangement, movement, etc. in the background of the actual feature material, and thus the airplane pilot can face the situation such as the actual battle situation , It is possible to increase the efficiency of training by carrying out mission training in actual battle situations such as missile avoidance training and target striking.

Second, it can save money. In the past, mission training was carried out through dummy during air-to-air training. In other words, there was a situation in which an aircraft or a fighter equipped with an intercept pile during air-to-air training was operated to assist in the training of the aircraft to be trained. However, since the mission training according to the present invention shows the augmented reality to the pilot of the aircraft performing the mission training, the cost for the aircraft operation can be reduced because the mission training can be performed even if the additional aircraft other than the training target aircraft is not operated have.

1 is a system configuration diagram of a mission training according to an embodiment of the present invention.
2 is a block diagram of an apparatus for mission training in accordance with an embodiment of the present invention.
3 is a flowchart of a task training method according to an embodiment of the present invention.
4 is a diagram schematically showing virtual object data of an augmented reality transmitted and received to an aircraft pilot in mission training according to an embodiment of the present invention.
5 is a diagram schematically illustrating an example for displaying performance for mission training in accordance with an embodiment of the present invention.
FIG. 6 is a diagram schematically illustrating how many aircraft perform mission training according to an embodiment of the present invention.
FIG. 7 is a view schematically showing a plurality of vehicles performing mission training according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, some configurations which are not related to the gist of the present invention may be omitted or compressed, but the configurations omitted are not necessarily those not necessary in the present invention, and they may be combined by a person having ordinary skill in the art to which the present invention belongs. .

<Configuration of control module and vision module>

FIG. 1 is a system configuration diagram of a mission training according to an embodiment of the present invention, and FIG. 2 is a block diagram of a mission training apparatus according to an embodiment of the present invention.

1 and 2, a live mission training apparatus (hereinafter, referred to as 'mission training') through LVC and augmented reality according to an embodiment of the present invention includes a control module 100 and a vision module 200, .

The control module 100 manages the mission training based on the LVC (Live Virtual Constructive). The control module 100 determines virtual object data for the augmented reality in which mission training is performed on the aircraft side, and transmits object data for the augmented reality do. Such a control module 100 may be a small terminal or a huge system device. The control module 100 includes a trainer registration unit 110, a position receiving unit 120, a data processing unit 130, an augmented reality determining unit 140, a first data transmitting and receiving unit 150, a performance recording unit 160, ).

The trainer registration unit 110 registers the trainee who performs the mission training in the database 170 and registers personal information related to the trainee such as the name, key, sight, weight, rank of the trainee, . These trainers board aircraft and are trained as aircraft pilots.

Here, an aircraft refers to all the flying objects that a pilot has on board and controlled in relation to combat and material movement, and may include a variety of small fighters, helicopters, and helicopters.

The position receiver 120 receives the position information of the aircraft and determines the position of the aircraft. The position receiver 120 receives the distance information and the position information based on the GPS data transmitted from the position transmitter 210 of the vision module 200 .

The data processing unit 130 calculates a relative distance and position between the control module 100 and the aircraft through a series of predetermined processes based on the distance information and the position information received from the position transmitter 210. [

The augmented reality determining unit 140 determines the virtual object data for the augmented reality to be transmitted to the view module 200 according to a command from the training manager. The augmented reality decision unit 140 can determine various virtual object data for the training manager to perform the mission training in the database 170 by the training manager. Such virtual object data can be generated in various ways such as a posture, a position, a number of aircraft, a shape for a virtual hitting facility, and a virtual environment of a virtual aircraft with which a trainee is opposed according to a mission type.

In determining the virtual object data for the augmented reality, virtual object data for the same mission training may be determined based on the information on the existing mission training performed in the database 170, or otherwise stored in the database 170 In the case of non-mission training, the training manager may generate virtual object data directly related to the type of mission training using a separate tool, store the data in the database 170, and then determine virtual object data related to the mission training.

