KR102127962B1 - Pan-tilt-gimbal integrated system and control method thereof - Google Patents

Abstract

Disclosed is a pan-tilt-integrated system. The pan-tilt-integrated system according to an embodiment includes: a rotation module installed on a moving body and rotating a camera mounted on one side in at least two axes; A sensor unit for measuring yaw and pitch direction shaking of the moving body; An input unit to which a command for adjusting the photographing angle of the camera is input; And a control unit that controls the operation of the rotation module, and the control unit rotates the rotation module in a direction opposite to the motion of the moving object measured by the sensor unit so that the yaw and pitch directions of the camera are corrected. When the rotation command of the camera is input to the input unit, the controller rotates the rotation module according to the input command, and may be controlled to interlock with the camera shake correction control.

Description

PAN-TILT-GIMBAL INTEGRATED SYSTEM AND CONTROL METHOD THEREOF}

The following embodiment relates to a pan-tilt-integrated system and a control method thereof.

Recently, there is an increasing need for unmanned cameras in difficult-to-reach environments or in situations where it is difficult to continuously reside. Unmanned cameras are mounted on moving objects such as ships, vehicles, airplanes, or ground robots, and are used for various purposes such as video shooting, reconnaissance, and surveillance, and the range is gradually expanding. In order to adjust the shooting angle of the unmanned camera, the unmanned camera is mounted on a pan and tiltable pan tilt module. On the other hand, even when the moving object is shaken according to a change in the external environment or a movement situation, the camera must be kept horizontal for stable image shooting. For example, an unmanned camera installed on a ship must be leveled in real time in order to stably shoot an image even when the ship is shaken by waves. To this end, a gimbal module that compensates for the shaking of the moving object is used. Conventionally, the pan tilt module and the gimbal module have been configured as separate modules from each other. That is, the pan-tilt module for panning or tilting the camera, and the gimbal module for correcting the horizontality of the camera were configured as separate modules. However, using the pan-tilt module and the gimbal module as separate modules causes waste of space and cost, and the control method also has an inefficient aspect. Accordingly, there is a need for a pan-tilt-gimbal integrated system in which the pan-tilt module and the gimbal module are integrally formed, and a control method for controlling such an integrated system is required.

An object of one embodiment is to provide a pan-tilt-gimbal-integrated system in which the pan-tilt module and the gimbal module are integrally formed.

The purpose of one embodiment is to provide a control method for efficiently controlling a pan-tilt-integrated system.

The pan-tilt-integrated system according to an embodiment includes: a rotation module installed on a moving body and rotating a camera mounted on one side in at least two axes; A sensor unit for measuring yaw and pitch direction shaking of the moving body; An input unit to which a command for adjusting the photographing angle of the camera is input; And a control unit that controls the operation of the rotation module, and the control unit rotates the rotation module in a direction opposite to the motion of the moving object measured by the sensor unit so that the yaw and pitch directions of the camera are corrected. When the rotation command of the camera is input to the input unit, the controller rotates the rotation module according to the input command, and may be controlled to interlock with the camera shake correction control.

When a command for rotating the camera in one direction is input to the input unit, the control unit rotates the rotation module in the one direction, but does not perform shake correction for the one direction of the camera while the rotation module rotates in the one direction. Control.

When the panning command of the camera is input to the input unit, the control unit may pan the rotation module, while controlling the yaw direction shake correction of the camera while the rotation module is panning.

When the tilting command of the camera is input to the input unit, the controller may control the tilting of the rotation module so that the camera does not perform the pitch direction shake correction while the rotation module is tilting.

When a command for rotating the camera in one direction by an input angle is input to the input unit, the control unit moves the rotating module in the one direction until the camera follows the position rotated by the input angle in the one direction from the current position. While rotating, the rotation module may be controlled so as not to perform shake correction in the one direction of the camera while the rotation module rotates in one direction.

When a command for rotating the camera to the input position is input to the input unit, the controller may rotate the rotation module so that the camera follows the input position while performing the camera shake correction.

