The invention relates to an adjustable bracket for a display device. The adjustable bracket includes a mounting seat for being fixed to an object surface, a pylon for mounting the display device, and a connecting arm with two ends being rotatably connected to the mounting seat and the pylon, respectively. The mounting seat is provided with a lifting means and an adjusting mechanism for adjusting a retraction state of the pylon therein. The bracket is suitable for a variety of display devices of various specifications, and the pylon is adjustable in three dimensions relative to the mounting seat, thereby meeting the use requirements. The power structure is built to protect itself and to avoid safety hazards. A user can adjust the position of the pylon relative to the mounting seat by pulling and pushing, and the installation and debugging operation is simple, and an overall thickness of the bracket is small when the pylon and the mounting seat are closed up, and the storage space occupied by the bracket is small. The setting of the adjusting mechanism solves the problem of premature failure of a boosting unit caused by over-reliance on its own strength.

A tensile parallelogram arm that mimics parallelogram counterbalancing structures and which can be folded into a compact form. The assembly includes a gimbal to which a supported payload is attached.

A horizontal-posture maintaining apparatus is provided. The apparatus includes a barrel, a cover unit provided on a side surface of the barrel, a first driver provided in the cover unit, for rotating the barrel in a first direction (around an X axis) to keep the barrel in horizontal posture, a second driver provided in the cover unit, for rotating the cover unit in a second direction (around a Y axis) to keep the barrel in the horizontal posture, and a controller for controlling rotation of the first and second drivers.

A handheld image stabilization device or an image capture device includes a housing, a motor, a microphone, and a dampener. The housing includes a first port. The motor is attached to the housing. The microphone detects audio waves via the first port and vibration noise of the motor via the housing. The audio waves may include acoustic noise from the motor. The dampener is coupled to the housing. The dampener reduces the acoustic noise from the motor and the vibration noise from the motor.

A system for mounting a medical imaging device on a tablet arm is provided. In one embodiment the tablet arm includes an upper portion configured to rotate a mounted electronic device relative to a central axis of the upper portion and a lower portion coupled to the upper portion and extending downwards, away from the upper portion along a vertical axis perpendicular to the central axis, the upper portion and lower portion forming a hollow structure configured to house cables of an electronic device.

The present disclosure provides a gimbal control method, a device, a gimbal, a system, and a storage medium. The gimbal includes at least one axis of rotation. The method includes: determining a current first working mode of the gimbal; and if the gimbal satisfies a preset mode switching condition, controlling the gimbal to switch from the first working mode to a second working mode, and enabling the gimbal to maintain smooth and stable operation during the switching process, where in the first working mode, the axis of rotation is configured to enable the gimbal to face a first direction, and in the second working mode, the axis of rotation is configured to enable the gimbal to face a second direction. In this way, smooth transition of the gimbal can be maintained during mode switching, so that stability of image shooting during mode switching of the gimbal is improved.

An X-ray detector holder stand maintaining the position of a detector is proposed. A pillar erected on a base has a sliding window formed on the front surface of a pillar housing to extend upwards/downwards. A rack is fixed inside the pillar housing to extend perpendicularly. A wire is wound around multiple pulleys to extend perpendicularly to the front/rear side of the rack. A balance weight is coupled to the wire behind the rack inside the pillar housing. An arm includes a sliding block guided along the sliding window, a stopper gear coupled to the sliding block to rotate between a locking position and an unlocking position, an elastic pressurizing means for pressurizing the stopper gear to rotate to the locking position, and a lever means for rotating/operating the stopper gear to the unlocking position. A holder is coupled to an end portion of the arm to enable rotational manipulation.

The description relates to devices that can include a hollow arm that has an open side and a cover engaging region around the open side. The cover engaging region defines a first width at the open side, a second width farther from the open side, and a third width that is farther from the open side than the first width and the second width. The device can also include an arm cover that includes an arm engaging region. The arm engaging region can define a fourth width at the open side, a fifth width farther from the open side, and a sixth width that is farther from the open side than the fourth width and the fifth width. The sixth width can be greater than the fifth width and the second width and less than the first width and the fourth width.

An embodiment provides a motorized monopole for a camera, including: a hand-held monopole; a first motor positioned at an end of the hand-held monopole; a first connecting element attached to the first motor; a second motor positioned at an end of the first connecting element; a second connecting element attached to the second motor; a third motor positioned at an end of the second connecting element; and a camera mounting plate attached to the second connecting element by the third motor, where components of the multi-axis gimbal are positioned such that a camera viewing axis, a horizontal image axis, and a vertical image axis of a camera mounted on the camera mounting plate need not be aligned with any of a rotational axis of the first motor, a rotational axis of the second motor, or a rotational axis of the third motor. Other aspects are described and claimed.

The description relates to devices, such as computing devices having displays that can be rotated through a range of travel. The device can counter-balance the display to create a near weightless feel for the user when repositioning the display.