An instrument cluster for a vehicle, includes: a master microcontroller being powered by a power source regulated by a power regulator module; one or more input sources electrically configured to provide one or more inputs to the master microcontroller through a signal conditioning circuit; and one or more output sources configured to receive one or more outputs from the master microcontroller. The master microcontroller is connected to at least two wireless modules. The master microcontroller is configured to provide instruction to a secondary wireless module of a communication device to display an output on the one or more output sources and the communication device. The master microcontroller is configured to receive instruction from the secondary wireless module of the communication device to display the output on the one or more output sources.

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.

A mobile terminal includes a mobile communication unit for communicating with an in-vehicle signal-sending device, an input operation unit for inputting data, a computational processing unit for performing computational processing, a display unit for displaying a screen, a storage unit for storing screen display information, and a mobile control unit for controlling the display unit. The computational processing unit has a function for calculating a loadage deviation based on vehicle specifications and vehicle loadage information contained in a sensor signal from the mobile communication unit, the storage unit has a function for presetting the vehicle specifications, the loadage deviation, and the screen display information prepared to display the vehicle specifications and the loadage deviation on the display unit screen, and the mobile control unit has a function for causing the display unit to display at least the vehicle specifications and the loadage information based on the screen display information.

A method, device, and a vehicle information system are provided for persisting application context from the mobile device to the vehicle information system. An operating context is determined for at least one application executing on the mobile device. A user interface view for display by the vehicle information system is generated and provided to the vehicle information system. The user interface view comprises at least one application user interface element associated with the at least one application, and the application user interface element comprises an application entry point defined by the operating context for the at least one application.

A system comprises a vehicle and a smart device. The smart device is configured to establish a communicative connection with the vehicle. The vehicle is configured to determine a trigger event in the vehicle comprising an evaluation of sensor data in the vehicle. Upon the trigger event being determined by the vehicle, the vehicle is configured to communicate a trigger data set to the smart device. The smart device is configured, after receiving the trigger data set, to interact with the vehicle according to the trigger data set. The interacting of the smart device with the vehicle can comprise controlling at least one vehicle function of the vehicle.

A vehicle-mounted display apparatus includes a display panel, a geographic position acquisition circuit, a processor, and a display panel driving circuit. The geographic position acquisition circuit acquires a current geographic position of a vehicle. The processor determines whether the current geographic position of the vehicle is within a stored geographic range, and if so, generates a first control signal. The display panel driving circuit controls the display panel to display the vehicle information upon receiving the first control signal from the processor. The vehicle information includes at least one of vehicle license information and a pseudo mobile phone number. In the display apparatus, an information push terminal communicating circuit communicates with an information push terminal to obtain the vehicle information and the stored geographic range, and a server communicating circuit communicates with a server to obtain the pseudo mobile phone number corresponding to an identification for the display apparatus.

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.

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.

A camera system is installed on the front end of a vehicle, either on the left front, the right front, or both sides. The camera is linked via wired or wireless connection to an onboard computer and a navigation display that is located within the passenger compartment of the vehicle. The driver reviews a visual description on the display of any oncoming traffic in the form of motor vehicles, pedestrians, cyclists, animals and the like on the navigation display via a single screen, split screen or alternating screens. The camera system can include a speed sensor that detects when the vehicle reaches a threshold speed to activate or de-activate the camera. Alternatively, the computer can activate the system when a turn signal is activated, and de-activate the system when the turn signal is no longer activated. This camera system can be retrofitted into older vehicles.

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.