An ambient lighting system for automobiles configured to illuminate a passenger compartment, comprises: an optical system in turn comprising: a plurality of RGB LED light sources; a structural support on which the light sources are placed; and a contact surface on which a user can interact, and through which light rays can exit. The ambient lighting system also includes: a control unit configured to control the RGB LED light sources in order to present light animations; and a touch sensor configured to detect touch of the contact surface in a defined region, which is configured to define, along the optical system at least one soft key. The ambient lighting system further includes: a voice command recognition system electronically connected to the control unit and configured to recognize voice commands; and a projector configured to project an image, such as a symbol and/or logo, on the contact surface.

A shift control system for an automatic transmission is provided. The system includes a shift switch through which a manual transmission command for arbitrarily changing a gear stage of the automatic transmission can be inputted in a manual transmission mode. The manual transmission mode includes a first manual mode in which the gear stage is changed and maintained by inputting the manual transmission command using the shift switch, and a second manual mode in which an automatic transmission mode is resumed by satisfying a resuming condition after the gear stage is changed. The system includes a mode input device configured to select in advance one of the first manual mode and the second manual mode to be set, the mode input device setting to the automatic transmission mode by the selected mode being changed from the first manual mode to the second manual mode, or vice versa.

The invention relates to a user interface for a vehicle adapted to present visible information; the user interface comprises a two-dimensional display for displaying information on a display portion, and an optical faceplate comprising a contact surface, a three-dimensional display surface for displaying information, and an optic light guide material provided between the contact surface and the three-dimensional display surface; wherein the two-dimensional display comprises a pixel arrangement and a cover layer covering the pixel arrangement; wherein the contact surface contacts the display to transmit information from the pixel arrangement to the three-dimensional display surface; wherein the faceplate is integrated into the display. The invention also relates to a vehicle.

An input apparatus includes an operation interface configured to receive an input operation from a user, a piezoelectric element attached to the operation interface, and a controller configured to acquire output based on the input operation to the operation interface from the piezoelectric element and to execute different control with respect to a controlled apparatus in accordance with the output.

A driver monitoring device has a processor configured to acquire number of passengers that are occupying a vehicle when the vehicle has begun to travel, to determine whether or not a driver is sitting in a driving seat based on an image near the driving seat of the vehicle which has been taken by an imaging unit and, when it has been determined that the driver is not seated in the driving seat, to determine that the driver is not seated in the driving seat if number of seated people, representing number of people that are sitting as detected by a seating sensor situated in each seat other than the driving seat of the vehicle, matches the number of passengers, and to determine that the driver is seated in the driving seat if the number of seated people is one less than the number of passengers.

A vehicle interior component configured to provide a user interface for vehicle systems is disclosed. The component may provide a user interface for a vehicle occupant. The component may comprise a composite structure to provide the user interface comprising a cover providing an exterior surface, a sensor, light panel, absorber panel and/or decorative material. The light panel may provide output visible at the exterior surface; the decorative layer and/or absorber panel may provide a visual effect. The cover may comprise a light-transmissive cover; illumination from a display may comprise visible light transmitted through a functional layer and through an at least partially translucent cover. The component may comprise a light panel to provide output visible at the cover exterior surface. A method of operating the user interface provided by the composite structure is also disclosed. The user interface may be coupled to a control system.

An ambient lighting system for automobiles configured to illuminate a passenger compartment, comprises: an optical system in turn comprising: a plurality of RGB LED light sources; a structural support on which the light sources are placed; and a contact surface on which a user can interact, and through which light rays can exit. The ambient lighting system also includes: a control unit configured to control the RGB LED light sources in order to present light animations; and a touch sensor configured to detect touch of the contact surface in a defined region, which is configured to define, along the optical system at least one soft key. The ambient lighting system further includes: a voice command recognition system electronically connected to the control unit and configured to recognize voice commands; and a projector configured to project an image, such as a symbol and/or logo, on the contact surface.

A component for a vehicle interior may comprise a housing; a cover structure comprising a cover surface; and a user interface at the cover surface comprising a light display. The light display may comprise a light guide comprising a projection. The cover structure may comprise a cover base and a cover layer. The cover layer may be molded on the cover base. The cover base may comprise the light guide. The cover layer may comprise an aperture. The projection may extend into the aperture. The cover base may comprise an aperture, recess, notch and/or indentation. The cover layer may comprise a generally opaque material preventing visibility of a recess in the cover base. The cover base may comprise a different color and/or softness than the cover layer. The cover structure may comprise apertures and/or recesses for the light guide.

A surface of a vehicle component can be dynamically deformable surface. The dynamically deformable surface can be configured to undergo deformations to dynamically form a dynamic button or other user interface element on demand. The dynamically deformable surface can include one or more biosensors. When a user engages the dynamic button with a portion of the body, the one or more biosensors can acquire user biodata. The user biodata can be used by the vehicle as input for various purposes. For instance, the vehicle can operate as a health-monitoring and/or comfort monitoring system. As a result of these arrangements, buttons and other user interface elements can appear and disappear depending on the need and/or application, providing a cleaner vehicle cockpit interface and greatly expanding the possibilities of where such buttons can be located at and how many things can be controlled by the driver using physical interfaces.

The invention relates to an operating unit for a vehicle, provided with an operating element (12) having an operating interface (14) with multiple symbol fields (16), to which are assigned operating functions that can be triggered with the actuation of the operating element (12). The operating element (12) is arranged on a support structure (18) such that it can be pressed down in a resettable manner and by means of an actuation object, in particular by means of the finger of a hand. The operating unit (10) is also provided with a mechanical switch (22) which can be actuated when pressing down the operating element (12), a controllable press-down force threshold switching device (34) for switching the force to be overcome to press down the operating element (12) between a first threshold value and a second threshold value that is smaller in comparison to the first threshold value, an actuation sensor system (30) for detecting whether, when the operating element (12) is actuated, the actuation object contacts same within one of the symbol fields (16) of the operating interface (14), and an evaluation and control unit (32) which receives signals from the actuation sensor system (30) or, inter alia, from the actuation sensor system (30), and which only causes the press-down force threshold switching device (34) or, inter alia, the press-down force threshold switching device (34) to switch from the first threshold value to the second threshold value by changing its control, when the actuation object within one of the symbol fields is in contact with the operating interface (14) within one of the symbol fields (16) with an actuation of the operating element (12). An electromagnet or permanent holding electromagnet (40) is used as the press-down force threshold switching device (34).