Present invention provides a frame assembly for a stabilizer, wherein the stabilizer comprises a gimbal for fixing a photographing device and adjusting the posture of the photographing device, the frame assembly is used for supporting the gimbal, and comprises: a first frame part; a second frame part configured to be disposed at an angle with the first frame part; and a holding handle; wherein the frame assembly is configured to allow the stabilizer to be held via the holding handle in a manner roughly vertically aligned with the overall center of gravity of the stabilizer and a photographing device. Therefore, present invention provides the stabilizer and the frame assembly thereof, which is ergonomic, good in stability and changeable in operation postures. Furthermore, present invention also provides a stabilizer with the frame assembly.

A method and apparatus are provided for implementing an ultra-high stability stage with combined degrees of freedom for multiple axes of motion. The ultra-high stability stage includes a base, a driving wedge supported by the base and a following wedge supported by the driving wedge. The base and each wedge are formed of a selected stable material having predefined rigidity and low thermal expansion coefficient. Integrated air bearings, respective driving mechanics associated with each of the wedges and guiding components having selected degrees of freedom enable movement about multiple axes of motion, such as X, Y, Z translation axes, and rotation X and rotation Y axes. Another ultra-high stability stage with combined degrees of freedom for multiple axes of motion includes an intermediate wedge between the driving wedge and the following wedge to enable additional movement about a rotation X axis.

A method includes fabricating a mirror system that includes a dual axis gimbal, a mirror, and a mirror substrate that are formed together as an integral component using an additive manufacturing process. The method also includes forming multiple first gaps in the mirror system using a subtractive manufacturing process, where the first gaps extend through the mirror system in a first direction. The method further includes forming multiple second gaps in the mirror system using the subtractive manufacturing process, where the second gaps extend through the mirror system in a second direction perpendicular to the first direction. The first gaps and the second gaps separate the gimbal into a top portion and a bottom portion.

A method and apparatus are provided for implementing an ultra-high stability stage with combined degrees of freedom for multiple axes of motion. The ultra-high stability stage includes a base, a driving wedge supported by the base and a following wedge supported by the driving wedge. The base and each wedge are formed of a selected stable material having predefined rigidity and low thermal expansion coefficient. Integrated air bearings, respective driving mechanics associated with each of the wedges and guiding components having selected degrees of freedom enable movement about multiple axes of motion, such as X, Y, Z translation axes, and rotation X and rotation Y axes. Another ultra-high stability stage with combined degrees of freedom for multiple axes of motion includes an intermediate wedge between the driving wedge and the following wedge to enable additional movement about a rotation X axis.

A device and method for providing a levelable attachment surface for attaching a construction tool at a jobsite is provided. The device includes a receiver portion and a post portion. The receiver portion includes a portion being embeddable in a work surface at the jobsite and a portion for receiving a portion of the post portion. The post portion includes at least one flange portion including the levelable attachment surface. The levelable attachment surface can be leveled to facilitate substantially leveled attachment of the construction tool to the levelable attachment surface.

An adjusting device includes an adjuster and a supporting mechanism. The adjuster includes a transmission member that is configured to drive a portion of the adjuster to have a movement. The supporting mechanism includes a mounting assembly, a supporting assembly, and a connection assembly. The mounting assembly is configured to be coupled to a gimbal. The supporting assembly is configured to be coupled to the adjuster and includes a supporting member that is provided as a rod. The connection assembly is configured to adjustably connect the mounting assembly and the supporting assembly. A position of the adjuster relative to the gimbal is adjustable at least by adjusting a linear position of the adjuster relative to the rod and a rotation position of the connection assembly relative to the mounting assembly.

A method of controlling a handheld gimbal includes obtaining an input instruction, and selecting one follow mode from a plurality of follow modes for following movement of an input device or a handheld member of the handheld gimbal based on the input instruction. The plurality of follow modes have different following speeds, and include a rapid follow mode. The method further includes controlling movement of the handheld gimbal using the selected one follow mode to follow the movement of the input device or the handheld member. In response to the rapid follow mode being selected, the movement of the handheld gimbal is controlled according to a sum of a first speed and a second speed. The first speed and the second speed are determined based on different information.

A method for object tracking. The method includes capturing a sequence of images of a scene, detecting, by a hardware processor based on a pattern of local light change across the sequence of images, a light source in the scene, comparing, by the hardware processor in response to detecting the light source, a location of the light source in at least one image of the sequence of images and a target position within the at least one image to generate a result, and generating, by the hardware processor based on the result, a control signal for changing a field-of-view of a camera device such that the light source substantially aligns with the target position within the field-of-view, wherein the light source is configured to produce an object-identifying code.

A gimbal assembly is provided that allows for more than a single rotation about a rotational axis in both a first rotational direction and a second rotational direction.

A gimbal frame includes a guide rod and a locking mechanism mounted at the guide rod. The locking mechanism includes a tightening member disposed at the guide rod, a transmission member disposed at the guide rod and in transmission engagement with the tightening member, an abutting member disposed at one side of the transmission member, and a driving member connected to the abutting member. The transmission member can move in a first direction to drive the tightening member to move in a second direction. The driving member can drive the abutting member to abut the guide rod and to drive the transmission member to move in the first direction.