A crossbar assembly for facilitating isolation of a sensor assembly from vibration comprises an outer crossbar segment, an inner crossbar segment, and an isolator. The outer crossbar segment comprises a payload mount interface and an outer isolator interface operable to mount to an isolator. The inner crossbar segment comprises a structure interface and an inner isolator interface operable to mount to the isolator. The isolator can be supported by the outer and inner crossbar segments. The isolator comprises a first wire rope assembly comprising wire ropes extending longitudinally from the outer crossbar segment to the inner crossbar segment, and a second wire rope assembly comprising a wire rope extending circumferentially between the outer and inner crossbar segments. The isolator operates to partially decouple the outer crossbar segment from the inner crossbar segment and dampen vibrations propagating between the outer and inner crossbar segments.

An image-capturing device includes a camera and a rotating mechanism for orienting the camera in multiple directions. The rotating mechanism includes a motor; a driving gear; a first transmission module including a first input gear, which is selectively engaged with and transmitted to rotate by the driving gear at a first position, and transmitting the camera to rotate in a first direction with rotation of the first input gear; a second transmission module including a second input gear, which is selectively engaged with and transmitted to rotate by the driving gear at a second position, and transmitting the camera to rotate in a second direction with rotation of the second input gear; and a clutch mechanism including a clutch device for driving the driving gear to switch between the first position and the second position. The clutch device includes a solenoid.

Aspects of the present disclosure relate to modular camera mounts interoperable with cameras. The modular camera mount may include a bracket comprising a first mounting portion positioned perpendicular to a camera mounting portion. The first mounting portion may facilitate securing the modular camera mount to a first surface, wherein the first surface may comprise a small area. Both the camera mounting portion and the first mounting portion may include a plurality of mounting provisions configured to align with mounting provisions of a cover. The cover may be secured to the bracket via a plurality of fasteners threaded through the mounting provisions. Securing the cover to the bracket may form a chamber therebetween, wherein the chamber may be a conduit for a cable configured to electrically connect the camera to a power source. The cover may be configured to secure the position adjustable camera via an angular adjustable bracket.

A camera control apparatus of the present disclosure includes an interface and a controller. The interface receives first image data generated by a first camera performing image capturing, second image data generated by a second camera performing image capturing, and altitude information relating to altitude, the altitude information being output by an altitude sensor, and transmits a drive signal to a first actuator capable of changing an image capturing direction of the first camera and to a second actuator capable of changing an image capturing direction of the second camera. The controller outputs the drive signal driving at least one of the first actuator and the second actuator to the interface so that an image capturing region of composite image data in which the first image data and the second image data are combined is narrower when the altitude indicated by the altitude information is lower.

This application discloses a stand assembly that includes an upper portion for holding electronic components and a lower portion for supporting the upper portion. The lower portion including a base, a joint, and a second fastener structure configured to mate with a first fastener structure of the upper portion. The first fastener structure and the joint are configured to respectively provide a first degree of freedom of motion and a second degree of freedom of motion of the upper portion with respect to the lower portion. Movement of the upper portion at the first degree of freedom has substantially consistent resistance through first part of a first full range of motion associated with the first degree of freedom of motion. Movement of the upper portion at the second degree of freedom has substantially consistent resistance through a second full range of motion associated with the second degree of freedom.

Disclosed is a tripod. The tripod comprises a base body, a plurality of tripod tubes and a plurality of connecting components. An end of each tripod tube is pivotally connected to the base body. The plurality of tripod tubes is pivotally operated in relation to the base body either at a folded state or at an expanding state. The other end of the plurality of tripod tubes get being close to each other so as to be folded in the folded state, and the other end of the plurality of tripod tubes get being far from each other so as to be expanding in the expanding state. Each of the plurality of connecting components is pivotally connected between the tripod tubes adjacent to each other. the two connecting elements are pulled by the tripod tubes connected to the two connecting elements in such a manner that the connecting elements are pulled by each other to be a straight line so as to provide a steady force to support the adjacent tripod tubes and thus to provide stable supporting force for a photographic equipment.

A coupler for coupling to a provided article of wear comprises a base plate and a clip. The coupler may be configured to provide a mount interface on an article of wear for an accessory to mount to. The base plate may comprise one or more structures configured to engage one or more respective portions of the clip over the provided article of wear. The clip may be shaped to interlock with the structures of the base plate. The clip may engage the base plate in a series of actions. The series of actions may be repeated in reverse to disengage the clip from the base plate. The series of actions for disengaging the clip from the base plate may reduce a likelihood of the clip in being unintentionally decoupled from the base plate, thereby increasing a likelihood that the coupler remains coupled to an article of wear.

A system including a motorized base unit with a smart device mount for automatically orienting the smart device camera toward a moving target to track the moving target and take pictures or video. The target (e.g., a child playing soccer) wears a tracking tag comprising a GPS chip and transmitter packaged inside an athletic pad. The base unit includes a motorized mast for mounting a smart device. The base unit receives the transmitted GPS data, calculates updated pointing angle and angular velocity for the smart phone based on update location information from the remote tag sensor, calculates the correct angle that the smart phone should be pointed at, translates the new pointing directions to a control signal that turns the mast, which in turn causes the smart device camera to “follow” or track the target.

An electronic device includes a body, electronic components contained in the body, and two finger members. The two finger members movable relative to the body between an extended state and a collapsed state. In the extended state, the two finger members extend outward from the body for receipt by a mount of an external support. In the collapsed state, the two finger members are collapsed toward the body. In the extended state, the two finger members may extend parallel with each other for receipt in parallel slots of the mount of the external support.

A gimbal arrangement includes a static structure, a gimbal supported for rotation relative to the static structure, an actuator operably connected to the gimbal and configured to rotate the gimbal relative to the static structure, and a magnetic soft stop. The magnetic soft stop is connected between the static structure and the gimbal to limit rotation of the gimbal relative to the static structure to within a predetermined range. Sensor systems and imaging methods are also described.