The first data transmission / reception unit 150 transmits / receives virtual object data to / from the second data transmission / reception unit 230 of the visualization module 200 and the training records for the mission training of the trainee. The first data transmission / reception unit 150 packetizes the virtual object data and transmits the virtual object data to the second data transmission / reception unit 230 through the data link based on the real-time communication protocol.

The performance record unit 160 is configured to receive, record, and store information on the performance of the mission training in which the trainee participates. The performance recorder 160 records the type of mission training performed by the registered trainer and the detailed records according to the training execution process individually for each trainee and also provides various statistical data to the trainee for all trainees .

The database 170 is configured to store and store virtual object data and environment information on the mission training performed by the trainee. In this database 170, newly created mission training and virtual object data therefor can be updated and stored.

The first control unit 180 controls the trainer registration unit 110 to register the trainee in the database 170 in the control module 100 and to receive the position information of the aircraft in the position receiving unit 120, Calculating a relative distance of the aircraft on the basis of the distance information and the position information received by the position receiving unit 120, determining virtual object data for the augmented reality in the augmented reality determining unit 140, The controller 150 controls the transmission and reception of the virtual object data and the training record of the trainee and the recording and storage of the training results of the trainee in the performance recorder 160.

The vision module 200 is provided in a helmet of an aircraft or an aircraft pilot to present an augmented reality so that an aircraft pilot (or a trainee) can visually confirm the augmented reality. The demonstration module 200 includes a position transmitter 210, an augmented reality receiver 220, a second data transmitter / receiver 230, a training recorder 240, and a second controller 250.

The position transmitter 210 is configured to transmit the current position of the aircraft to the position receiver 120 of the control module 100 and includes a GPS device and a gravity sensor (or gyroscope sensor) Information can be transmitted.

The augmented reality presenting unit 220 receives the virtual object data extracted from the database 170 in the augmented reality determining unit 140 according to the mission training, and displays the virtual object data to the aircraft pilot. The augmented reality presenting unit 220 generates a virtual augmented reality based on the posture, the location, the number of the aircraft, and the shape of the virtual batting facility of the virtual aircraft opposed to the trainee according to the mission type determined by the augmented reality determining unit 140 Visualize the object data so that it can be visually confirmed by the aircraft pilot.

The second data transmission / reception unit 230 transmits / receives the virtual object data and the training record of the trainee to / from the first data transmission / reception unit 150 and the augmented reality. The second data transmission / reception unit 230 packetizes the virtual object data in the same manner as the first data transmission / reception unit 150 and transmits the virtual object data to the first data transmission / reception unit 150 through the data link based on the real- can do.

The training recording unit 240 is a configuration in which the registered aircraft pilot performs the mission training and then temporarily records the training contents of the aircraft pilot for the mission training in the vision module 200. The training log 240 may include information such as the number of times the aircraft pilot hits the target during the mission training, the number of times the mission has completed various detailed missions, the number of missiles avoided by the virtual enemy, And so on.

The second control unit 250 may be configured such that the position transmitting unit 210 transmits position information on the aircraft to the position receiving unit 120 in the visualization module 200 and the virtual object data transmitted from the augmented reality visualizer 220 The second data transmission and reception unit 230 transmits and receives the first data transmission and reception unit 150 and the virtual object data and the training records of the trainee to each other, It is a configuration that controls the recording of the statistics that occurred during the flight training of the aircraft pilots.

<How to demonstrate Augmented Reality>

Hereinafter, a method of performing mission training by showing an augmented reality to an aircraft pilot will be described.

3 is a flowchart of a task training method according to an embodiment of the present invention.

3, the relative distance information and the positional information with respect to the aircraft are received at first. <S30> In the aircraft on which the registered trainee rides for the mission training, the vision module 200 is mounted on one side of the helmet of the aircraft or the trainee, And a position transmitter 210 is included in the vision module 200.

Here, the registered trainer will use the same name as the aircraft pilot after boarding the aircraft to conduct the mission training. Therefore, the trainee and the airplane occupant are considered to refer to the same person.

