A device for controlling the activation/deactivation of at least one function performed by electronic equipment of a vehicle comprises a screen able to display a first menu for activating/deactivating said functions, the first, menu including a plurality of displayed elements comprising, for at least one of the functions, a state of the function chosen from an activated state, a deactivated state and an unavailable state, the device comprising selection means for selecting and activating at least one displayed element, wherein, when the state of a function is the unavailable state, the first menu is designed to display an element associated with said unavailable function and the selection of which makes it possible to display an unavailability window containing unavailability information regarding the unavailable state.

A control unit for an air conditioning system is designed to operate one or more actuators of the air conditioning system automatically in an automatic operating mode in order to set reference ambient conditions in a chamber. The control unit is configured to detect that an automatic change has occurred in an operating state of an actuator of the air conditioning system. The control unit is further configured to output via a user interface of the air conditioning system, information relating to the automatic change in the operating state of the actuator.

A battery control device includes: an input unit that selects and inputs a first battery operation mode that is one of a plurality of battery operation modes that control discharging from a battery to an electric motor and charging from a generator to the battery by an operation of an occupant of the vehicle; a selection status display unit that displays a mode indicator corresponding to each of the plurality of battery operation modes and displays a selection status in the input unit; a confirmation unit that confirms the first battery operation mode when a selected state of the first battery operation mode is maintained for a predetermined time after the first battery operation mode is selected in the input unit; and a battery operation control unit that controls the operation of the battery of the vehicle based on the first battery operation mode confirmed by the confirmation unit.

The skin (1) comprises at least a translucent elastomeric layer (5) composed of a pigmented plastic material and comprising at least one first portion (8) which is configured to be placed in front of a light source (9). The light of this light source (9) produces an image on this first portion (8) of the translucent layer due to the presence of a surface relief (17, 18) on the surface of the translucent layer (5). A clearly visible image can be obtained by providing even small differences in thickness of the translucent layer (5) when the pigmented plastic material thereof has an average spectral attenuation coefficient (α.sub.av) of between 1.0 and 25 mm.sup.−1. The difference in layer thickness (d.sub.2-d.sub.1) and the average spectral attenuation coefficient (α.sub.av) should moreover be large enough to meet the formula: α.sub.av(d .sub.2−d.sub.1)>-In a, wherein a is equal to 0.50. Since the surface relief (18an automatically be produced when moulding the translucent layer (5) against a mould surface, the image can easily be obtained in the correct position on the skin (1).

Disclosed is a method for operating an operating system in a vehicle, wherein display data of a graphical user interface comprising at least one first display region are generated and output. The graphical user interface comprises a basic state and an info state. Context data about a current context of the vehicle are recorded and a first relevance value is determined for a first info application based on the recorded context data. The info state is activated depending on the determined first relevance value of the first info application, wherein, when the info state is activated, the first display region is reduced in size such that an info region is formed and a graphical info object is generated using the first info application and output in the info region.

A vehicle input control device includes: an operation reception unit that receives input from operation switches provided in a vicinity of a driver's seat of a vehicle; a function switching reception unit that receives input from function switching switches that switch functions allocated to the operation switches; and a function switching restriction unit that restricts switching of the functions by the function switching reception unit in a case in which a driving mode of the vehicle is a predetermined driving mode.

A vehicular display control device includes a memory; and a processor coupled to the memory, the processor being configured to: acquire a function allocation status of a multifunction switch capable of being allocated any press-implemented function, in order to display an image of a switch array including the multifunction switch on a display device, and display a first symbol in a display region corresponding to the multifunction switch in the switch array image in a case in which the multifunction switch has not been allocated a press-implemented function.

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.

A trim element having a first aspect layer, a lighting device emitting light to the first aspect layer, and a first obturation layer extending between the lighting device and the first aspect layer. The first obturation layer includes at least two first optical obturation areas, configurable between an open position, in which a first optical obturation area lets light pass through, and a closed position, in which a first optical obturation area prevents the passage of light. The trim element includes a second aspect layer and a second obturation layer having at least two second optical obturation areas that are configurable between an open position and a closed position.

A trim panel intended to be arranged within the interior of a vehicle cabin, the trim panel having an appearance face intended to be visible to an occupant of the cabin, a reverse face provided with an interface for attachment of the trim panel to a support member, and at least one attachment bracket forming part of the attachment interface. The appearance face defines a tactile interaction area intended to serve as a control input for the occupant, and at least one sensor assembly is arranged on an attachment bracket, each sensor assembly being adapted to, when the trim panel is arranged inside a cabin, detect a deformation of its attachment bracket upon pressure exerted by an occupant on the trim panel on the tactile interaction area.