This application claims priority from Korean Patent Application No. 10-2016-0120141, filed on Sep. 20, 2016, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein in its entirety by reference.
One or more exemplary embodiments relate to a weapon control system and a method of controlling the weapon control system, and more particularly, to a weapon control system, which may perform accurate shooting by independently controlling aiming directions of a plurality of weapons, and a method of controlling the weapon control system.
Weapon control systems are mounted on military combat vehicles, fighter planes, and warships, and are used for attack and defense against an enemy. The weapon control system is mainly used for surveillance of the surrounding area in peace and is operated to attack the enemy by using weapons during warfare.
When a combat mission is carried out at a position close to or far away from a target, the weapon control system may enable accurate shooting to the target by remotely controlling weapons without exposing a shooter, thereby effectively completing the combat mission without damage to the shooter.
A weapon control system capable of independently controlling two weapons mounted on a vehicle and performing shooting may be used to secure superiority of firepower.
Korean Patent No. 1569735 discloses a weapon control system in which a mortar launch tube and a machine gun are placed on a rotatable plate. The weapon control system has a limitation in which two weapons having different trajectories may not be used at the same time. In other words, when a rotation angle of the rotatable plate is set to have the machine gun shoot a target, it is not possible to use the mortar to shoot the target. Accordingly, the operation of the mortar is paused until the machine gun stops shooting.
U.S. Pat. No. 8,245,624 discloses a weapon control system in which two weapons are mounted and rotated by one rotation shaft. In the weapon control system, a rotation direction of a first weapon and a rotation direction of a second weapon are separately controlled to allow the first weapon and the second weapon to aim at targets, and thus, the first weapon and the second weapon may perform shooting at the same time.
However, in such a weapon control system, since the first weapon and the second weapon are placed on the same plate mounted on a vehicle, the shooting ranges of the first weapon and the second weapon overlap each other. In other words, when the first weapon and the second weapon are simultaneously aimed at the same target, a shooting range (trajectory range) of the first weapon and a shooting range of the second weapon overlap each other. Furthermore, since a horizontal shooting range of the first weapon overlaps an installation position of the second weapon or a horizontal shooting range of the second weapon overlaps an installation position of the first weapon, shooting operations of the first weapon and the second weapon are limited.
One or more exemplary embodiments of the present disclosure include a weapon control system, which may perform accurate shooting by independently controlling aiming directions of a plurality of weapons, and a method of controlling the weapon control system.
One or more exemplary embodiments include a weapon control system, which may simultaneously shoot a plurality of targets or concentrate firepower on a single target by using a plurality of weapons having different trajectories at the same time, and a method of controlling the weapon control system.
One or more exemplary embodiments include a weapon control system, which may perform efficient shooting by reducing mechanical interference and a trajectory range (shooting range) interference of a plurality of weapons, and a method of controlling the weapon control system.
Additional aspects will be set forth in part in the description which follows and, in part, will be apparent from the description, or may be learned by practice of the exemplary embodiments presented herein.
According to one or more exemplary embodiments, a weapon control system includes a base, a frame rotatably coupled to the base and rotatable around a first rotation axis, a first actuator rotating the frame with respect to the base, a first weapon rotatably coupled to the frame and rotatable around a second rotation axis in a direction crossing the first rotation axis, a second actuator rotating the first weapon with respect to the frame, a rotating support rotatably coupled to the frame and rotatable around a third rotation axis in a direction crossing the first rotation axis, a third actuator rotating the rotating support with respect to the frame, a second weapon rotatably coupled to the rotating support and rotatable around a fourth rotation axis in a direction crossing the third rotation axis, a fourth actuator rotating the second weapon with respect to the rotating support, and an actuator controller controlling the first actuator, the second actuator, the third actuator, and the fourth actuator.
The second rotation axis and the third rotation axis may be parallel with each other.
The third rotation axis may be spaced apart from the second rotation axis in an upward direction away from the base.
The first rotation axis and the fourth rotation axis may be spaced apart from each other in parallel with each other.
The first rotation axis and the fourth rotation axis may match each other.
The weapon control system may further include an imaging apparatus rotatably coupled to the frame and rotatable around a fifth rotation axis in a direction crossing the first rotation axis, and a fifth actuator rotating the imaging apparatus with respect to the frame.
