A vehicle control device includes processor being configured to: perform automated driving control for automatically performing a driving operation of the vehicle; and provide a driving event which will occur at a point ahead in the direction of advance from a current point based on a driving plan for automated driving through the information provision device to the driver. The processor is further configured to: judge the suitability of the driving operation corresponding to the driving event being performed by the driver at a point before the point of the driving event; and provide the driver with judgment information so that the driver does not perform the driving operation corresponding to the driving event at a point before the point of the driving event when judging it is not suitable to perform it.

The present disclosure provides systems and methods to obtain feedback descriptive of autonomous vehicle failures. In particular, the systems and methods of the present disclosure can detect that a vehicle failure event occurred at an autonomous vehicle and, in response, provide an interactive user interface that enables a human located within the autonomous vehicle to enter feedback that describes the vehicle failure event. Thus, the systems and methods of the present disclosure can actively prompt and/or enable entry of feedback in response to a particular instance of a vehicle failure event, thereby enabling improved and streamlined collection of information about autonomous vehicle failures.

A vehicle-mounted display device, a vehicle steering wheel assembly, and a vehicle. The vehicle-mounted display device comprises a decorative piece (1), wherein the decorative piece (1) comprises a connection portion (4), a touch-control display screen (2), a first mounting position (11) and a second mounting position (12); the decorative piece (1) is mounted on a base (13) of a vehicle steering wheel (3) by means of the connection portion (4); the first mounting position (11) is used for mounting the touch-control display screen (2), and the second mounting position (12) is used for mounting a vehicle airbag; and the first mounting position (11) and the second mounting position (12) are arranged side by side on the decorative piece (1), and the first mounting position (11) is located above the second mounting position (12) in the direction in which the first mounting position (11) and the second mounting position (12) are arranged.

A display control device that includes: a memory; and a processor that is coupled to the memory, the processor being configured to in a case in which a contact with, or a movement adjacent to, any of a plurality of operating portions provided inside a vehicle cabin is detected, display information corresponding to that operating portion on a display portion inside the vehicle cabin, and, in a case in which a contact with, or a movement adjacent to, two or more of the operating portions is detected, arbitrate the displaying of information on the display portion.

A side window display system on vehicles is provided. The side window display system on vehicles includes a transparent display, at least one external sensor, at least one internal sensor and a controller. The transparent display is provided on a side window of a vehicle. The external sensor is used to detect an external environment of the vehicle to provide external environment information. The internal sensor is used to detect an internal environment of the vehicle to provide internal environment information. The controller is coupled to the transparent display, the external sensor, and the internal sensor to select an operation mode based on the internal environment information, and controls the transparency distribution and brightness distribution of the transparent display based on the operation mode and the external environment information.

The invention relates to a method for setting functions of a vehicle that includes system of digital rear-view mirrors comprising at least one camera (102, 103) capturing images from outside the vehicle, a first touch screen (104) placed on the driver's side, dedicated to displaying the outside environment on the driver's side, a second touch screen (105) placed on the passenger's side, dedicated to displaying the outside environment on the passenger's side, and a computer processing images captured by said camera and displaying them on said screens (104, 105). The method comprises a step of displaying, on one of the touch screens (104, 105), functional settings of the system of digital rear-view mirrors in response to detecting a first command, characterized in that it further comprises a step of displaying comfort and/or safety function settings of the vehicle in response to detecting a second command.

A vehicle surrounding environment display device configured to generate a virtual space corresponding to a surrounding environment of a host vehicle on the basis of detection information from an external sensor of the host vehicle and display an image inside the virtual space viewed from a virtual viewpoint operated by a user of the host vehicle on a display, wherein a three-dimensional host vehicle icon corresponding to the host vehicle is disposed in the virtual space, and when the virtual viewpoint is located in an icon transformation region set above the rear or front of the host vehicle icon, the host vehicle icon is transformed so that a width of an upper surface of the host vehicle icon is narrower as compared to when the virtual viewpoint is not located in the icon transformation region.

Systems and methods for context sensitive user interfaces for enhanced vehicle operation. An example method is method implemented by a system of one or more processors, the system being included in a vehicle. The method includes causing presentation, via a display of the vehicle, of a unified user interface comprising a combined view which aggregates an autonomous visualization and map information, the autonomous visualization and map information being related to a zoom level, with the unified user interface being generated based on first contextual information indicative of operation of the vehicle. Second contextual information indicative of subsequent operation of the vehicle is accessed. The unified user interface is updated based on the second contextual information, with the combined view being adjusted, and with adjusting the combined view including adjusting a size of the combined view in the unified user interface or adjusting the zoom level.

A device, system, and method for controlling a vehicle display and a mobile display into a threat mode is provided. A system comprises a vehicle display of a vehicle; and a mobile device communicatively coupled to the vehicle, the mobile device comprising: a mobile display. The system further comprises a controller that determines a threat associated with the vehicle; and a threat type; and in response to determining the threat, controls the vehicle display and the mobile display to switch to a threat mode by: controlling the vehicle display to: provide one or more graphical threat indications indicating one or more of: the threat; and the threat type; and controls the mobile display to: provide one or more threat-related applications associated with the threat, that may be for one or more of interacting with, and modifying, one or more graphical threat indications at the vehicle display.

A vehicle system includes a controller programmed to display a plurality of icons on a heads-up-display (HUD) of the vehicle, receive electroencephalography (EEG) data from a driver of the vehicle, perform a Fast Fourier Transform of the EEG data to obtain an EEG spectrum, input the EEG spectrum into a trained machine learning model, determine which of the plurality of icons the driver is viewing based on an output of the trained machine learning model, and perform one or more vehicle operations based on the output of the trained machine learning model.