A determination is made as to whether a driver or a front-seat passenger of the motor vehicle would like to operate a display device. If it is detected that only the driver would like to operate the display device, the display device is put in a first operating mode in which a graphic user interface is displayed exclusively in a driver-side display region of the display device. If it is detected that only the front-seat passenger of the motor vehicle would like to operate the display device, the display device is put in a second operating mode in which the graphic user interface is displayed exclusively in a front-seat-passenger-side display region of the display device. If it is detected that the driver and the front-seat passenger of the motor vehicle both would like to operate the display device, the display device is put in a third operating mode in which the graphic user interface is displayed in the driver-side display region and at least part of the graphic user interface is additionally also displayed in the front-seat-passenger-side display region.

The present disclosure relates to a configurable user interface for a vehicle (V). The configurable user interface includes a plurality of control devices for controlling a first set of vehicle systems (S-n). The control devices are each associated with at least one of the vehicle systems (S-n) in said first set. At least one processor is provided for identifying a subset of the first set of vehicle systems (S-n) consisting of the vehicle system(s) (S-n) installed on the vehicle (V). A memory is connected to the at least one processor. The at least one processor is configured to enable any of said control devices associated with the vehicle systems (S-n) contained in said subset; and/or to disable any of said control devices associated with the vehicle systems (S-n) not contained in said subset. The present disclosure also relates to a steering wheel of a vehicle (V) incorporating a configurable user interface. A vehicle (V) and a method of configuring a user interface are also disclosed.

A touch-sensitive vehicle display device is disclosed. The touch-sensitive vehicle display device comprises a body having a display including a touch panel on a surface thereof, whereby a screen operation is performed on the surface of the display by a touch-screen operation; an operation plate provided along the surface of the display; and a controller controlling information to be indicated on the display. The operation plate includes an opening section to indicate a switch provided to face the touch panel, and a plurality of touch-sensitive switch-confirmation portions provided on an end portion of the opening section for switch indication, and the controller controls a switch-indication portion to be inside the opening section to indicate switching in the display, and controls a plurality of selection-switches to be in the switch-indication portion to correspond to the plurality of switch-confirmation portions.

Various aspects of a device and method to manage interaction with one or more control circuits in a vehicle and one or more wearable devices are disclosed herein. The device comprises one or more circuits configured to receive a first set of input values from the one or more wearable devices associated with a first user. The one or more wearable devices are communicatively coupled to the device used in the vehicle. A second set of input values is received from one or more vehicle sensors embedded in the vehicle. An operating mode of the device is determined based on the received first set of input values and the second set of input values. One or more functions of the vehicle are controlled based on the determined operating mode of the device.

An interchangeable operator interface system for a work vehicle has at least one controller, at least one operator interface device having a plurality of controls, and at least one interface device docking arrangement. The docking arrangement removably mounts different interface devices to alternatively physically connect them to the work vehicle and operatively couple them to the controller. Different operator interface devices have at least one common control that operates in a different mode of operation and/or in a different physical layout on the associated operator interface device. The controller is configured to effect an associated common change in state of an associated component of the work vehicle upon receiving a control input from the different common controls.

The invention relates to a system (10) for controlling industrial or all-terrain vehicle functions, which comprises data processing means (20), such as a computer, and a plurality of devices (10a-10g) for controlling industrial or all-terrain vehicle functions. The control devices are arranged in a network with the data processing means (20) according to a master-slave model, and each control device comprises at least one first control member (3a) sensitive to contact and connectors (2), a computing circuit (1) with at least one data processing unit (MC), a memory in which is stored a unique identifier associated with said control device, and at least one first control state visualization member (4a). The data processing means (20) are configured to transmit to each identified control device (10a-10g) a request to obtain a feedback of information from the associated processing unit.

An adjustment device for activating or deactivating at least one of a driver assistance system and a driver assistance mode for autonomous driving in a vehicle may include a push-button. The push-button may be configured to select at least one of the driver assistance system and the driver assistance mode upon rotation of the push-button. The push button may also be configured to activate or deactivate at least one of the driver assistance system and the driver assistance mode upon linear movement of the push-button due to a pushing action by an operator.

An apparatus including a display, an antenna, and processing circuitry that receives, via the antenna, a near-field communication data packet from an antenna of a secondary device, the near-field communication data packet including information regarding a functional type of the secondary device, and updates graphics of the display based on the functional type of the secondary device.

A method for adapting an operating device in a motor vehicle. The operating device is provided for operating at least one vehicle function of the motor vehicle. In at least one driving situation, observation data which describe the current driving situation and usage data which describe which of the vehicle functions is currently activated via the operating device are in each case detected by the operating device, and an assignment rule is generated on the basis of the observation data and the usage data by a procedure of automatic learning.

A control and display device for a vehicle includes a control element and an associated display area. In the display area are superimposed: a first layer that is opaque except for a translucent complex pictogram, the complex pictogram combining two separate elementary pictograms; two separate filtering areas, each filtering area having the shape of a corresponding single elementary pictogram, each filtering area transmitting wavelengths within a respective range, the respective ranges of wavelengths being disjoint; and a light source suitable for emitting within the respective different ranges of wavelengths, concomitantly or alternately. The two filtering areas are positioned between the light source and the complex pictogram on the opaque layer.