When a command for rotating the camera to the input position is input to the input unit, the controller may reset the reference position for the camera shake correction to the input position.

The controller may reset the reference position for the shake correction of the camera to the current position of the camera when the shooting angle adjustment of the camera is completed.

The rotation module is rotatable in a three-axis direction, the sensor unit measures yaw, pitch and roll direction shaking of the moving object, and the control unit is configured to correct the yaw, pitch and roll direction shaking of the camera, in the sensor unit The rotating module is rotated in a direction opposite to the measured shaking of the moving body, and the control unit can control the camera to continuously perform the rolling direction shaking correction.

The sensor unit may include at least one or more of a gyro sensor, an acceleration sensor, and a geomagnetic sensor.

The pan-tilt-integrated system control method according to an embodiment is installed on a moving body and rotates the camera in at least two-axis directions with respect to the moving body so that yaw and pitch direction shake of the camera mounted on one side is corrected. Providing a module; Inputting a command to rotate the camera in one direction; Rotating the rotating module in the one direction; And while the rotation module rotates in the one direction, controlling the camera to not perform shake correction for the one direction.

The pan-tilt-integrated system control method according to an embodiment is installed on a moving body and rotates the camera in at least two-axis directions with respect to the moving body so that yaw and pitch direction shake of the camera mounted on one side is corrected. Providing a module; Inputting a command to rotate the camera by an input angle in one direction; Rotating the rotation module in the one direction until the camera follows the position rotated by the input angle in the one direction from the current position; And while the rotation module rotates in the one direction, controlling the camera to not perform shake correction for the one direction.

When the rotation of the camera according to the input command is completed, the reference position for the camera shake correction may be reset to the current position of the camera.

The pan-tilt-integrated system and a control method thereof according to an embodiment may implement both a pan-tilt function and a gimbal function with a single rotation module.

The pan-tilt-integrated system and its control method according to an embodiment may simplify the control process by controlling the pan-tilt function and the gimbal function in cooperation with each other.

The effects of the pan-tilt-integrated system and its control method according to an embodiment are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

The following drawings attached to this specification are intended to illustrate one preferred embodiment of the present invention, and to serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, the present invention is only described in those drawings It should not be construed limitedly.
1 is a schematic diagram of a pan-tilt-integrated system according to an embodiment.
2 is a flowchart of a method of controlling a pan-tilt-integrated system according to an embodiment.
3 is a flowchart of a method of controlling a pan-tilt-integrated system according to an embodiment.

Hereinafter, embodiments will be described in detail through exemplary drawings. It should be noted that in adding reference numerals to the components of each drawing, the same components have the same reference numerals as possible even though they are displayed on different drawings. In addition, in describing an embodiment, when it is determined that a detailed description of a related known configuration or function interferes with understanding of the embodiment, the detailed description is omitted.

Further, in describing the components of the embodiment, terms such as first, second, A, B, (a), (b), and the like can be used. These terms are only for distinguishing the component from other components, and the nature, order, or order of the component is not limited by the term. When a component is described as being "connected", "coupled" or "connected" to another component, the component may be directly connected to or connected to the other component, but another component between each component It should be understood that may be "connected", "coupled" or "connected".

Components included in any one embodiment and components including common functions will be described using the same name in other embodiments. Unless there is an objection to the contrary, the description described in any one embodiment may be applied to other embodiments, and a detailed description will be omitted in the overlapped range.

1 is a schematic diagram of a pan-tilt-integrated system according to an embodiment.