The fifth rotation axis may be spaced apart from the second rotation axis in a downward direction toward the base.
The weapon control system may further include a firing controller that controls firing of the first weapon and firing of the second weapon.
The weapon control system may further include an operating computer electrically connected to the actuator controller and the firing controller and providing an angle adjustment signal to adjust a panning angle and a tilt angle of each of the first weapon and the second weapon and a firing control signal for firing of each of the first weapon and the second weapon.
The operating computer may receive target information relative to a target from at least one of a detection apparatus detecting the target, a tactical network, an artificial satellite, a radar, and an imaging apparatus of the weapon control system, and generating the angle adjustment signal and the firing control signal based on the target information.
The operating computer may perform one of a single shooting mode in which shooting is performed by selecting one of the first weapon and the second weapon as a firing weapon and an intense shooting mode in which shooting is performed by selecting both of the first weapon and the second weapon as firing weapons, and in the single shooting mode, after a trajectory direction of the firing weapon is corrected to be aligned to the target, a direction of the other one of the first weapon and the second weapon, not selected as the firing weapon, is adjusted to reduce mechanical interference in a shooting range of the firing weapon.
In the intense shooting mode, trajectory directions of the first weapon and the second weapon may be all corrected to be aligned to the target, and during shooting, shooting time points of the first weapon and the second weapon may be adjusted to be in sequence so that influence of vibrations due to shooting of the first weapon and the second weapon is reduced.
The weapon control system may further include a display connected to the operating computer and displaying an image, wherein the target information of the operating computer comprises information about a plurality of targets, and the operating computer assigns one of the first weapon and the second weapon to a first target, assigns order of priority to the plurality of targets, except for the first target, and displays the plurality of targets and information about the order of priority.
The weapon control system may further include a user input device that receives a user input and transfers a signal to the operating computer, wherein, when one of the plurality of targets, except for the first target, is selected as a second target through the user input device, the operating computer assigns the other one of the first weapon and the second weapon not assigned to the first target, to the second target, and adjusts trajectory directions of the first weapon and the second weapon.
When no signal to select one of the plurality of targets is input through the user input device, the operating computer may select one target of the plurality of targets having a top priority order, except for the first target, as the second target, assign the other one of the first weapon and the second weapon not assigned to the first target, to the second target, and adjust trajectory directions of the first weapon and the second weapon.
According to one or more embodiments, there is a method of controlling a weapon control system having a first weapon and a second weapon mounted on a frame, the frame being rotatable around a first rotation axis, the first weapon being rotatable around a second rotation axis in a direction crossing the first rotation axis, and the second weapon being rotatable around a third rotation axis in a direction crossing the first rotation axis and being rotatable around a fourth rotation axis in a direction crossing the third rotation axis, the method including aiming at a target by rotating the frame in a direction toward the target, selecting at least one of the first weapon and the second weapon as a firing weapon to shoot the target, correcting a trajectory of the firing weapon by adjusting at least one of a panning angle and a tilt angle of the firing weapon, and performing firing at the target by operating the firing weapon.
When only one of the first weapon and the second weapon is selected as the firing weapon in the selecting at least one of the first weapon and the second weapon as a firing weapon, the method may further include adjusting a direction of the other one of the first weapon and the second weapon not selected as the firing weapon, prior to the performing of firing, so that interference in a shooting range of the firing weapon is reduced.
In the aiming at the target, a first target may be aimed at among a plurality of targets. The method may further include receiving target information about positions of the plurality of targets, and assigning order of priorities to the plurality of targets based on the target information about positions of the plurality of targets.
The method may further include determining whether the plurality of targets are located within a range in which simultaneous firing at the plurality of targets by using the first weapon and the second weapon is possible.
The assigning of the order of priorities to the plurality of targets may include arranging the plurality of targets in an order of a distance, assigning weights to the plurality of targets, and generating and transferring information about the order of priorities of the plurality of targets. The method may further include displaying on a display the information about the order of priorities of the plurality of targets, and selecting a second target subject to firing along with the first target among the plurality of targets, wherein the selecting at least one of the first weapon and the second weapon as a firing weapon may include selecting one of the first weapon and the second weapon as a first firing weapon for firing at the first target, and selecting the other one of the first weapon and the second weapon as a second firing weapon for firing at the second target.
