A vehicle dashboard assembly includes a dashboard panel, a display support, a display and a display cover. The dashboard panel has a display receiving space. The display support is coupled to the dashboard panel. The display is removably and reinstallably attached to the display support. The display cover is movably coupled relative to the dashboard panel between a closed position and an open position. The display cover includes a first cover portion for covering a front side of the display and a second cover portion for covering one edge of the display. The first cover portion surrounds a screen of the display while in the closed position to define a display opening for viewing the screen. The first and second cover portions are movable as a unit between the closed and open positions.

Compact, multi-function rotational controllers or switches that allow an operator of a vehicle to simultaneously view the status of a plurality of related functions, and to easily change or toggle the status of each of the functions. A multi-function controller of the present disclosure may include a rotatable central control dial that is at least partially surrounded by a visual indicator panel that indicates a current status for the functions that are controlled by the multi-function controller. The multi-function controller may include a selected function indicator that indicates which of the plurality of related functions is currently selected, control input hardware that receives operator input, and control circuitry that toggles the state of the selected function responsive to such operator input. The multi-function controller may include an “all functions off” function that allows the operator to simultaneously turn all of the related functions off via a single input action.

A vehicle interior component includes a first surface, a second surface that is adjacent to the first surface, an edge disposed between the first surface and the second surface, and an operating element where an item of operating information can be input by the operating element. The operating element is disposed adjacent to the edge on the first surface and/or on the second surface and the operating element is nonvisible in an inoperative state and is visible in an operative state.

A multi mode screen device for a vehicle, the device including a display screen unit with a display screen. The display screen unit is configured to switch an operational state between a first operational mode related to a manual vehicle driving functionality and a second operational mode related to an autonomous vehicle driving functionality. The display screen has a portrait orientation in the first operational mode and a landscape orientation in the second operational mode, and the display screen unit is adapted to be rotatably displaced between the portrait orientation and the landscape orientation.

A vehicle electronic control system includes a center device and a master device and a data relay device capable of performing data communication therebetween. The center device obtains campaign information of the program update, transmits the obtained campaign information to the data relay device, and transmits the update data to the data relay device. When receiving the campaign information from the center device, the data relay device changes setting of the received campaign information and delivers the information to the master device, and, when receiving the update data from the center device, the data relay device delivers the received update data to the master device. When receiving the campaign information from the data relay device, the master device instructs a target electronic control device to update the program with the update data received from the data relay device according to the received campaign information.

An opening switch for a vehicle having a decorative cover assembly, a sensor housing region, and a microelectromechanical (MEMS) sensor mounted in the sensor housing region. The decorative cover assembly has an inner surface, an outer surface, an anchor portion, and a deflection portion. When contact from a vehicle user occurs at the deflection portion in the decorative cover assembly, a microdeflection occurs. The microdeflection has a microdeflection apex, and the microdeflection apex is spaced from other surfaces in the sensor housing region when the contact from the user occurs at the deflection portion in the decorative cover assembly. The MEMS sensor is configured to generate an output signal that is indicative of a force of the contact from the user. The force integrated switch can include haptic feedback and/or backlighting.

A system for remote interaction with a pointing means of an aircraft cockpit display system, equipped with HMIs, includes three layers: a lower layer configured so as to receive wired electric power supply and data exchange connections; an upper layer comprising a hand-rest knob, at least one physical interaction means configured so as to interact on the pointing means for pointing at the HMIs of the cockpit, and a module with a touch-sensitive flat surface configured so as to interact on the pointing device for pointing at the HMIs of the cockpit and arranged in the extension of the hand-rest knob; and an intermediate layer configured so as to make it possible to modify the position of the upper layer.

A vehicle control apparatus is to be provided in a vehicle including a wireless charger that charges a mobile device placed on the wireless charger. The vehicle control apparatus includes an interruption detector, a cause determination unit, and a notification controller. The interruption detector detects interruption of charging of the mobile device by the wireless charger, based on an operating state of the wireless charger. The cause determination unit determines whether a cause of the interruption of the charging is a first or second cause. The first cause is that the mobile device is moved by inertia during traveling. The second cause is that the mobile device is moved by a passenger. When the cause is determined as being the first cause, the notification controller notifies information about the interruption of the charging in a more prominent manner than when the cause is determined as being the second cause.

A remote control an automotive vehicle, the remote control including a 3-D shaped object, stretch sensors connecting the 3-D shaped object to a structure of the vehicle and a control unit configured to collect information from the stretch sensors, the remote control being configured to control a display of the automotive vehicle, the remote control being configured to be integrated in a stretchable fabric part of an interior of the vehicle.

The technology relates to providing an enhanced user experience for riders in autonomous vehicles. Two or more displays may be arranged at different locations within a vehicle to provide notifications, alerts and control options. Information may be dynamically and automatically switched between these displays, as well as a rider's own personal communication device(s). What information to present on each screen can depend on factors including how many riders are in the vehicle, their seating within the vehicle, how their attention is focused and/or display location and size. Certain information may be mirrored or otherwise duplicated among multiple screens while other information can be presented asymmetrically on different screens. Presented information may include a “monologue” from the vehicle explaining why a driving action is taken or not taken, alerts about important conditions, buttons to control certain functionality of the vehicle, or other information that may be of interest to the rider.