Techniques are described for remotely controlling functions of a vehicle without an integrated touchscreen. According to an embodiment, an auxiliary device is provided comprising a display and a processor that executes computer executable components stored in at least one memory. The computer executable component can comprise a feature acquisition component that determines electronic features of the vehicle that are respectively controlled by electromechanical controls of the vehicle, and a display component that displays a graphical user interface via the display wherein the graphical user interface comprises one or more graphical controls for controlling one or more features of the electronic features of the vehicle. The computer executable components further comprising a remote-control component that remotely controls the one or more features via interaction with the one or more graphical controls as rendered via the display.

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.

Embodiments are directed towards providing a system that presents customized content to a user of an automobile based on what the user of the automobile is looking at. A first camera captures images of the user of the interior of the automobile, and a second camera captures images of a scene that the user is viewing. The images are analyzed to determine if the user is looking at, or not looking at, an object in the scene. If the user is looking at such an object, content associated with the object is selected and presented to the user.

An image stabilization method adapted to an electronic device is provided. The electronic device includes at least a display and at least a connection interface. The connection interface is connected to the detector. The detector is configured to detect environmental information. The image stabilization method comprises receiving a detecting signal from the detector; and performing an image stabilization procedure corresponding to a visual dislocation event according to the detecting signal. The visual dislocation event refers to a change of the relative position between the viewer and the display from a first position to a second position. An electronic device using the image stabilization method is also provided.

A vehicular control system includes a forward viewing camera disposed at an in-cabin side of a windshield of a vehicle and viewing forward of the vehicle. Road curvature of a road along which the vehicle is traveling is determined responsive at least in part to processing by an image processor of image data captured by the camera. Responsive at least in part to processing of captured image data, a traffic lane of the road along which the vehicle is traveling is determined. Responsive at least in part to processing of captured image data, another vehicle present on the road and forward of the vehicle may be detected. Responsive at least in part to processing of captured image data, the system may determine that the detected other vehicle is travelling in a traffic lane to the left or to the right of the traffic lane along which the vehicle is traveling.

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.

The disclosure relates to a method for displaying safety-relevant information on a display device of a vehicle. A speed of the vehicle, environment data representing an environment of the vehicle, a driver reaction time, and an emergency braking reaction time for an emergency braking driver assistance function are input, and used to superimpose an emergency braking marker and a driver intervention marker on the map representing a lane in which the vehicle is travelling in the display device. The emergency braking marker represents a future point in time and/or future location for an intervention of the emergency braking driver assistance function, and the driver intervention marker represents a future point in time and/or a future location for the latest possible intervention of the driver prior to the intervention of the emergency braking driver assistance function.

An electronic device and a method are described. The electronic device is adapted to be installed on a handlebar of a vehicle, the electronic device comprising: a processor; a communication module; a display comprising a halo-shaped display; a memory for storing therein executable instructions, the instructions upon being processed by the processor, causing the electronic device to: receive, via the communication module, navigational data from a mobile device, the navigational data being associated with a circular visual signal indication, the circular visual signal indication being indicative of at least one of (i) an upcoming directional instruction and (ii) a distance between a current location and an upcoming location associated with the upcoming directional instruction; and, cause to display, on the halo-shaped display, of the circular visual signal indication.

An information processing device has an obtaining unit, a controller, and a giving unit. The obtaining unit can obtain vehicle information. The controller creates first warning information when the passability of a road in the vehicle information indicates non-passable. The controller creates recovery information when the passability of the road at the same position in the vehicle information indicates passable, after creation of the first warning information. The giving unit gives the recovery information.

A vehicle heads-up display (HUD) includes a smart phone or tablet computer with at least one processor running at least one computer program adapted to enable the HUD to: (i) establish a connection to an on board unit (OBU) of the vehicle using the mechanisms provided by ICMPv6 for IPv6 router discovery, and acquire an IPv6 address through the mechanism of Stateless address auto configuration (SLAAC); (ii) process an authentication challenge from a Roadway Authorization Server (RAS); and (iii) respond to an authentication challenge from said Roadway Authorization Server (RAS).