These and/or other aspects will become apparent and more readily appreciated from the following description of the exemplary embodiments, taken in conjunction with the accompanying drawings in which:
Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout. In this regard, the present exemplary embodiments may have different forms and should not be construed as being limited to the descriptions set forth herein. Accordingly, the exemplary embodiments are merely described below, by referring to the figures, to explain aspects of the present disclosure. Expressions such as “at least one of,” when preceding a list of elements, modify the entire list of elements and do not modify the individual elements of the list.
Hereinafter, the structure and operation of a weapon control system according to exemplary embodiments are described in detail with reference to the accompanying drawings.
Referring to
The base 10 may be mounted on a vehicle so that the weapon control system may be moved by the vehicle, or may be fixedly placed at a particular position. The base 10 functions as a platform supporting various constituent elements such as the first weapon 31, the second weapon 32, and an imaging apparatus 33.
The frame 20 is rotatably coupled to an upper portion of the base 10. The frame 20 may include a lower frame 21 rotatably coupled to the base 10 and rotatable around a first rotation axis C1, and a side frame 22 upwardly extending from opposite end portions of the lower frame 21.
Referring to
A first actuator 41 is coupled to the base 10 and rotates the frame 20 around the first rotation axis C1 with respect to the base 10. The first rotation axis C1 is a rotation center of the frame 20 and corresponds to a direction parallel with a Z-axis in a vertical direction in
The first actuator 41 may be implemented by, for example, an electric motor operated by an electrical signal, a hydraulic motor or hydraulic cylinder operated by oil pressure, or a pneumatic cylinder operated by air pressure.
When the first actuator 41 is implemented by an electric motor, an output shaft of the first actuator 41 is connected to the frame 20 via a decelerator and a power transfer device. In
Referring to
A middle support 24 that supports the first weapon 31 is rotatably coupled to the side frame 22 and is rotatable around a second rotation axis C2 perpendicularly crossing the first rotation axis C1. Since the first weapon 31 is fixed to the middle support 24 by a coupling device such as a bolt or a bracket, the first weapon 31 may rotate with the middle support 24 around the second rotation axis C2. The second rotation axis C2 may be in a direction perpendicularly crossing the first rotation axis C1 and may be parallel with a horizontal X-axis direction in
Although in
The second actuator 42 that rotates the first weapon 31 and the middle support 24 is coupled to the side frame 22. Since an output shaft of the second actuator 42 is coupled to an end portion of the middle support 24 by penetrating through the side frame 22, when the output shaft of the second actuator 42 rotates, the middle support 24 may be rotated around the second rotation axis C2.
As the first weapon 31 rotates around the second rotation axis C2, angles in a vertical direction of the first weapon 31 may be adjusted when the first weapon 31 aims at a target.
The second weapon 32 is coupled to the frame 20 and is rotatable around a third rotation axis C3 that is in a direction crossing the first rotation axis C1. Referring to
The third rotation axis C3 may be in a direction perpendicularly crossing the first rotation axis C1, and since the third rotation axis C3 is parallel with the horizontal X-axis direction of
As such, as the second rotation axis C2 and the third rotation axis C3 are spaced apart from each other in an upward direction from the base 10, a space for adjustment of the angle in the vertical direction of the first weapon 31 and the second weapon 32 with respect to the frame 20 may be secured.
The third actuator 43 that rotates the second weapon 32 and the rotating support 23 is coupled to the side frame 22. Since an output shaft of the third actuator 43 is coupled to an end portion of the rotating support 23 by penetrating through the side frame 22, when the output shaft of the third actuator 43 rotates, the rotating support 23 and the second weapon 32 may rotate around the third rotation axis C3.
Referring to
The rotating bracket 26r is rotatably coupled to a rotating guide 23g of the rotating support 23 and is rotatable around the fourth rotation axis C4 with respect to the rotating support 23. The rotating guide 23g is formed on the rotating support 23, extending in an arc shape around the fourth rotation axis C4, and has a function of supporting the rotating bracket 26r that is rotatable around the fourth rotation axis C4. Accordingly, when the rotating bracket 26r rotates with respect to the rotating support 23, the second weapon 32 performs a rotation motion with the rotating bracket 26r around the fourth rotation axis C4 with respect to the rotating support 23.