Referring to FIG. 1, the pan-tilt-integrated system 1 may be installed on a moving body M. The pan-tilt-integrated system 1 can be used to control the camera C installed on the moving body M. The moving body M may mean a ship, airplane, vehicle, robot, or drone. The pan-tilt-integrated system 1 can rotate the camera C in a desired direction and angle in order to adjust the shooting angle of the camera C. For example, the pan-tilt-integrated system 1 can pan or tilt the camera C. In addition, the pan-tilt-integrated system 1 can implement a gimbal function for correcting the shaking of the camera C. That is, the pan-tilt-integrated system 1 prevents the shaking of the camera C due to the shaking of the moving body M so that the camera C can stably shoot the image even when the moving body M is shaking. It can be corrected in real time. The pan-tilt-integrated system 1 can perform both the pan-tilt function and the gimbal function with one rotating module 10. In addition, the pan-tilt-integrated system 1 can control the pan-tilt function and the gimbal function in cooperation with each other. For example, a part of the gimbal function may not be performed while the camera C is panned/tilted. Alternatively, in some cases, the panning/tilting of the camera C and the gimbal function may be performed simultaneously. According to this configuration, since both the pan tilt function and the gimbal function can be implemented with one rotating module 10, space and cost can be saved, and the control process can be simplified. The pan-tilt-integrated system 1 may include a rotation module 10, an input unit 11, a sensor unit 12, and a control unit 13.

The rotating module 10 may be installed on the moving body M. A camera C may be mounted on one side of the rotation module 10. The rotation module 10 may rotate the camera C in a two-axis or three-axis direction with respect to the moving body M. To this end, the rotation module 10 may include a driving unit rotatable in two or three axis directions. The camera C mounted on the rotation module 10 may include a general camera, a cam, a CCTV, a thermal imaging camera, and an infrared camera. For example, a daytime camera may be connected to one side of the rotation module 10 and a nighttime camera may be connected to the other side.

The rotation module 10 may pan or tilt the mounted camera C. Based on the coordinate system shown in FIG. 1, panning means rotation about the z-axis direction, and tilting means rotation about the y-axis direction. That is, panning may mean rotation in the left and right directions, and tilting may mean rotation in the up and down directions. The rotation module 10 may rotate in the z-axis direction to pan the camera C. Also, the rotation module 10 may rotate in the y-axis direction to tilt the camera C. By panning and tilting the camera C through the rotation of the rotation module 10, the shooting angle of the camera C can be adjusted. On the other hand, when the rotation module 10 is rotatable in the 3-axis direction, the rotation module 10 may roll the camera C. Rolling means rotation about the x-axis direction. The rotation module 10 may rotate the x-axis direction to roll the camera C.

The rotation module 10 may correct the shaking of the camera C with respect to the moving body M so that the camera C can remain horizontal even if shaking occurs as the moving body M moves. That is, the rotation module 10 may function as a 2-axis or 3-axis gimbal. For example, when the rotation module 10 is driven in the three-axis direction, the rotation module 10 may correct the yaw, pitch, or roll direction shaking of the camera C. . That is, the rotation module 10 may rotate so that yaw, pitch, or roll direction shake of the camera C according to the shake of the moving body M is corrected. According to such a configuration, the rotation module 10 corrects the shaking of the moving body M, so that the camera C can provide a shooting screen without shaking. On the other hand, based on the coordinate system shown in FIG. 1, yaw means rotation about the z-axis direction, pitch means rotation about the y-axis direction, and roll means rotation about the x-axis direction. That is, yaw corresponds to panning, pitch corresponds to tilting, and rolls corresponds to rolling.

A command for adjusting the photographing angle of the camera C may be input to the input unit 11. The photographing angle of the camera C may mean a position of the camera C, an angle of rotation, and the like. The user may input a command to the input unit 11 to adjust the position, rotation angle, etc. of the camera C. The input unit 11 may be formed in various forms, such as a joystick, keyboard, and button. A rotation direction and/or rotation angle of the camera C may be input to the input unit 11. For example, when the input unit 11 is a joystick, the rotation direction of the camera C may be input to the input unit 11. Alternatively, when the input unit 11 is a keyboard, a rotation direction and/or a rotation angle of the camera C may be input to the input unit 11. The command input to the input unit 11 may be transmitted to the control unit 13.