Accordingly, the position transmitter 210 of the vision module 200 transmits the current position information of the aircraft to the position receiver 120 of the control module 100 in the aircraft on which the aircraft pilot boarded. At this time, the distance information and the position information to be transmitted can transmit GPS data sensed by the GPS device and the gravity sensor.

Next, the relative distance and position from the control module 100 to the aircraft are calculated by processing the distance information and the position information transmitted from the position receiving unit 120. <S31> At this time, The distance information and the position information of the control module 100 are transmitted to the data processing unit 130 and the data processing unit 130 calculates the relative distance and the current position between the control module 100 and the aircraft by a predetermined series of processes. The calculation of the distance and position of the aircraft can be performed in real time in the data processing unit 130 according to the progress of the mission training.

Specifically, during the course of the mission training, the aircraft will fly on the battlefield or mission area based on the augmented reality for the purpose of the mission training. At this time, augmented reality may cause a missile to be fired from enemy aircraft toward the position where the aircraft is flying. Accordingly, the data processor 130 processes the distance information and the position information received from the position receiver 120 to calculate the current distance and position of the aircraft in real time, thereby realizing the position of the aircraft in flight, In reality, an augmented reality in which an enemy aircraft fires a missile at the position of an aircraft where mission training is conducted can be demonstrated.

Then, virtual object data for the augmented reality of the mission training is determined according to the instruction of the training manager. <S32> At this time, in the control module 100, the training manager is connected to the control module 100, And the virtual object data for the mission training that has been performed previously can be determined.

Specifically, when the augmented reality determining unit 140 determines virtual object data for the augmented reality according to a command from the training manager, the augmented reality determining unit 140 refers to the database 170 for the mission training performed in the past And determines virtual object data for the augmented reality.

The augmented reality related to the mission training is composed of a combination of virtual object data in the augmented reality view unit 220 and is composed of various virtual objects such as an enemy aircraft or a missile, Can be displayed.

In addition, for the mission training that has not been performed previously, virtual object data for a new augmented reality can be generated by using a separate tool or device for generating virtual object data for the augmented reality, Data can be stored in the database 170. [

In order to create virtual object data for this new mission training, a separate tool for creating augmented reality is used to determine the location of virtual enemy facilities, And various physical object data such as a troop deployment can be generated.

Next, the virtual object data for the determined augmented reality is transmitted to the vision module 200 on the aircraft side. <S33> At this time, the virtual object data for the augmented reality is transmitted to the first data transmission / And transmits the virtual object data to the second data transmission / reception unit 230 of the vision module 200 through the data link based on the real-time communication protocol.

The virtual object data transmitted from the first data transmitting and receiving unit 150 to the second data transmitting and receiving unit 230 is transmitted to the visual module 200. [ And moves from the inside to the augmented reality visualizer 220 again.

Finally, the virtual object data transmitted to the augmented reality view unit 220 is processed and combined by the augmented reality view unit 220 to generate a plurality of virtual The augmented reality is displayed on a display provided on the helmet of the aircraft pilot or on the front window of the aircraft, so that the pilot can visually confirm the augmented reality, and accordingly, the augmented reality using the augmented reality Can proceed.

Such a series of processes will be briefly summarized in FIG.

4 is a diagram schematically showing virtual object data of an augmented reality transmitted and received to an aircraft pilot in mission training according to an embodiment of the present invention.

4, the position receiver 120 of the control module 100 receives signals from the position transmitter 210 of the visibility module 200 provided in the aircraft or the helmet of the aircraft pilot to the aircraft from the control module 100, Receives the relative position information and the distance information, and continuously grasps the current position of the aircraft. At this time, the information transmitted by the position transmitter 210 may include the traveling direction and the current posture of the aircraft.

After the position transmitter 210 of the aircraft transmits the position of the aircraft to the position receiver 120 of the control module 100, a plurality of virtual object data for the augmented reality selected by the training manager is determined in the database 170 And transfers the virtual object data from the first data transmission / reception unit 150 to the second data transmission / reception unit 230.