A fourth actuator 44 is coupled to the rotating support 23 and rotates the rotating bracket 26r around the fourth rotation axis C4 with respect to the rotating support 23. The fourth rotation axis C4, which is a rotation center of the rotating bracket 26r and the second weapon 32, is parallel with a Z-axis that is the vertical direction in
The fourth actuator 44 may be implemented by, for example, an electric motor operated by an electrical signal, a hydraulic motor or hydraulic cylinder operated by oil pressure, or a pneumatic cylinder operated by air pressure.
When the fourth actuator 44 is implemented by an electric motor, an output shaft of the fourth actuator 44 is connected to the rotating bracket 26r via a decelerator and a power transfer device. In
Since the power of the fourth actuator 44 is transferred to a gear 26g of the rotating bracket 26r via the gear 44g, as the fourth actuator 44 operates, the rotating bracket 26r and the second weapon 32 perform a rotation motion with respect to the rotating support 23.
The imaging apparatus 33 is rotatably coupled to the side frame 22 at a position under the first weapon 31 with respect to the side frame 22. The imaging apparatus 33 is supported by the imaging apparatus support 25, and the imaging apparatus support 25 is rotatably coupled to the side frame 22. Accordingly, the imaging apparatus 33 and the imaging apparatus support 25 may rotate around a fifth rotation axis C5 which is in a direction crossing the first rotation axis C1.
The fifth actuator 45 is coupled to the side frame 22 and rotates the imaging apparatus 33. The fifth rotation axis C5 may be in a direction perpendicularly crossing the first rotation axis C1 and parallel with the second rotation axis C2 and the third rotation axis C3. Furthermore, the fifth rotation axis C5 is spaced apart from the second rotation axis C2 in a downward direction toward the base 10.
Furthermore, the imaging apparatus 33 is rotatable in the horizontal direction with respect to an axis parallel with the first rotation axis C1 with respect to the imaging apparatus support 25. A sixth actuator 46 that rotates the imaging apparatus 33 in the horizontal direction is coupled to the imaging apparatus support 25.
Referring to
The controller 70 may include a firing controller 71 connected to each of the first weapon 31 and the second weapon 32 and controlling firing of the first weapon 31 and the second weapon 32; an actuator controller 72 controlling each of the actuators 41, 42, 43, and 44; an image processor 73 connected to and controlling the imaging apparatus 33, and processing an image; and an input/output controller 74 controlling input and output signals. The firing controller 71 may include a first firing controller 71a controlling firing of the first weapon 31, and a second firing controller 71b controlling firing of the second weapon 32.
The controller 70 may be implemented by a control computer installed in a weapon control system or a vehicle mounted with the weapon control system, a circuit board included in a computer, a semiconductor chip mounted on a circuit board, or control software included in a semiconductor chip or a computer.
The actuator controller 72 may include a first driver 72a, a second driver 72b, a third driver 72c, a fourth driver 72d, and a fifth driver 72e for respectively controlling the first actuator 41, the second actuator 42, the third actuator 43, the fourth actuator 44, and the fifth actuator 45. Each of the actuators may be equipped with an encoder for detecting the position of a drive shaft, and a signal of each encoder may be transferred to each of the drivers connected to each actuator.
The weapon control system may include an operating computer 81 that is electrically connected to the firing controller 71 and the actuator controller 72 of the controller 70. The operating computer 81 may supply an angle adjustment signal to adjust a panning angle (azimuth angle) and tilt angle (elevation angle) of each of the first weapon 31 and the second weapon 32, and a firing control signal to control firing of each of the first weapon 31 and the second weapon 32.
The operating computer 81 is mounted on the base 10 of the weapon control system or on a vehicle mounted with the weapon control system, and is connected to the controller 70 by a wired communication method. Alternatively, the operating computer 81 is mounted at a position far from the vehicle and the base 10 of the weapon control system and remotely controls the angle adjustment operation and firing of the first weapon 31 and the second weapon 32, and the photographing operation of the imaging apparatus 33 in the weapon control system.
