Provided is a display device. The display device includes: a display panel; a motor-driven module, which is configured to be connected to the display panel and drive the display panel to move; a control module, which is configured to control the motor-driven module; a first module and a second module disposed opposite to each other in a first direction, where the first module and the second module are able to move relatively in a second direction; a first unit, which is disposed on a side of the first module facing the second module; a second unit, which is disposed on a side of the second module facing the first module; and in response to a position relationship between the first unit and the second unit, providing, by the control module, a first control signal for the motor-driven module, where the first direction intersects the second direction.

A module for an automated laboratory system is disclosed. The module comprises a module connector configured to releasably connect to a component of the automated laboratory system, a detector at least configured to detect at least one component marker located at the component so as to obtain position data of the module indicating an actual position of the module, a processor configured to calculate a position deviation of the module from a target position defined by the component based on the position data and to calculate position alignment data based on the position deviation, and a alignment device configured to align the module to the target position based on the position alignment data. Further, an automated laboratory system and a method for aligning a module are disclosed.

A module for an automated laboratory system is disclosed. The module comprises a module connector configured to releasably connect to a component of the automated laboratory system, a detector at least configured to detect at least one component marker located at the component so as to obtain position data of the module indicating an actual position of the module, a processor configured to calculate a position deviation of the module from a target position defined by the component based on the position data and to calculate position alignment data based on the position deviation, and a alignment device configured to align the module to the target position based on the position alignment data. Further, an automated laboratory system and a method for aligning a module are disclosed.

A method for controlling a device, in particular a prosthetic hand or a robotic arm, includes using an operator-mounted camera to detect at least one marker positioned on or in relation to the device. Starting from the detection of the at least one marker, a predefined movement of the operator together with the camera is detected and is used to trigger a corresponding action of the device. The predefined movement of the operator is detected in the form of a line of sight by means of camera tracking. A system for controlling a device, in particular a prosthetic hand or a robotic arm, includes a pair of AR glasses adapted to detect the at least one marker and to detect the predefined movement of the operator.

A method for controlling a device, in particular a prosthetic hand or a robotic arm, includes using an operator-mounted camera to detect at least one marker positioned on or in relation to the device. Starting from the detection of the at least one marker, a predefined movement of the operator together with the camera is detected and is used to trigger a corresponding action of the device. The predefined movement of the operator is detected in the form of a line of sight by means of camera tracking. A system for controlling a device, in particular a prosthetic hand or a robotic arm, includes a pair of AR glasses adapted to detect the at least one marker and to detect the predefined movement of the operator.

A system has a hydraulic circuit configured to control a position of an attachment of the system and a control system configured to perform operations that include receiving an input indicative of a center of gravity of the attachment and controlling a flow rate of fluid directed through the hydraulic circuit based on the center of gravity.

A transfer operation of moving the slider between one fixed linear module and a movable linear module while locating the movable linear module in the facing range facing the one fixed linear module is performed. At this time, it is judged whether or not the coordinate axis of the one fixed linear module and the coordinate axis of the movable linear module are continuous If it is judged before the transfer operation that the coordinate axes are not continuous, the transfer operation is performed after the coordinate axes are made continuous in the direction by changing the coordinate axis. Thus, it is possible to suppress the occurrence of a situation where the transfer operation of moving the slider between the fixed linear module and the movable linear module cannot be performed due to the discontinuity of the coordinate axes respectively set for the fixed and movable linear modules.

A transfer operation of moving the slider between one fixed linear module and a movable linear module while locating the movable linear module in the facing range facing the one fixed linear module is performed. At this time, it is judged whether or not the coordinate axis of the one fixed linear module and the coordinate axis of the movable linear module are continuous If it is judged before the transfer operation that the coordinate axes are not continuous, the transfer operation is performed after the coordinate axes are made continuous in the direction by changing the coordinate axis. Thus, it is possible to suppress the occurrence of a situation where the transfer operation of moving the slider between the fixed linear module and the movable linear module cannot be performed due to the discontinuity of the coordinate axes respectively set for the fixed and movable linear modules.

Certain aspects of the present disclosure provide a method for setting a working distance of an additive manufacturing system, including: moving a deposition element towards a build surface; detecting, via a contact detection system, a contact between the deposition element and the build surface; stopping the moving of the deposition element in response to detecting the contact between the deposition element and the build surface; and moving the deposition element away from the build surface a determined working distance.

Certain aspects of the present disclosure provide a method for setting a working distance of an additive manufacturing system, including: moving a deposition element towards a build surface; detecting, via a contact detection system, a contact between the deposition element and the build surface; stopping the moving of the deposition element in response to detecting the contact between the deposition element and the build surface; and moving the deposition element away from the build surface a determined working distance.