Then, the virtual object data transferred is moved to the augmented reality view unit 220. In the augmented reality view unit 220, the augmented reality including the virtual object is processed by the aircraft pilot Can be seen.

<Performance Record for Mission Training>

Hereinafter, recording of the performance of the mission training after the mission training of the aircraft pilot will be described with reference to FIG.

5 is a diagram illustrating an example for displaying performance for mission training in accordance with one embodiment of the present invention.

As shown in FIG. 5, the mission training according to the present invention can be performed by presenting an augmented reality to an airplane pilot, and the performance generated in the mission training process can be stored in the performance logger 160 for each airplane pilot.

Specifically, the demonstration module 200 is provided with a training record unit 240 for temporarily recording the training contents of the aircraft pilots during the mission training process. In addition, during the mission training, various scenarios related to the mission can be set up while the aircraft pilots conduct the mission training. Accordingly, a plurality of detailed missions are set in the mission training process, and it is determined whether or not the achievement is accomplished, and the training for the mission training of the airplane pilot is recorded, and the recorded training record is stored in the second data transmission / May be transmitted through the transmission / reception unit 150 and may be classified and stored in the performance recording unit 160.

For example, suppose that an aircraft pilot has set up scenarios and goals for mission training to avoid enemy missiles and strike virtual enemy facilities. At this time, in the mission training process, detailed missions can be set as the number of times missiles fired from the enemy aircraft can be set, the number of times the target is struck at the enemy main facility can be set, Can be set, and the time spent to accomplish the mission and the ultimate success of the mission training can be recorded.

These examples are only a few examples, and you can set up various scenarios for mission training of aircraft pilots, as well as these examples, to record the achievement of goals for mission training.

In the course of the mission training, the training records of the pilots can be stored and stored in the performance log 160 for each pilots. In the performance record unit 160, training records related to the mission training can be stored for each type of mission performed by the aircraft pilot.

The types of missions can be various, such as avoiding enemy missiles, hitting enemy facilities, defending friendly facilities, and shooting down enemy missiles, and can be given classification codes for mission types from A to X (variables).

It is also possible to arrange the rank of an aircraft pilot who has performed well on the mission type for the mission type. Accordingly, the training manager can easily grasp the performance of the airplane pilots for the mission type through the performance logger 160 in the control module 100.

In addition, when entering the area of the individual aircraft pilots in the performance logger 160, it is possible to confirm the history of the plurality of mission training performed by the aircraft pilots and the rating of the performance, The administrator can grasp it.

Examples of the performance logger 160 are only examples of the present invention. The performance logger 160 can record performance on various indicators for the mission training performed by the aircraft pilots as well as the above example have.

<Many aircraft mission training progress>

FIG. 6 is a diagram schematically illustrating how many aircraft perform mission training according to an embodiment of the present invention.

As shown in FIG. 6, in the present invention, not only the virtual object data for the augmented reality is transmitted to one aircraft side in the control module 100, but also the virtual object data for the augmented reality By transmitting, it is also possible for a plurality of aircraft to carry out mission training at the same time. These missions training can be conducted in a variety of ways, such as hitting enemy airplanes or hitting the enemy's main facilities by sharing their roles among multiple pilots in the process of mission training.

For example, suppose that three friendly aircraft A, B, and C carry out mission training to hit enemy aircraft a, b, and c as shown in FIG. At this time, the friendly aircraft A is given the mission to strike the enemy aircraft a, the friendly aircraft B is given the duty to hit the enemy aircraft b, and the friendly aircraft C can be given the duty to strike the enemy aircraft c.

As a result, friendly aircraft A, B, and C were able to determine how hard they hit the enemy aircraft in battle with enemy aircraft a, b, and c, how far they missed the enemy aircraft, One can set up detailed missions to carry out mission training.

In the course of the mission training, the friendly aircraft A, B, and C can be teamed and recorded in the performance log unit 160 as a team-based mission training, and each team The administrator can grasp it.

