Methods, systems, and devices are described for antenna positioning with an eccentric tilt pointing mechanism. For example, a system in accordance with the present disclosure may include a base structure and an intermediate structure that is rotatably coupled with the base structure about a first axis (e.g., a tilt axis). The system may also include a positioning system that is coupled with the intermediate structure and configured to orient an antenna boresight about at least two angular degrees of freedom with respect to the intermediate structure (e.g., in an elevation-over-azimuth configuration). The system may also include an actuator between the base structure and the intermediate structure that is configured to set, change, or maintain an angle between the base structure and the intermediate structure, which, in some examples, may include a rotation of an eccentric element based on a predicted path of a target device.

A stabilization device for stabilizing an attachment component relative to movements of a basic component which occur outside a permitted plane of movement. The attachment component and the basic component are connected via a stabilization arrangement that includes: a first compensation arrangement for compensating rotational movements of the basic component with respect to an intermediate component, about rotational axes lying in the plane of movement, including a first compensation device which can be actuated actively, a second compensation arrangement for compensating residual linear movements of the intermediate component in a compensation direction, perpendicular to the plane of movement, in relation to the attachment component, having a second compensation device which can be actuated actively, a plurality of inertial sensors assigned to the first and/or second compensation arrangement, and a control device for actuating the compensation devices for movement compensation as a function of sensor data of the inertial sensors.

An adjustable mount for mounting a component subjected to dynamically-varying loads decouples position adjustment of one axis from position adjustment along the other. The mount includes a frame between base and top plates. The frame has apertures for receiving positioners. The positioners abut sides that extend inward from the plates and into the frame. Actuating a positioners causes it to push its corresponding side. This causes relative motion between the frame and the positioner's corresponding plate. Movement interfaces guide these movements during adjustment and locking interfaces lock the frame and the corresponding plate into position after completion of adjustment.

A rotatable connection for a stand apparatus to be arranged in an operating room and including an adaptable stop mechanism which can be arranged between a first connection component and a second connection component mounted rotatably around a rotational axis relative to the first connection component and is configured to define at least two different relative rotational angles of the connection components or at least two different rotational ranges is provided. A carrier system or a stand apparatus having such a rotatable connection is also provided.

The present disclosure provides a control device. The control device is configured to control a rotation mechanism to rotatably hold a camera device. The control device includes a processor configured to execute a program to: determine a mounting state of a mounting member mounted on a support mechanism supporting the rotation mechanism; determine a rotation range of the camera device coupled to the rotation mechanism based on the mounting state of the mounting member; and control a rotation of the camera device based on the rotation range.

In one aspect of the present disclosure, a gimbal assembly is described for use with an image capturing device. The gimbal assembly includes a motor assembly, a first housing defining an internal compartment that is configured and dimensioned to receive the motor assembly, and a second housing that is mechanically connected to the motor assembly such that actuation of the motor assembly causes relative rotation between the first and second housings. The first housing includes a first guide that is configured and dimensioned to support transmission media adapted to communicate electrical and/or digital signals. The second housing defines a channel that is configured and dimensioned to receive the first guide such that the first guide extends into the second housing through the channel. The transmission media is supported on the first guide such that the first guide routes the transmission media from the first housing into the second housing.

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 tool changing system with rigidity improved belt moving mechanism includes a pedestal, a sliding base, a driving unit, a positioning belt, and a transmission belt. The sliding base is disposed on the pedestal, and reciprocatively moves along a linear direction. The driving unit is disposed on the sliding base. The positioning belt and the transmission belt are disposed on the pedestal and include a gear rack, respectively. A detouring section of the transmission belt is separated from the positioning belt, and transmissibly meshed with the driving wheel of the driving unit. When the driving wheel rotates, the detouring section is driven to continuously shift on the transmission belt, and the sliding base is simultaneously driven to slide on the pedestal along the linear direction. Thus, a combination of the positioning belt and the transmission belt achieves an improved rigidity.

A modular linking system provides a positioning and supporting structure for mounting various components, particularly on a wheelchair structure. A wheelchair kit includes such a modular linking system and further wheelchair includes at least one modular linking system or at least one wheelchair kit.

A binocular adapter including a base and a receiver joined together by a stanchion arm. The receiver being configured to receive a binocular stem in a stem aperture defined by a receiver head. The receiver head configured to rotate relative to a receiver stanchion. The binocular stem including a first and a second end. The first end including a connector configured to connect to a binocular. The second end, distal to the first end, including a stem extension configured to be received by the stem aperture. The second end further including a groove configured to be received in a spring clip disposed on the receiver stanchion for retaining the binocular stem. The receiver head including a fastener for securing the binocular stem within the stem aperture while it is engaged in the spring clip.