The sensor unit 12 may measure yaw, pitch, or roll direction shaking of the moving body M. That is, the sensor unit 12 may measure how much the camera C is shaken in the yaw, pitch or roll direction as the moving body M shakes. The sensor unit 12 may include at least one or more of a gyro sensor, an acceleration sensor, and a geomagnetic sensor. The sensor unit 12 may measure the inclined direction, angle, angular velocity, and the like of the moving body M using the sensor. Measurement values measured by the sensor unit 12 may be transmitted to the control unit 13. Meanwhile, the pan-tilt-integrated system according to an embodiment may further include an encoder that measures a rotation angle and a rotation speed of the rotation module.

The control unit 13 may control the operation of the rotation module 10. The control unit 13 may pan or tilt the rotation module 10 so that the rotation module 10 functions as a pan tilt module. That is, the control unit 13 may rotate the rotation module 10 in the z-axis or y-axis direction so that the camera C is panned or tilted. In addition, the control unit 13 may rotate the rotation module 10 so that the rotation module 10 functions as a gimbal module. That is, the control unit 13 may rotate the rotation module 10 in the biaxial or triaxial direction so that the yaw, pitch, or roll direction shaking of the camera C according to the shaking of the moving body M is corrected. For example, the control unit 13 may correct the shaking of the camera C by rotating the rotating module 10 in a direction and angle opposite to the shaking of the moving body M measured by the sensor unit 12. . The reference position for camera shake correction of the camera C may refer to an absolute reference position. The controller 13 may control the rotation operation of the rotation module 10 so that the shake correction of the camera C is continuously performed unless there is a separate command through the input unit 11.

The controller 13 may receive a command input from the input unit 11. When a rotation command of the camera C is input to the input unit 11, the control unit 13 may control rotation of the rotation module 10 in conjunction with the shake correction of the camera C according to the input command. That is, the controller 13 rotates the rotation module 10 according to the input command, but can control the rotation of the rotation module 10 to interlock with the shake correction control of the camera C. The interlocking control of the control unit 13 will be described for each case below.

Hereinafter, the interlocking control when the command to rotate the camera C in a specific direction is input will be described.

A command for rotating the camera C in a specific direction may be input to the input unit 11. For example, the input unit 11 is a joystick, and the user can input a rotation direction of the target camera C using the joystick. It can be understood that only the information on the rotation direction of the camera C is input to the input unit 11. When the above command is input, the control unit 13 may rotate the rotation module 10 in the input direction. In addition, while the rotation module 10 rotates in the direction input according to the user's command, the control unit 13 does not perform shake correction of the camera C in the same direction as the rotation module 10 input direction. Control. That is, the controller 13 may control the camera module C to not perform the shake correction for the one direction while the rotation module 10 rotates in one direction according to a user's command. If only the command for the rotation direction of the camera C is input, it is more efficient to rotate the camera C in the input direction, so it is more efficient for the rotation module 10 not to perform shake correction for the input direction. Can. While the rotation module 10 rotates according to a command, by stopping the shake correction for the same direction, the correction process can be simplified from three-axis correction to two-axis correction or from two-axis correction to one-axis correction. In addition, since unnecessary rotation of the rotating module 10 can be prevented, it may help to increase the life of the rotating module 10.

For example, when a panning command of the camera C is input to the input unit 11, the control unit 13 pans the rotation module 10 (rotates in the z-axis direction), and the rotation module 10 pans In the meantime, it is possible to control the rotation module 10 not to perform the shake correction for the yaw direction. However, even when the rotation module 10 is panned, the correction for the pitch or roll direction shake of the camera C may be controlled to be continuously performed. The same can be applied to tilting. When a tilt command of the camera C is input to the input unit 11, the control unit 13 tilts the rotation module 10 (rotates in the y-axis direction), and while the rotation module 10 tilts, the rotation module ( 10) It is possible to control not to perform the shake correction for the pitch direction. However, even when the rotation module 10 is tilted, correction for yaw or roll direction shaking of the camera C may be controlled to be continuously performed.

On the other hand, when a command to end the rotation of the camera (C) is input, the controller 13 ends the rotation operation of the rotation module 10, so that the rotation module 10 again performs shake correction in all directions Can be controlled. In this case, the reference position for camera shake correction of the camera C may be reset to the current position of the camera C. That is, when the control of the photographing angle of the camera C according to the user's command is completed, the controller 13 may reset the reference position for the camera C to shake correction to the current position of the camera C.