The weapon control system may include a display 82 electrically connected to the operating computer 81 and displaying an image. The display 82 may display information about a target to be hit by the weapon control system, that is, information about a position or distance of a target, or information about the order of priority for firing at targets during firing. Furthermore, the display 82 may display information about a panning angle and a tilt angle of the first weapon 31 and the second weapon 32.
Furthermore, the display 82 may be implemented by a touch screen so that a user may select or input a menu or information by touching a surface thereof. A user of the weapon control system may check the information displayed on the display 82 and select targets displayed on the display 82.
The weapon control system may include a user input device 83 that is electrically connected to the operating computer 81, and may receive a user's input operation and transfer a signal of the user's input operation to the operating computer 81. The user input device 83 may be a joystick, a mouse, a keyboard, or a combination thereof.
The operating computer 81 may be connected to an information network 86 that includes a radar information processor 84 and a global positioning system (GPS) information processor 85. The radar information processor 84 receives information from a radar device and transfers the information to the operating computer 81. The GPS information processor 85 receives geographical position information from GPS satellites and transfers the geographical position information to the operating computer 81.
Referring to
In the weapon control system according to the embodiment illustrated in
Furthermore, although in the weapon control system of
Referring to
The operating computer 81 is connected to a tactical network 110, a detection apparatus 140 detecting a target, an artificial satellite 120 providing GPS information, a radar 130, and the imaging apparatus 33 of the weapon control system mounted on the combat vehicles 101, 102, 103, and 104, so as to be capable of communicating with one another by a tactical data link system.
The operating computer 81 may receive target information related to a target from at least one of the detection apparatus 140, the tactical network 110, the artificial satellite 120, the radar 130, and the imaging apparatus 33 of the weapon control system. The target information that the operating computer 81 receives may include locational information about the positions of a plurality of targets, locational information of the combat vehicles 101, 102, 103, and 104, distance information, climate information, and information related to tactics to hit targets.
The operating computer 81 may generate an angle adjustment signal to adjust angles of weapons of the combat vehicles 101, 102, 103, and 104 and a firing control signal to instruct firing of weapons, based on the target information, and transfer the signals to the combat vehicles 101, 102, 103, and 104.
The operating computer 81 may select and perform any one of a single shooting mode and an intense shooting mode to perform firing by using the weapon control systems of the combat vehicles 101, 102, 103, and 104.
The single shooting mode is a mode of performing shooting by selecting, as a firing weapon, any one of the first weapon and the second weapon of the weapon control system mounted on each of the combat vehicles 101, 102, 103, and 104. The “firing weapon” is a term referring to a weapon selected to perform firing at the target. For example, when the first weapon is selected as a firing weapon in the single shooting mode, the second weapon may be controlled to halt shooting while the first weapon performs a firing motion.
The intense shooting mode is a mode of performing shooting by selecting, as firing weapons, both of the first weapon and the second weapon of the weapon control system mounted on each of the combat vehicles 101, 102, 103, and 104.
In the single shooting mode in which the first weapon is selected as a firing weapon, after a mark (target) is aimed at by rotating the frame of the weapon control system (S100), the first weapon is selected as a firing weapon (S110). Then, a trajectory of the first weapon selected as the firing weapon is corrected by adjusting at least one of a panning angle and a tilt angle of the first weapon (S120). In the correcting of the trajectory of the first weapon (S120), the trajectory of the first weapon is corrected to increase accuracy of firing in consideration of the position of a target and a trajectory range of the first weapon.
Simultaneously with or after the correcting of the trajectory of the first weapon (S120), interference of the second weapon is corrected (S130). After the correcting of the interference of the second weapon, firing of the first weapon is performed (S140).
As illustrated in
In the single shooting mode in which the second weapon is selected as a firing weapon, after a mark (target) is aimed at by rotating the frame of the weapon control system (S200), the second weapon is selected as the firing weapon (S210). Then, a trajectory of the second weapon selected as the firing weapon is corrected by adjusting at least one of a panning angle and a tilt angle of the second weapon (S220). In the correcting of the trajectory of the second weapon (S220), the trajectory of the second weapon is corrected to increase accuracy of firing in consideration of the position of a target and a trajectory range of the second weapon.
