An adjustable mounting apparatus for electronic devices is configured to be adaptable to various support structures, and to facilitate a customized mount orientation for the electronic devices through several degrees of pivot freedom. The mounting apparatus is particularly adaptable to outdoor or industrial environments in which standard support structure modalities may not be available.

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.

Examples of the present disclosure are directed toward a control panel display with rotatable mount. An example apparatus includes a control panel mount including a first surface to receive a control panel display and a second surface opposite the first surface. The apparatus further includes a rotatable mount including a first surface and a second surface opposite the first surface. A first hinge mechanism which is rotatable about a first axis may allow the rotatable mount to move between a first operational position in which the rotatable mount is disposed in contiguous contact with a top cover of the apparatus and a second operational position in which the control panel display is disposed within a recessed portion of the top cover. A second hinge mechanism may be rotatable about a second axis orthogonal to the first axis to change a display angle of the control panel display.

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.

Disclosed herein is a bracket for mounting a tablet shaped device.

An exercise apparatus comprises an exercise apparatus body and an image display connected to a front portion of a frame of the exercise apparatus body. The image display can be moved between a first position and at least one second position via a connecting component. When the image display is located at the first position, a display surface of the image display basically faces substantially rearward, and the center point of the display surface is located in the region of the width in the transverse direction of the exercise apparatus body for a user viewing an image to perform a first exercise by using the exercise apparatus in a first exercise area; and when the image display device is located at the second position, the display surface faces substantially rearward, and the center point of the display surface is located outside the region of the width in the transverse direction of the exercise apparatus body for a user viewing the image to perform a second exercise in a second exercise area which is outside the first exercise area.

A display device for the interior of a vehicle includes a display unit designed to optically display information, and a movement mechanism designed to transfer the display unit, controllably, between a non-usage position parallel to a roof liner of the vehicle and a usage position, swivelled away from the roof liner of the vehicle, and to retain the display unit, controllably, in the non-usage position and/or in the usage position. The movement mechanism is attached to the display unit: by first guide elements in order to define a swivel axis for swivelling the display unit at least between the non-usage position and the usage position; by second guide elements, each of which is or can be coupled to the display unit in a mechanical operative connection via a coupling lever of the display device; and by guide rails for attaching to the roof liner. The rails have a guide track for receiving the guide elements and for moving same therein along the guide track.

A support system for a display device includes a first arm configured to extend from a support surface. A second arm is rotatably connected to the first arm. The second arm has a range of movement relative to the first arm. A tilt head is rotatably connected to the second arm and configured to connect to a display. A first biasing member is positioned in the second arm and configured to provide a first counterbalancing force to the second arm to offset a load of the display. A second biasing member is positioned in the second arm and configured to provide a second counterbalancing force to the second arm to offset the load of the display. A lockout mechanism is configured to disengage the second biasing member and eliminate the second counterbalancing through at least a portion of the range of motion.

A gimbal photographing device includes a body including a supporting wall and a side wall adjacent to the supporting wall, a folding mechanism connected to the body and configured to rotate around a rotation axis, and a gimbal camera connected to the folding mechanism and having an expanded state and a folded state. In response to the folding mechanism driving the gimbal camera to rotate to the expanded state, at least a portion of the folding mechanism abuts against the supporting wall. In response to the folding mechanism driving the gimbal camera to rotate to the folded state, the gimbal camera fits to the side wall of the body.

Aspects of the present disclosure relate to automatic monitor position adjustment. An indication that an application is being launched is received. A preferred monitor position for the application is determined by referencing a data store mapping preferred monitor positions to respective metadata attributes, where the preferred monitor position for the application is determined based on the preferred monitor position being mapped to a first metadata attribute associated with the application within the data store. An actuator associated with the monitor is then instructed to adjust the position of the monitor to the preferred monitor position.