Hereinafter, interlocking control when a command for rotating the camera C by a specific angle in a specific direction is input will be described.

A command for rotating the camera C by a specific angle in a specific direction may be input to the input unit 11. For example, the input unit 11 is a keyboard, and the user can input a rotation direction and rotation angle of the target camera C using the keyboard. It can be understood that information on the rotation direction and rotation angle of the camera C is inputted to the input unit 11 together. When the above command is input, the controller 13 may rotate the rotation module 10 so that the camera C follows the position rotated by the angle input in the direction input from the current position. In addition, while the rotation module 10 rotates in the direction in which the rotation module 10 is input according to a user's command, the control unit 13 may control the rotation module 10 not to perform shake correction of the camera C in the input direction. Can. When a command for the rotation direction and rotation angle of the camera C is input, the purpose is to rotate the camera C in the direction and angle input from the current position, so that the rotation module 10 shakes against the input direction It may be more efficient to avoid performing corrections. For example, suppose that a command for tilting the camera C by +20 degrees is input to the input unit 11, and the moving object M is shaken by +5 degrees in the y-axis direction at that moment. In this case, the control unit 13 may stop the correction in the pitch direction of the camera C, and tilt the rotation module 10 only by +15, thereby achieving the same result as the user desires. That is, since the camera C only needs to be rotated by a substantially input angle, the angle at which the movable body M is shaken in the inputted direction (+5 degrees) and the rotational module 10 rotated in the inputted direction ( The rotation module 10 may be rotated such that the sum of +15 degrees coincides with the input angle (+20 degrees). To this end, the controller 13 may rotate the rotating module 10 until the camera C is tracked at the rotated position by the angle input in the direction input from the current position. In other words, the control unit 13 rotates the rotating module 10 so that the sum of the angle of rotation of the movable body M in the inputted direction and the angle of rotation of the rotating module 10 in the inputted direction matches the inputted angle. I can do it. As described above, by controlling the rotation module 10 not to perform the shake correction for the rotation direction of the camera C temporarily, unnecessary rotation of the rotation module 10 can be prevented. That is, in the same example as above, the rotation module 10 rotates by -5 degrees in the y-axis direction to compensate for the pitch-direction shaking, and inefficient rotation such as rotation by +20 in the y-axis direction according to the input command again Can be prevented. In addition, by temporarily stopping the shake correction for a specific direction of the rotation module 10, the correction process can be simplified from 3-axis correction to 2-axis correction, or 2-axis correction to 1-axis correction. On the other hand, in the same example as above, the control unit 13 may be controlled to continuously perform correction for yaw or roll direction shaking of the camera C.

When the camera C reaches the target position and rotation of the camera C is completed, the controller 13 may control the rotation module 10 to perform shake correction again in all directions. In this case, the reference position for camera shake correction of the camera C may be reset to the current position of the camera C. That is, when the control of the photographing angle of the camera C according to the user's command is completed, the controller 13 may reset the reference position for the camera C to shake correction to the current position of the camera C.

Hereinafter, the interlocking control in the case where the camera C is controlled by the positioning method will be described.

A command for rotating the camera C to a specific position may be input to the input unit 11. That is, the absolute coordinates of the position to be photographed by the camera C may be input to the input unit 11. For example, the user may input location coordinates such as latitude, longitude or azimuth, and altitude of the location to be photographed by the camera C on the input unit 11. When the above command is input, the controller 13 may rotate the rotation module 10 so that the camera C follows the input position. In this case, the control unit 13 may control the camera C to be shake corrected in all directions. For example, the control unit 13 may reset the reference position for the shake correction of the camera C to the position input to the input unit 11. According to such a control, since the control for the camera C's shake correction and the control according to a user's command are matched, unnecessary rotation of the rotation module 10 can be prevented. On the other hand, even when the position coordinates are input to the input unit 11, in order to follow the camera C to the input coordinates, it is possible to calculate the direction and angle at which the camera C should be rotated, which means that the camera C Since the rotation direction and the rotation angle are interpreted as in the case of input, the corresponding control method may be applied.