Simultaneously with or after the correcting of the trajectory of the second weapon (S220), interference by the first weapon is corrected (S230). After the correcting of the interference by the first weapon, firing of the second weapon is performed (S240).
As illustrated in
In the intense shooting mode, after a mark (target) is aimed at by rotating the frame of the weapon control system (S300), both of the first and second weapons are selected as firing weapons (S310). Then, a trajectory of each of the first and second weapons selected as firing weapons is corrected by adjusting at least one of a panning angle and a tilt angle of each of the first and second weapons selected as the firing weapons (S320). In the correcting of the trajectories of the first and second weapons (S320), the trajectory of each of the first and second weapons is corrected to increase accuracy of firing in consideration of the position of a target and a trajectory range of the first weapon and the position of a target and a trajectory range of the second weapon.
After the correcting of the trajectories of the first and second weapons (S320), each of the first and second weapons is fired (S330). As such, when shooting is performed by both the first and second weapons, the goal of shooting may be surely achieved because firing power of the first and second weapons may be concentrated on a single target.
In the firing of each of the first and second weapons (S330), in order to reduce influence of vibration generated by the firing operation of each of the first weapon and the second weapon, shooting time points of the first weapon and the second weapon may be adjusted to be in sequence so that the shooting of the first weapon and the shooting of the second weapon may be sequentially performed.
For example, although the first weapon and the second weapon may be simultaneously fired, when the first weapon and the second weapon perform shooting at the same time, vibration generated by the firing of the first weapon may have a significant influence on the second weapon due to mechanical properties of the weapon control system. Accordingly, to reduce the influence of the vibration between the first weapon and the second weapon, the first weapon is primarily operated to perform shooting and, when the vibration due to the firing of the first weapon stops after the shooting of the first weapon ends, the second weapon may be operated to perform shooting.
Referring to
A firing weapon selection operation in which a firing weapon is selected may be performed before the aiming operation (S400), simultaneously with the aiming operation (S400), or after the aiming operation (S400). The firing weapon selection operation may include selecting one of the first weapon and the second weapon as a first firing weapon to fire at a first target and selecting the other one of the first weapon and the second weapon as a second firing weapon to fire at a second target.
Although in the above description the first weapon is selected as the first firing weapon and the second weapon is selected as the second firing weapon, the present disclosure is not limited thereto, and the second weapon may be selected as the first firing weapon and the first weapon may be selected as the second firing weapon. The selection of the first firing weapon and the second firing weapon may be automatically performed by the weapon control system or manually performed by the user.
After or simultaneous with the aiming operation (S400), an information receiving operation (S410) in which the weapon control system receives target information related to the position of a target from at least one of a detection apparatus, a tactical network, an artificial satellite, a radar, and an imaging apparatus of the weapon control system is performed.
After the information receiving operation S410, a priority order assigning operation (S420) is performed in which the operating computer assigns the order of priority to each of a plurality of targets based on the target information.
Referring to
The firing range determination operation (S421) may be performed independent of the priority order assigning operation (S420). In other words, the priority order assigning operation (S420) may be performed or may not be performed based on a result of the firing range determination operation (S421).
When no target on which simultaneous firing by the first weapon and the second weapon is possible is determined to be present in the firing range determination operation (S421), the targets are not assigned with an order of priority and the process ends. However, when there are targets on which simultaneous firing by the first weapon and the second weapon is possible, an arrangement operation (S422) in which input targets are arranged in an order of a distance, a weight assigning operation (S423) in which weights are assigned to the targets, a rearrangement operation (S424) in which the targets are rearranged based on the assigned weights, and an information transfer operation (S425) in which information about the order of priority of the targets is generated and transferred, are performed.
As an example of the weight addition operation (S423), weights may be assigned to targets subject to the top priority firing by combining tactical command information and information about distances of the targets received from the tactical network.
As another example of the weight addition operation (S423), a high weight may be assigned to a target located in a range in which trajectory ranges of the first weapon and the second weapon do not overlap with each other when the first weapon and the second weapon simultaneously perform firing, considering the trajectory ranges of the first weapon and the second weapon.
As another example of the weight addition operation (S423), weights may be assigned to targets in an order of a high hit rate of firing considering the size or distribution of the targets.
