A method for operating an implement of a work machine is disclosed. The method includes detecting a progression of an input device between a first position and a second position based on a first parameter and a second parameter; determining a plurality of segments of the progression; estimating a value of the second parameter of at least one first segment and at least one second segment; issuing a baseline signal to generate command to initiate manipulation of the implement if the value of the second parameter of the first segment complies with corresponding second parameter threshold condition; issuing a secondary signal to continue manipulation of the implement if the value of the second parameter of the second segment complies with corresponding second parameter threshold condition; and terminating the command if the value of the second parameter of at least one second segment violates the corresponding second parameter threshold condition.

The operating unit (10) for a vehicle component is provided with a housing (14) having a frame (16) and a display (62) having a transparent cover pane (18) with an edge (22). A plurality of actuators (24) for introducing flexural waves into the cover pane (18) is arranged along the edge (22) of the cover pane (18). A contact surface (34) is assigned to each actuator (24) on the cover pane (18), by means of which contact surface the actuator (24) acts on the cover pane (18) in order to introduce flexural waves into the cover pane (18). The flexural waves introduced into the cover pane (18) by the actuators (24) are superposed in the cover pane (18) and give the cover pane (18) a tactilely sensible, locally resolved surface structure. The contact surfaces (34) are each arranged at a distance from the frame (16) of the housing (14), and consequently the introduction of flexural waves into the cover pane (18) and/or the propagation of flexural waves in the cover pane (18) is damped for wavelengths or frequencies resulting from the magnitude of the distance. The distance is selected in such a way that flexural waves having frequencies in the audible frequency range are damped.

Vehicle information is displayed on a deformable display of an instrument cluster for a motor vehicle. The instrument cluster includes the deformable display, a support structure, at least one sensor element, and at least one movement element. The deformable display is arranged on the support structure and the support structure is movable from a first position into a second position by using the at least one movement element, based on environmental influences detected by the sensor element.

The operating unit for a vehicle, in particular for a vehicle component, is provided with a housing (10) which has an operating element (12), such as a display for example, and is designed to be secured in a device, in particular in a vehicle dashboard. The operating element (12) is elastically mounted on the housing (10). An actuator (16) is additionally provided for mechanically exciting the operating element (12) when an operation of the operating element (12) has been detected. Finally, the operating unit also has a vibration compensating mass (20) which can be mechanically excited by the actuator or by one actuator (16) when an operation of the operating element (12) has been detected and/or which is mounted on the housing (10) and can be moved in order to substantially compensate for forces acting on the housing (10) when the operating element (12) is moved.

Aspects of the present disclosure relate switching between autonomous and manual driving modes. In order to do so, the vehicle's computer may conduct a series of environmental, system, and driver checks to identify certain conditions. The computer may correct some of these conditions and also provide a driver with a checklist of tasks for completion. Once the tasks have been completed and the conditions are changed, the computer may allow the driver to switch from the manual to the autonomous driving mode. The computer may also make a determination, under certain conditions, that it would be detrimental to the driver's safety or comfort to make a switch from the autonomous driving mode to the manual driving mode.

An over-mount structure for over-mounting a vehicle start/stop button that is mounted in a housing with a gap defined between an outer periphery of the start/stop button and an inner periphery of the housing. The over-mount structure includes a mounting body having a first, generally cylindrical, mounting portion having a wall thickness sized to be received within the gap and having an inner diameter sized to make a removable press-fit engagement with an outer diameter of the start/stop button. The mounting body also includes a second generally cylindrical mounting portion, integral with the first mounting portion and in opposing relation therewith. A faceplate is removably coupled to the second mounting portion to cover an end thereof.

A virtual touch recognition apparatus and a method of correcting a recognition error of the virtual touch recognition apparatus utilize a user's eye position and an image display position or projection position of a head-up display (HUD). The virtual touch recognition apparatus includes a gesture recognizer detecting the eye position of a user, the head-up display projecting an image on the image display position in front of the user, and a controller correcting a recognition error of a virtual touch based on the eye position of the user and the image display position. The apparatus and method can minimize a virtual touch recognition error occurring depending on the user's eye position and the image display position of the HUD when gesture control technology using the virtual touch is applied to a vehicle.

Embodiments of a vehicle interior system are disclosed. In one or more embodiments, the system includes a base with a curved surface, and a display or touch panel disposed on the curved surface. The display includes a cold-bent glass substrate with a thickness of 1.5 mm or less and a first radius of curvature of 20 mm or greater, and a display module and/or touch panel attached to the glass substrate having a second radius of curvature that is within 10% of the first radius of curvature. Methods for forming such systems are also disclosed.

An apparatus includes an information system with at least one pattern generator having a plurality of light nodes, each light node including at least one light emitting element, such as an LED. The at least one pattern generator is positioned with regard to a user of the apparatus such that it is located in the peripheral view of the user. A controller is operatively coupled to the pattern generator and configured to selectively initiate the generation of a visual light pattern on the pattern generator, the visual light pattern being indicative of information which is to be provided to the user of the apparatus.

A method for adjusting a switch position includes adjusting a position of a changeover switch for changing over a travel mode of a vehicle between an automated driving mode in which travel of the vehicle is controlled in an automated manner and a manual driving mode in which travel of the vehicle is operated by a driver is adjusted according to a state of the driver seat.