A compact first-person-view (FPV) pan and tilt camera mount is installed in a remote-controlled vehicle, and the vehicle is configured to accommodate a video processing module/air unit, a camera module, and a horizontal and vertical rotatable (pan and tilt) camera mount module. A realistic scale remote-controlled scale vehicle typically comes with interior cabin or cockpit space to accommodate driver/pilot that can be utilized to install the pan & tilt camera module. The video processing module is configured to process images shot by the camera module. The camera is mounted on the pan and tilt module. The pan and tilt module includes a first servo, a base, a movable seat, a rotation module, a clamp portion, and an accommodation portion. The first servo has a first shaft, the movable seat has a fitting seat, and the fitting seat has a connection orifice. The rotation module has a first semi-circular gear and a second semi-circular gear meshing. The accommodation portion is formed on the movable seat and is configured to receive a second servo, and the second servo has a second shaft.

One variation of the tile display includes a set of tile assemblies, each tile assembly includes: a base plate; a tile panel; a tile interface; and a set of linear actuator assemblies arranged in a radial pattern about the base plate and cooperating to constrain the tile panel in angular roll, linear heave, and linear sway motion relative to the base plate. Each linear actuator assembly includes: a bearing housing defining a linear bearing, a floating bearing, and a through-hole; an actuator mounted to the bearing housing; a distal link coupled to the tile interface; a first support boom running through the linear bearing; a second support boom running through the floating bearing; and a driven boom running through the through-hole of the bearing housing. Each tile assembly also includes a primary controller configured to maneuver tile panels over ranges of angular pitch, angular yaw, and linear surge positions.

A method for aligning the field of view of a user with the field of view of a camera mounted on the user's head may include providing at least one head-mounted camera module that includes at least one sensor that in turn includes an image sensor, where the said image sensor outputs video of an area; receiving a first input from a user to expect a second input relating to the field of view; receiving the second input relating to the field of view; and aligning the field of view of the user with the field of view of the camera.

A spring clamp for removably attaching a camera, decoy or other device to a structural support. The clamp includes two opposing arms, each including a handle component and a jaw component. The clamp can be attached to an apparatus when the two jaw components including Inward facing arcuate jaws with gripping teeth and notches are closed around the apparatus. The clamp is provided with a plurality of threaded inserts at selected positions for supporting a device such as a camera. An adjustable and positionable extension may be removably fastened to the camera mount and the camera is detachably coupled to the extension. This allows an article such as a camera to be situated at any desired angle for taking photographs.

A support device includes a support structure and a carrier assembly. The support structure includes a connection groove. The carrier assembly is configured to support a host system and/or a display device and includes a first connector. At least a part of the first connector is located in the connection groove and sliding in the connection groove. An angle between the host system and/or the display device and the support structure is adjusted in a first direction and/or a second direction by sliding the first connector in the connection groove.

A mobile device mounting system includes a device case and a mount. The device case includes: an insert including a rectangular bore and defining a set of undercut sections about the rectangular bore; and a first set of magnetic elements arranged in a first pattern about the rectangular bore. The mount includes: a body; a polygonal boss extending from the body and configured to insert into the rectangular bore; a set of locking jaws arranged on the polygonal boss configured to transiently mate with the set of undercut sections to constrain the polygonal boss within the rectangular bore; and a second set of magnetic elements arranged in a second pattern about the polygonal boss and configured to transiently couple to the first set of magnetic elements to transiently retain the mount against the device case and to drive the set of locking jaws toward the set of undercut sections.

A gimbal includes a control device configured to receive an action instruction including a press action instruction and, based on the action instruction, generate a control instruction including a switch control instruction for switching operating modes of the gimbal, a controlling assembly configured to receive the control instruction and generate a performing instruction based on the control instruction for controlling an optical device, and a performing assembly configured to receive and implement the performing instruction. The performing assembly is operably connected to the controlling assembly and supported on a top end of a support arm of the control device. The performing assembly comprises a first rotation member, a second rotation member, and a carrying member connected one to another, and first and second motors for driving the second rotation member and the carrying member to rotate relative to the first and second rotation members, respectively.

A gimbal includes a control device configured to receive an action instruction including a press action instruction and, based on the action instruction, generate a control instruction including a switch control instruction for switching operating modes of the gimbal, a controlling assembly configured to receive the control instruction and generate a performing instruction based on the control instruction for controlling an optical device, and a performing assembly configured to receive and implement the performing instruction. The performing assembly is operably connected to the controlling assembly and supported on a top end of a support arm of the control device. The performing assembly comprises a first rotation member, a second rotation member, and a carrying member connected one to another, and first and second motors for driving the second rotation member and the carrying member to rotate relative to the first and second rotation members, respectively.

A gear fine-tuning pan-tilt includes a rotating base, a roll worm support seat, a roll adjusting assembly, a pitch adjusting assembly, and a bearing seat arranged in sequence from bottom to top; the pitch adjusting assembly of the complete gear structure is located on the above, and the roll adjusting assembly located below adopts an arc-shaped rack structure, which reduces the interference to the pitching movement of the upper assembly and makes the height of the pan-tilt smaller. The arc opening of the arc-shaped rack faces upwards, so that the rotation axis is closer to the center axis of the lens. The upper and lower combination of the two structures strengthens the swing ability of the top of the pan-tilt in the limited size. The structure is able to be aimed at the subject through the rotating base, and leveled the left and right, and determined the pitch angle.