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.

A location of a first wearable device is determined based on a first biometric signature. Operation of a touchscreen display is restricted if the location of the first wearable device is in an operator's side of a vehicle cabin and the first wearable device is within a first distance from the display.

Arranged between a steering wheel (or more generally, steering handle) and a windshield of a motor vehicle, a control panel module has at least on e operator control element, each arranged on one side of a steering column of the steering wheel. The at least one operator control element is rotatable about an axis of rotation and/or movably at least along a longitudinal direction of the motor vehicle with respect, to a driver's seat. An actuator device of the control panel module respectively moves the at least one operator control element response to a control device of the control panel module, depending on at least one enable signal, into an enable position and, depending on at least one position signal, from the enable position into position corresponding in each case the position signal.

The invention relates to a control system (2) for controlling a main monitor (10) of a motor vehicle, said control system (2), configured so as to be installed on a central console (12), comprising a display screen and a touchscreen. Said control system (2) has a first mode of operation in which said display screen is in an inactive state and the touchscreen is in a basic configuration, and a second mode of operation in which said display screen is in an active state and the touchscreen is in an advanced configuration; the control system furthermore comprises a control module configured so as to put the control system into said first mode of operation when the vehicle is in a driven driving mode or into said second mode of operation when the vehicle is in an autonomous driving mode.

The present application relates to a method for fabricating a vehicle interior trim part. The proposed method comprises the step of providing a glass panel with a backside and a first and a second region. In a further step, a first stiffener is attached to the first region of the glass panel. Thereby, a stiffened region of the glass panel is formed. The method further comprises the step of bending the second region of the glass panel by cold forming so that a bent region of the glass panel is formed in a region adjacent to the stiffened region. The method further comprises the step of holding the glass panel in shape using a means of fixation.

When the automobile is changed to the manual driving mode, the control device starts acceptance as the operation of the touch pad as an operation on the application system that displays the screen on the heads-up display, and when the automobile is in the autonomous driving mode, the control device starts acceptance of the operation of the touch pad as an operation on the application system that displays the screen on the center display.

Electrostatic friction textures on a touchscreen panel are used to create the sensation of block icons in a contextual menu adapted to an automotive environment. In particular, a center stack touchscreen friction display in a passenger vehicle provides one set of touch controls and HMI data to the driver while simultaneously providing either the same control options and HMI or a completely different set of information and menu structure to the passenger in invisible texture form. The invisible texture is in the form of block icons, and coincidence between a finger of a passenger and a block icon results in an audio announcement of the block icon to guide a visually impaired passenger through the contextual menu.

A method for providing a user interface of a transportation vehicle, wherein the user interface has at least one mechanically adjustable controller and a touch display and operates peripheral devices of the transportation vehicle. A user interface of a transportation vehicle for performing the method for operating the at least one mechanically adjustable controller to bring about temporary deactivation of the touch display so that operation of peripheral devices by the touch display is temporarily blocked during the operation of the mechanically adjustable controller.

The invention relates to the transmission of multimedia data, which is to be output, from a computer device to a vehicle multimedia device. The vehicle multimedia device has a control device which is designed to determine a piece of vehicle status information in order to transmit said information to the computer device. On the basis of the vehicle status information, the computer device generates release data which determines to what extent the multimedia data is to be output. The computer device transmits the multimedia data and the release data to the vehicle multimedia device, which multimedia device outputs, by means of an output device, the maximum multimedia data to the extent defined by the release data.