A mobile device to be in cooperation with a vehicle selects and performs one of cooperative functions, acquires upward, downward, leftward, and rightward instructions from the vehicle, generates a sound output toward a driver, and acquires a voice input from the driver. The plurality of cooperative functions are classified into a menu hierarchy, a target selection hierarchy, and an active hierarchy. The mobile device transitions from the menu hierarchy to the target selection hierarchy and from the target selection hierarchy to the active hierarchy in the cooperative functions, based on an instruction in one specific direction of the upward, downward, leftward, and rightward instructions, and transitions to a voice search in the target selection hierarchy, based on an instruction in the specific direction.

A smart mobility vehicle includes a windshield including an electrochromic film having adjustable transparency based on power applied thereto, and a projector configured to project vehicle driving information onto the windshield, wherein the windshield comprises an internal display area and an external display area, the internal display area being configured to display an image toward an inside of the vehicle, the external display area being configured to display an image toward an outside of the vehicle.

Computer-implemented methods include detecting a device ultra-wideband (UWB) transceiver of a mobile device and a set of vehicle UWB transceivers of a vehicle, determining a defined driver zone within the vehicle, the defined driver zone indicating a set of relative positions within the vehicle, communicating between the device UWB transceiver and the set of vehicle UWB transceivers to determine a position of the mobile device within the vehicle, and automatically enabling a driver mode of the mobile device whereby operation of the mobile device is limited when the determined position of the mobile device is within the defined driver zone and the vehicle is moving.

A system for using a mobile phone in a vehicle includes an auxiliary jack having multiple conductors and configured to receive a connector having a first end to be coupled to the auxiliary jack and a second end to be coupled to a mobile device. The system further includes a ground coupled to a first conductor of the multiple conductors, and a microphone coupled to a second conductor of the multiple conductors that receives microphone data from a cabin of the vehicle to be transmitted to the remote device via the connector. The system further includes a first speaker coupled to a third conductor of the multiple conductors that outputs audio data received from the third conductor, and an IVI interface configured to receive user instructions for controlling the mobile device and to transmit the user instructions to the mobile device via at least one of the multiple conductors.

In some examples, a vehicle head unit of a vehicle includes at least one processor; and at least one module operable to: responsive to authenticating a first user at a vehicle head unit of a vehicle, establish a session with a first user identifier, the first user identifier associated with the first user; responsive to authenticating a second user at the vehicle head unit, associate a second user identifier with the session, the second user identifier associated with the second user, wherein the first and second user identifiers are concurrently associated with the session; generate data while the first and second user identifiers are concurrently associated with the session; and store, based on the first user identifier and the second user identifier, the data to both a first user account associated with the first user identifier and a second user account associated with the second user identifier.

A compartment in a vehicle can be loaded by an object and an operating device having a user interface configured to output at least one output signal on a part of the user interface. The operating device is designed to cover the compartment. The compartment includes a sensing unit configured to detect the presence of the object when at least a part of the object is loaded into the compartment and the operating device includes control circuitry configured to display a digital image of the object on a part of the user interface.

Techniques are described that facilitate remotely interfacing with a vehicle touchscreen. According to an embodiment, a method is provided comprising determining touch controls included in a GUI configured for displaying on a touchscreen of the vehicle, wherein the touch controls provide for controlling functions of the vehicle based on first interaction with the touch controls as displayed on the touchscreen. The method further comprises generating a representation of the GUI for display via an auxiliary display of the auxiliary device, the representation comprising one or more graphical controls corresponding to one or more touch controls of the touch controls, and enabling remote control of one or more functions of the functions of the vehicle by the auxiliary device based on second interaction with the one or more graphical controls as displayed via the auxiliary display.

Described are various embodiments related to a vehicle device and an electronic device, wherein the vehicle device according to one embodiment can include: a display; a memory; at least one or more sensors; communication circuitry configured to communicate with an external electronic device; and a processor configured to display first display information according to execution of a first application on a first area on the display, perform control to transfer vehicle-related context information to the electronic device based on information obtained by the at least one or more sensors and, if information related to a second application corresponding to the vehicle-related context information is received from the electronic device, display second display information associated with the second application on a second area on the display using the received information.

A display apparatus and a mobile phone for content adjustment based on motion of a vehicle and an eye gaze of an occupant is provided. The display apparatus includes a display screen, a motion sensor, and an image capturing device. The display screen displays content. The display apparatus controls the motion sensor to capture a motion signal associated with the display apparatus. The display apparatus controls the image capturing device to capture an image of the occupant in the vehicle. The display apparatus determines a region of the eye gaze of the occupant on the display screen based on the captured image. The determined region on the display screen includes a portion of the displayed content. The display apparatus adjusts a movement of the portion of the displayed content in response to the captured motion signal being higher than a predefined threshold.

Provided is a head-up display for a vehicle. The head-up display may include a camera configured to capture an image of a road ahead of the vehicle. The camera may further be configured to be in communication with a processor. The head-up display may also include a display in communication with the processor. The processor may be configured to select a route on a map between a current position of the vehicle and a destination selected by a user, receive the image from the camera, correlate the image to an area of the map, and control the display to display an indication indicating the route. Based on correlation of the image to the area of the map, the indication on the display may be substantially aligned with the road when viewed from front of the display. Other embodiments are disclosed and additional embodiments are also possible.