In the above description, the interlocking control of the control unit 13 has been described for each case, and although the user's command is described as a rotation command for one direction, even when rotation commands for two or more directions are simultaneously input, each direction is independently The control method can be applied. In addition, when the rotation module 10 is rotatable in the 3-axis direction, and the roll direction operation of the camera C is not separately controlled by the user, the controller 13 corrects for the roll direction shake of the camera C. Can be controlled to run continuously.

Hereinafter, a method of controlling a pan-tilt-integrated system according to an embodiment will be described. In describing the control method, the content overlapping with the above-described content will be omitted.

2 is a flowchart of a method of controlling a pan-tilt-integrated system according to an embodiment.

2, the control method (2) of the pan-tilt-integrated system according to an embodiment includes a step 210 in which a rotation module is provided, and a step 220 in which a command for rotating the camera in one direction is input, It may include the step of rotating the rotating module in one direction (230), the step of controlling not to perform the shake correction in one direction (240) and resetting the shake correction reference position (250).

Step 210 may be a step in which a rotation module is provided. The rotating module can be installed on the moving body. A camera may be mounted on one side of the rotating module. The rotation module may rotate the camera in a two-axis or three-axis direction with respect to the moving object so that the yaw and pitch direction shake of the mounted camera is corrected.

Step 220 may be a step of inputting a command to rotate the camera in one direction. Information about the rotation direction of the camera may be input to the input unit.

Step 230 may be a step of rotating the rotating module in the one direction. The control unit may rotate the rotation module in the rotation direction input to the input unit.

Step 240 may be a step of controlling the camera to not perform a shake correction for the one direction of the camera while the rotation module rotates in the one direction according to an input command. Step 240 may be performed only while the rotation module rotates in the one direction according to the inputted command. That is, steps 230 and 240 may be performed simultaneously. However, even while the rotation module rotates in the one direction, it may be controlled to continuously perform shake correction in other directions except the one direction. According to such a control method, the correction process can be simplified from 3-axis correction to 2-axis correction, or 2-axis correction to 1-axis correction.

Step 250 may be a step of resetting the reference position for the camera shake correction to the current position of the camera when the angle adjustment of the camera according to the input command is completed.

3 is a flowchart of a method of controlling a pan-tilt-integrated system according to an embodiment.

Referring to FIG. 3, the control method (3) of the pan-tilt-integrated system according to an embodiment includes a step 310 in which a rotation module is provided, and a command in which a camera is rotated by an input angle in one direction ( 320), rotating the rotating module until the camera follows the target position (330), controlling not to perform the shake correction in one direction (340) and resetting the shake correction reference position (350) It can contain.

Since step 310 is the same step as step 210 described above, description thereof will be omitted.

Step 320 may be a step of inputting a command to rotate the camera in one direction by an input angle. Information about a rotation direction and a rotation angle of the camera may be input to the input unit.

Step 330 may be a step of rotating the rotating module in the one direction until the camera follows the position rotated by the input angle in the one direction from the current position. That is, the rotation module can be rotated in the one direction so that the camera follows the target position.

Step 340 may be a step of controlling not to perform a shake correction in one direction of the camera while the rotation module rotates in the one direction according to an input command. Step 340 may be performed only while the rotation module rotates in the one direction according to the inputted command. That is, steps 330 and 340 may be performed simultaneously. However, even while the rotation module rotates in the one direction, it may be controlled to continuously perform shake correction in other directions except the one direction. According to such a control method, unnecessary rotation of the rotation module can be prevented because the rotation module does not temporarily perform shake correction for the rotation direction of the camera.

Step 350 may be a step of resetting the reference position for the camera shake correction to the current position of the camera when the angle adjustment of the camera according to the input command is completed.

