A robotic mount is configured to move an entertainment element such as a video display, a video projector, a video projector screen or a camera. The robotic mount is moveable in multiple degrees of freedom, whereby the associated entertainment element is moveable in three-dimensional space. In one embodiment, a system of entertainment elements are made to move and operate in synchronicity with each other, such as to move a single camera via multiple robotic mounts to one or more positions or along one or more paths.

Embodiments of the present disclosure provides a gimbal. The gimbal includes a pitch motor, a coaxial cable, and a first support arm arranged opposite a second support arm. The pitch motor is disposed at a front end of the first support arm, a motor shaft of the pitch motor extending in a direction of the second support arm for connecting with one end of an imaging device; a limiting shaft is disposed at a front end of the second support arm, the limiting shaft extending in a direction of the first arm for connecting with another end of the imaging device; a first wiring space is formed in the limiting shaft and a second wiring space is formed in the second support arm, a first end of the coaxial cable sequentially passing through the second wiring space and the first wiring space for electrically connecting with the imaging device.

A gimbal control method includes determining a current state of a follow-configuration button, determining a current follow coefficient based on the current state of the follow-configuration button, and controlling a gimbal to follow a target object according to the current coefficient. The follow-configuration button corresponds to a plurality of states, and each state corresponds to a different follow coefficient.

The present disclosure provides a joint assembly for an apparatus comprising an object and a base component. The joint assembly comprises a first joint component coupled to a second joint component and each joint component comprises annular joint sections. A first peripheral section of a first annular joint section of the first joint component abut with a second peripheral section of a second annular joint section of the second joint component is defined to rotate about a first axis. A second peripheral section of a second annular joint section of the first joint component abut with the base component is defined to rotate about a second axis. A first peripheral section of a first annular joint section of the second joint component abut with the object is defined to rotate about the third axis. The first axis, the second axis, and third axis are orthogonal to each other.

A handheld gimbal includes a handle and a gimbal. The gimbal is connected to the handle and includes at least two shaft assemblies. The at least two shaft assemblies are rotatably connected to each other. Each of the at least two shaft assemblies includes a motor. The motors of the at least two shaft assemblies are arranged one over another along a same straight line when the gimbal is in a folded state. The motors of the at least two shaft assemblies are arranged separately when the gimbal is in an unfolded state.

Disclosed are a vehicle-mounted camera gimbal servo system and a control method. The vehicle-mounted camera gimbal servo system includes a camera tri-axial gimbal and a servo control apparatus. The camera tri-axial gimbal includes a pitch motor, a roll motor, a yaw motor, a roll arm (1), a pitch arm (4), a yaw arm (5), a gimbal top (7), a camera (11), a pitch-axis bearing (12), and a counterweight block (13); the pitch motor includes a pitch motor stator (2) and a pitch motor rotor (3); the yaw motor includes a yaw motor stator (6) and a yaw motor rotor (8); the roll motor includes a roll motor stator (9) and a roll motor rotor (10); the servo control apparatus includes an inertial measurement unit, a three-dimensional modeling control unit, an angular velocity loop control unit, and an angular displacement loop control unit.

A lens device includes a first lens system including a first lens, a second lens system including a second lens, a moving member configured to move in an optical axis direction of the first lens, and a physical structure configured to move the first lens in the optical axis direction and move the moving member in a direction opposite to a movement direction of a center of gravity of a physical system that includes the first lens.

A device for supporting a smartphone having a video camera or supporting an action video camera has a grip configured for supporting the smartphone having the video camera in it or supporting the action video camera, a holder configured to be controlled by a user, and components for receiving audio signals from an audio signal source and reproducing the received audio signals in the vicinity of the holder so that the video recorded by the camera includes the received audio signals.

Disclosed herein is an articulated support device. The articulated support device is formed to include a plurality of links connected to each other. A device stand is detachably coupled to the front end of the articulated support device and the rear end of the articulated support device is fixedly coupled to a structure detachably. The connection portions of the plurality of links are fixed not to move relative to each other or the connection portions are released to be rotatable relative to each other through an operation of a handle part provided on a front side of the articulated support device. The articulated support device includes a plurality of rotation and fixing units. Each of the plurality of rotation and fixing units includes a front link connection adapter, a wire central binding portion, a rotation regulation portion, a casing pipe, and an inner connection pipe.

A gimbal system includes an angle adjusting assembly, a digital video transmitter, and a holder. The angle adjusting assembly is configured to support an imaging device and includes an electronic adjuster configured to control a rotation speed of a motor. The digital video transmitter includes a video converter configured to convert a digital video signal obtained from the imaging device to a serial differential signal, a transmission circuit electrically coupled to the video converter, and an image transmitter electrically coupled to the transmission circuit and configured to receive and transmit the serial differential signal. The holder includes a first surface and a second surface opposite to each other. The angle adjusting assembly is pivotally connected to and arranged on the first surface of the holder, and the transmission circuit is arranged on the second surface of the holder.