<Progress of many vehicle mission training>

FIG. 7 is a view schematically showing a plurality of vehicles performing mission training according to an embodiment of the present invention.

As shown in FIG. 7, the mission training according to the present invention not only performs an augmented reality by showing an augmented reality to an airplane pilot, but also can perform a mission training by showing an augmented reality to a vehicle driver. Therefore, personal information of the driver of the vehicle can also be registered in the trainer registration unit 110, and the trainer can be an aircraft pilot and a vehicle driver by controlling and driving both the aircraft and the vehicle.

These vehicles refer to all weapons that can be used for combat by moving the wheels on the ground. They can include tanks, armored vehicles, trucks, missiles, and self-propelled guns.

The control module 100 is provided with a vision module 200 on one side of the vehicle so that the vehicle driver can visually confirm the augmented reality on the helmet mounted display of the vehicle driver, By displaying the augmented reality or by showing the augmented reality on the windshield, it is possible for the driver of the vehicle to perform the mission training through the augmented reality. The augmented reality demonstration method is the same as that described above for the aircraft pilot, so the same explanation will be omitted.

Also, the performance of the mission training can be recorded and stored in the performance logger 160 in the same manner for the vehicle driver. The performance records of the vehicle driver in the mission training are recorded in the training log 240 of the vision module 200 in the same manner as the vision module 200 provided on the aircraft side, And transmits the data to the first data transmission / reception unit 150 of the control module 100 through the second data transmission / reception unit 230, so that the performance of the vehicle driver can be recorded and stored in the performance recording unit 160 .

In addition, a plurality of aircraft pilots are organized in a team unit and a plurality of vehicle drivers are organized in a team unit so that a plurality of vehicle drivers can perform mission training by displaying augmented reality to a plurality of vehicle drivers.

For example, suppose that three friendly vehicles D, E, and F carry out mission training to hit enemy vehicles d, e, and f as shown in FIG. At this time, the friendly vehicle D is given the duty to hit the enemy vehicle d, the friendly vehicle E is given the duty to hit the enemy vehicle e, and the friendly vehicle F can be given the duty to hit the enemy vehicle f.

Therefore, the friendly vehicles D, E, and F have been fighting enemies d, e, and f to determine how hard they have hurtled enemy vehicles, how far they have fought from enemy vehicles, And so on, as detailed duties.

In the course of the training, the friendly vehicles D, E, and F are formed as teams and can be recorded in the performance record unit 160 as a team-based mission training. In addition, The administrator can grasp it.

In addition, a number of aircraft pilots and a large number of vehicle drivers can conduct mission training together during the mission training. Even in such a situation, if the vision module 200 is provided on each of the aircraft side and the vehicle side as described above, virtual object data for the augmented reality is transmitted from the control module 100 to each vision module 200 And it is possible to carry out the mission training by demonstrating the augmented reality.

As described above, the live mission training apparatus and the mission training method through the L-V-C and the augmented reality according to the present invention can effectively train an airplane pilot or a vehicle driver.

In the live mission training according to the present invention, an augmented reality can be displayed through a module for creating a virtual object by being installed on a display inside an airplane or a helmet of an airplane pilot in a controller for managing mission training.

Such augmented reality can be displayed by setting the target of the mission or the number of the enemy, the formation, the arrangement, the movement, and the like in the background of the actual feature material, and accordingly the airplane pilot and the vehicle driver can realize the actual battle situation By facing the situation, it is possible to increase the efficiency of training by carrying out mission training in actual battle situation such as missile avoidance training and target striking.

In addition, the cost can be reduced. In the past, mission training was carried out through dummy during air-to-air training. In other words, there was a situation in which an aircraft or a fighter equipped with an intercept pile during air-to-air training was operated to assist in the training of the aircraft to be trained.

However, since the mission training according to the present invention shows the augmented reality to the pilot of the aircraft performing the mission training, the cost for the aircraft operation can be reduced because the mission training can be performed even if the additional aircraft other than the training target aircraft is not operated have.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And additions should be considered as falling within the scope of the claims of the present invention.

