A gimbal includes a handle (300), a first arm (100), a second arm (200) and a clamping member (400) sequentially connected, the second arm (200) including a second connecting portion (210) and a second rod portion (211); and further includes: a first driving member (11) connected to the handle (300) and the first arm (100) to drive the first arm (100) to rotate with respect to the handle (300); a second driving member (12) connected to the second connecting portion (210) and the second rod portion (211) in the second arm (200) to drive the second rod portion (211) to rotate with respect to the second connecting portion (210); and a third driving member (13) connected to the second rod portion (211) and the clamping member (400) to drive the clamping member (400) to rotate with respect to the second rod portion (211).

A multifunctional holder is provided for supporting a first object and a second object. The multifunctional holder includes a backboard assembly, an adapter, at least one movable arm and a positioning member. The backboard assembly is disposed on a back side of the first object. The adapter is connected to the backboard assembly. The at least one movable arm is connected to the adapter, wherein a first degree of rotational freedom is provided between the backboard assembly and the adapter, and a second degree of rotational freedom is provided between the adapter and the at least one movable arm. The positioning member is disposed on the backboard assembly or the adapter for fixing the second object.

A balancing arm, comprising a folding arm that extends between a first end that is held in position, and a second end on which a load is carried, a first folding arm portion that extends from the first end of the folding arm being pivotably connected via a hinge to a second folding arm portion that extends to the second end of the folding arm. The balancing arm further comprises a balancing force device that is arranged to act between the first and second ends of the folding arm across the friction hinge to balance the load carried on the second end of the folding arm. The friction hinge is embodied as a friction hinge with adjustable friction, and includes a head and a socket arranged to pivot relative to each other when the folding arm portions pivot.

A kit of portable modular components for use in demountably configuring a variety of structural assemblies. The kit comprises three types of elongate structural support components wherein the first type has a pair of opposed male ends, the second type has a male end and an opposed female end, and the third type has a pair of opposed female ends, wherein the male ends are configured for demountable engagement with the female ends. Each of the male ends comprises a cylindrical body with at least one linear set of two spaced-apart prongs around the circumferential surface of the cylindrical body. Each of the female ends has a cylindrical receptacle with one or more linear channels for receiving therein the cylindrical body and the at least one linear set of prongs. The female ends are provided with locking assemblies for releasable engagement the male ends.

A hand-held gimbal includes a handle portion and a gimbal photographing device mounted on the handle portion. A display screen is disposed at the handle portion and configured to display at least one of content captured by the gimbal photographing device or a photographing parameter of the gimbal photographing device.

A kit of portable modular components for use in demountably configuring a variety of structural assemblies. The kit comprises three types of elongate structural support components wherein the first type has a pair of opposed male ends, the second type has a male end and an opposed female end, and the third type has a pair of opposed female ends, wherein the male ends are configured for demountable engagement with the female ends. Each of the male ends comprises a cylindrical body with at least one linear set of two spaced-apart prongs around the circumferential surface of the cylindrical body. Each of the female ends has a cylindrical receptacle with one or more linear channels for receiving therein the cylindrical body and the at least one linear set of prongs. The female ends are provided with locking assemblies for releasable engagement the male ends.

An image capture device and a handheld image stabilization device may each include a housing, a motor assembly, a microphone, a dampener, or any combination thereof. The housing may include a first port. The motor assembly may be attached to the housing. The motor assembly may include a plurality of motors. The microphone may be configured to detect audio waves via the first port, vibration noise of the plurality of motors via the housing, or both. The audio waves may include acoustic noise from the plurality of motors. The dampener may be coupled to the housing. The dampener may be configured to reduce the acoustic noise from the plurality of motors, the vibration noise from the plurality of motors, or both.

A method to stabilize a camera device. The method includes receiving, from the camera device mounted in a camera device holder, sensor data representing at least one selected from a group consisting of orientation and movement of the camera device, generating, using a pre-determined algorithm, a control signal based on the sensor data, and adjusting, using the control signal, a geometrical behavior of the camera device holder, wherein the geometrical behavior corresponds to at least one selected from a group consisting of the orientation and the movement of the camera device holder.

A handheld gimbal includes a handheld part and a gimbal. The handheld part is configured with a human-machine interface component. The gimbal is mounted at the handheld part and configured to mount a camera device to photograph a target object. The human-machine interface component includes a display screen and a processor. The display screen is configured to display a photographing image captured by the camera device. The photographing image includes an image of the target object. The processor is configured to automatically recognize the target object, obtain a motion instruction of controlling a motion of the gimbal according to a motion status of the image of the target object, and control the motion of the gimbal according to the motion instruction.

An adjustment structure and an adjustment method therefor, a sealing member, a coaxial cable, a gimbal and a mobile apparatus are provided. The arm adjustment structure includes a base, an arm, and a sealing member. The arm is capable of moving relative to the base, and a clearing slot is disposed on the arm. The sealing member is disposed between the base and the arm, and is capable of being located at the clearing slot to cover the clearing slot. The sealing member is disposed between the base and the arm, and capable of being located at the clearing slot to cover the clearing slot to prevent the clearing slot from being exposed, and prevent foreign matters such as water droplets, sand, and dust from entering the gimbal through the clearing slot and affecting normal use of the gimbal.