Implementations relate to interactions, over a wireless communication modality, between an automated assistant of an automobile computer system, and separate client device(s). In some of those implementations, the client device(s) can be paired with the automobile computer system, and the client device(s) and the automobile computer system can include separate instances of an automated assistant, which can be associated with different user accounts. In some additional or alternative implementations, particular actions to be performed by a local application of a client device can be advanced via user interaction with the automobile automated assistant, despite a counterpart to the local application not being installed directly on automobile computer system. For example, despite an automobile computer system not having a third-party messaging application installed, the automobile automated assistant can access requested actions to be performed by the third-party messaging application in order to further a requested action. The automobile computer system can transmit, via the wireless communication modality, content to cause the third-party application to further the requested action.

A driving support apparatus includes a communication device configured to communicate with a vehicle-mounted device installed in a vehicle that's under automatic driving control; and a processor configured to determine, upon receiving a stop request by a passenger who is riding in the vehicle from a mobile terminal of the passenger or the vehicle-mounted device of the vehicle through the communication device, a stop location in accordance with the stop request; generate a driving route of the vehicle from a present location of the vehicle to the stop location; and calculate a stop time required to stop the vehicle at the stop location, based on the driving route to the stop location, and when the stop time is less than an allocated time for the stop request, send a stop command for moving the vehicle to the stop location to the vehicle-mounted device of the vehicle through the communication device.

A method for controlling a display of a vehicle infotainment system may include: establishing, by a controller of the vehicle infotainment system, a wireless communication session with a first user device; receiving, by the controller, an indication of a representative color from the first user device via the established wireless communication session; and controlling, by the controller, the vehicle infotainment system such that a display screen of a display device of the vehicle infotainment system displays the representative color.

The disclosure relates generally to an in-vehicle feedback system, and more particularly, to an in-vehicle device with a display or graphical interface that collects driving data and provides feedback based on the driving data. The system may comprise an in-vehicle device that includes a graphical user interface and a processor and a data collection device wirelessly connected to the in-vehicle device. The in-vehicle device may be configured to receive vehicle telematics data from the data collection device and the processor may process the telematics data in real time and cause the telematics data to be displayed on the graphical user interface. The graphical user interface may include a speed display and an acceleration display.

A vehicle control device that includes a communication unit that is configured to (i) communicate with a mobile device and (ii) receive data including user input that is received at the mobile device; and a processor that is configured to: based on receipt of the data including the user input, determine whether a vehicle with which the mobile device is associated operates in a manual driving mode or an autonomous driving mode and whether the user input received at the mobile device satisfies a preset condition; and based on determinations that the vehicle is in the manual driving mode and that the user input received at the mobile device satisfies the preset condition, switch the vehicle from the manual driving mode to the autonomous driving mode is disclosed.

A method for pairing authentication between a vehicle and a mobile device is proposed. After a host computer of the vehicle is operated to send out a vehicle identification code for pairing and the mobile device is operated to select the vehicle identification code, the host computer enables both of a host display of the vehicle and the mobile device to display a pairing code at the same time. After a pairing procedure is performed within a predetermined pairing operation period, the host computer completes pairing authentication between the host computer and the mobile device.

Embodiments are disclosed for systems and methods for operating a display actuator to provide user-configurable actions. An example device for a human-machine interface includes a display on a first surface of the device, an input interface adapted to detect one or more of touch input, rotation input, and push input directed to the device, a controller configured to generate control instructions based on input received from the input interface, the control instructions including display instructions for controlling output on the display, and an output interface configured to send at least a subset of the control instructions from the controller to a receiving device, the device being removably coupled to the receiving device.

Embodiments are directed towards providing a dynamic application environment where separate components of an application can execute on separate processing hardware at any given point in time. A host device monitors current operating characteristics associated with a computing device, such a head unit of an automobile, and based on those characteristics selects which components of one or more applications to execute on the computing device and which components to execute on the host device, if any. The host device provides the selected components to the computing device for execution by the computing device and the host device executes any other components that are not executed by the computing device. The host device monitors the current operating characteristics associated with the computing device, and modifies the selection of which components are executing on which device based on changes in current operating characteristics.

One or more devices in a data analysis computing system may be configured to receive and analyze movement data and driving data, and determine driving trips and associated drivers based on the received data. Movement data may be collected by one or more mobile devices, such as smartphones, tablet computers, and on-board vehicle systems. Drivers associated with driving trips may be identified based on the movement data collected by the mobile devices, such as speed data, acceleration data, or distance data.

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.