Although the embodiments have been described by the limited drawings as described above, a person skilled in the art can make various modifications and variations from the above description. For example, the described techniques may be performed in a different order than the described method, and/or components such as the structure, device, etc. described may be combined or combined in a different form from the described method, or may be applied to other components or equivalents. Even if replaced or substituted by, appropriate results can be achieved.

1: Pan tilt-gimbal integrated system
10: rotating module
11: Input section
12: sensor unit
13: Control
C: Camera
M: Moving object

Claims (13)

In the pan-tilt-integrated system,
A rotating module installed on the moving body and rotating a camera mounted on one side in at least two axes;
A sensor unit for measuring yaw and pitch directions of the moving body;
An input unit to which a command for adjusting the photographing angle of the camera is input; And
It includes a control unit for controlling the operation of the rotating module,
The control unit rotates the rotating module in a direction opposite to the shaking of the moving object measured by the sensor unit so that the shaking of the yaw and pitch directions of the camera is corrected,
When the rotation command of the camera is input to the input unit, the control unit rotates the rotation module according to the input command, and controls to be interlocked with the shake correction control of the camera,
When a command to rotate the camera in one direction is input to the input unit,
The control unit rotates the rotation module in the one direction, while the rotation module is rotated in the one direction, so as not to control the camera to perform a shake correction for the one direction, pan-tilt-integrated system. delete According to claim 1,
When the panning command of the camera is input to the input unit,
The control unit pans the rotation module, and controls to prevent the camera from performing yaw correction in the yaw direction while the rotation module is panning. According to claim 1,
When the tilting command of the camera is input to the input unit,
The control unit tilts the rotation module, while the rotation module is tilted, the pan tilt-gimbal integrated system is controlled so as not to perform pitch correction of the camera. In the pan-tilt-integrated system,
A rotating module installed on the moving body and rotating a camera mounted on one side in at least two axes;
A sensor unit for measuring yaw and pitch directions of the moving body;
An input unit to which a command for adjusting the photographing angle of the camera is input; And
It includes a control unit for controlling the operation of the rotating module,
The control unit rotates the rotating module in a direction opposite to the shaking of the moving object measured by the sensor unit so that the shaking of the yaw and pitch directions of the camera is corrected,
When the rotation command of the camera is input to the input unit, the control unit rotates the rotation module according to the input command, and controls to be interlocked with the shake correction control of the camera,
When a command to rotate the camera in one direction by an input angle is input to the input unit,
The control unit rotates the rotating module in the one direction until the camera follows from the current position to the position rotated by the input angle in the one direction, while the rotating module rotates in the one direction, the one direction of the camera Pan tilt-gimbal integrated system that controls not to perform shake correction for. delete delete According to claim 1,
The control unit resets the reference position for the camera shake correction to the current position of the camera when the camera's shooting angle adjustment is completed. delete According to claim 1,
The sensor unit includes at least one or more of a gyro sensor, an acceleration sensor, and a geomagnetic sensor, a pan-tilt-integrated system. In the pan-tilt-integrated system control method,
A step of providing a rotation module that rotates the camera in at least two axes with respect to the moving body such that yaw and pitch direction shaking of the camera installed on the moving body and compensated for yaw of the camera mounted on one side;
Inputting a command to rotate the camera in one direction;
Rotating the rotating module in the one direction; And
And while the rotation module rotates in the one direction, controlling the camera so as not to perform a shake correction for the one direction, a pan-tilt-integrated system control method. In the pan-tilt-integrated system control method,
A step of providing a rotation module that rotates the camera in at least two axes with respect to the moving body such that yaw and pitch direction shaking of the camera installed on the moving body and compensated for yaw of the camera mounted on one side;
Inputting a command to rotate the camera by an input angle in one direction;
Rotating the rotation module in the one direction until the camera follows the position rotated by the input angle in the one direction from the current position; And
And while the rotation module rotates in the one direction, controlling the camera so as not to perform a shake correction for the one direction, a pan-tilt-integrated system control method. The method of claim 11 or 12,
When the rotation of the camera according to the input command is completed, the pan tilt-gimbal integrated system control method of resetting the reference position for the camera shake correction to the current position of the camera.

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