100: control module
110: Register of trainees
120: Position receiver
130:
140: augmented reality decision unit
150: first data transmission /
160: Performance record
170: Database
180:
200: Visibility module
210: Position transmitter
220: Augmented Reality Visualization
230: second data transmission /
240: Training record
250:

Claims (14)

In mission training based on LVC (Live Virtual Constructive)
A control module that supervises mission training;
And a demonstration module that is located in at least one of the vehicles or the aircraft and receives virtual object data from the control module to simulate the augmented reality,
And the mission module performs the mission training by transmitting the virtual object data to the augmented reality module in the control module and displaying the augmented reality module in the view module.
The method according to claim 1,
The control module includes:
A position receiver for receiving relative distance information and position information with respect to the vehicle or the aircraft;
A data processing unit for processing the distance information and the position information to calculate a distance and a position of the vehicle or the aircraft;
An augmented reality determining unit that determines the virtual object data for the augmented reality according to a command from a training manager; And
And a first data transmission / reception unit for transmitting the determined virtual object data to the vision module,
The vision module includes:
A position transmitter for transmitting relative distance information and position information of the vehicle or the aircraft to the position receiver;
A second data transmission / reception unit receiving the virtual object data from the first data transmission / reception unit; And
And an augmented reality display unit for displaying the augmented reality based on the virtual object data.
3. The method of claim 2,
Wherein the control module further comprises a database in which information on the mission training is stored,
Wherein the augmented reality determining unit determines the virtual object data stored in the database with reference to the database.
The method of claim 3,
Wherein the control module further includes a trainee registration unit for registering the vehicle driver who performs the mission training or the personal information of the aircraft pilot,
And the personal information of the registered driver or the pilot is stored in the database.
3. The method of claim 2,
Wherein the vision module further comprises a training recorder for temporarily recording a result of the training of the driver of the vehicle or the pilot of the airplane.
6. The method of claim 5,
Wherein the control module further comprises a performance record unit for recording and storing the training results of the vehicle driver or the airplane pilot in receipt of the mission training record of the vehicle driver or the airplane pilot recorded in the training record unit. Live mission training device through Augmented Reality.
The method according to claim 6,
Wherein the performance record unit is provided with a classification code according to the type of the mission training.
Receiving relative distance information and position information from the control module to the vehicle or the aircraft;
Processing the distance information and the position information to calculate a distance and a position of the vehicle or the aircraft from the control module;
Determining virtual object data for augmented reality for mission training according to a command of a training manager;
Transmitting the virtual object data for the augmented reality to the vehicle or the sight-side module on the aircraft side;
Receiving the virtual object data from the view module; And
And displaying the augmented reality by using the virtual object data.
9. The method of claim 8,
Wherein the control module includes a database in which information on the mission training is stored,
Wherein the augmented reality determining unit determines the virtual object data stored in the database with reference to the database.
10. The method of claim 9,
Wherein the control module further includes a trainee registration unit for registering the vehicle driver who performs the mission training or the personal information of the aircraft pilot,
And the personal information of the registered driver or the airplane pilot is stored in the database.
9. The method of claim 8,
Wherein the visualization module further comprises a training recorder for temporarily recording a result of the training of the driver of the vehicle or the pilot of the airplane.
12. The method of claim 11,
Wherein the control module further comprises a performance record unit for recording and storing the training results of the vehicle driver or the airplane pilot in receipt of the mission training record of the vehicle driver or the airplane pilot recorded in the training record unit. A live mission training method through Augmented Reality.
13. The method of claim 12,
Wherein the performance record unit is provided with a classification code according to the type of the mission training.
In mission training based on LVC (Live Virtual Constructive)
A control module for receiving distance information and positional information of a vehicle or an aircraft to calculate a position where the vehicle or the airplane has departed and transmitting virtual object data about the augmented reality in a database to manage the mission training;
And a demonstration module that is located in at least one of the at least one vehicle or the aircraft and receives virtual object data of the augmented reality from the control module and displays the augmented reality. system.

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