As another example of the weight addition operation (S423), when the tactical network information (453) includes a command to assign the top priority order of a target, the target having the top priority order may be assigned the highest weight.
Referring to
Referring to
The information about the priority order of the targets 7, 3, 4, and 5 may be indicated by, for example, images or signs such as numbers, characters, or arrows. The information about the priority order of the targets 7, 3, 4, and 5 may be indicated by changing the color of the small circles indicating the positions of the targets 7, 3, 4, and 5, or by changing the thickness or type of line.
In
For example, the second weapon is set to rotate with a panning angle of up to 21° to the left and right from the center. However, since the maximum launch angle of the second weapon in the horizontal direction is 3°, the angular range in the horizontal direction to set the targets 3 and 4 subject to firing by the second weapon is set to be 18°, considering the maximum launch angle of the second weapon in the horizontal direction.
Referring to
In the input receiving operation (S440), a user's input operation to select a second target may be received. For example, when the user selects the target 3 located to the right of the first target 7 in
When no user input operation for selecting the second target is received, an automatic selection operation (S460) may be performed in which a target having the top priority order among the targets 3, 4, and 5 assigned with the order of priorities is selected as the second target.
After the second target is set, a trajectory correction operation (S450) is performed in which a trajectory direction of the first weapon is corrected by adjusting the panning angle and the tilt angle of the first weapon to have the first weapon aligned to the first target 7, and a trajectory direction of the second weapon is corrected by adjusting the panning angle and the tilt angle of the second weapon to have the second weapon aligned to the second target 3.
After the trajectory correction operation (S450), a firing operation (S470) is performed in which firing is performed with the first and second weapons. In the firing operation (S470), the first and second weapons may simultaneously perform firing, or the first and second weapons may sequentially perform firing with a time interval between the respective firings considering the interference on the trajectory range between the first and second weapons or a negative influence of vibration between the first and second weapons.
According to the above-described weapon control system configured as above, shooting may be performed by selecting any one of the first and second weapons or by simultaneously selecting both of the first and second weapons. Furthermore, when shooting is performed by simultaneously using both of the first and second weapons, targets subject to firing may be freely selected and, since influence due to the interference or vibration between the first and second weapons may be reduced, the weapon control system may be easily used, and effectiveness and accuracy of shooting may be improved simultaneously.
As described above, in the weapon control systems according to the above-described exemplary embodiments, shooting may be performed by selecting any one of the first and second weapons or by simultaneously using the first and second weapons having different trajectory ranges or the same trajectory range.
Furthermore, since a panning angle and a tilt angle of each of the first and second weapons are independently controlled and adjustment ranges of the panning angles of the first and second weapons do not interfere with each other, targets subject to firing may be freely selected when shooting is performed by using the first and second weapons simultaneously.
In addition, since information about the order of priority of targets that may be selected is provided by analyzing detected targets, effective and accurate shooting may be performed even when the weapon control system is remotely controlled.
It should be understood that the exemplary embodiments described herein should be considered in a descriptive sense only and not for purposes of limitation. Descriptions of features or aspects within each embodiment should typically be considered as available for other similar features or aspects in other embodiments.
While one or more exemplary embodiments have been described with reference to the figures, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope as defined by the following claims.
Number | Date | Country | Kind |
---|---|---|---|
10-2016-0120141 | Sep 2016 | KR | national |
Number | Name | Date | Kind |
---|---|---|---|
4282794 | Miller | Aug 1981 | A |
5682006 | Perry et al. | Oct 1997 | A |
6769347 | Quinn | Aug 2004 | B1 |
7669513 | Niv et al. | Mar 2010 | B2 |
8245624 | Green | Aug 2012 | B1 |
20010015126 | Grunewald | Aug 2001 | A1 |
20040050240 | Greene | Mar 2004 | A1 |
20120247317 | Karakookly | Oct 2012 | A1 |
20140116234 | Jacq | May 2014 | A1 |
Number | Date | Country |
---|---|---|
100576296 | May 2006 | KR |
101386643 | Apr 2014 | KR |
101569735 | Nov 2015 | KR |
Number | Date | Country | |
---|---|---|---|
20180080739 A1 | Mar 2018 | US |