A method for providing a user interface for at least one device of a transportation vehicle. A query gesture of a user is detected, and the query gesture is assigned a query direction. The query direction determines an approach value for the device. The approach value is then used to generate a feedback signal which is output, and the device is selected when the approach value exceeds a specific threshold. An operating possibility display for the selected device is generated and output, and the operating possibility display includes information on the operating possibilities for the selected device. An operating gesture of the user is detected, and the detected operating gesture is used to generate a control signal for the selected device, and the control signal is transmitted to the device. Also disclosed is a system for providing a user interface for at least one device of a transportation vehicle.

A touch-type button for a vehicle may include: a hidden cover defining an external appearance of the touch-type button and having a pattern which corresponds to a letter font; and a transparent electrode attached to a rear surface of the hidden cover and configured to generate a signal in response to a change in capacitance, wherein the transparent electrode transmits light emitted from a light source disposed behind thereof to allow the letter font to be revealed and recognized.

An input apparatus for a vehicle is provided with a plurality of sensor electrodes; and a controller is configured to determine a capacitance reference value of the input apparatus based on information about sensor values collected from a subset of sensor electrodes, which is randomly selected from the plurality of sensor electrodes.

The invention relates to a system (10) for controlling industrial or all-terrain vehicle functions, which comprises data processing means (20), such as a computer, and a plurality of devices (10a-10g) for controlling industrial or all-terrain vehicle functions. The control devices are arranged in a network with the data processing means (20) according to a master-slave model, and each control device comprises at least one first control member (3a) sensitive to contact and connectors (2), a computing circuit (1) with at least one data processing unit (MC), a memory in which is stored a unique identifier associated with said control device, and at least one first control state visualization member (4a). The data processing means (20) are configured to transmit to each identified control device (10a-10g) a request to obtain a feedback of information from the associated processing unit.

Provided is a soft upper trim of a vehicle door, in which an upper substrate, foam, and a transparent skin are laminated, and particularly, to a soft upper trim for switch assembly of a vehicle door, in which a switch, which is configured to preserve continuity of a transparent skin and display lock and unlock symbols on the transparent skin, is easily assembled to an upper substrate, and a method of manufacturing the same.

A vehicle user interface including a vehicle steering wheel including a grip, a sensor mounted in the steering wheel grip detecting objects touching the steering wheel grip, a plurality of individually activatable illumination units illuminating respective locations on the steering wheel grip, and a processor receiving outputs from the sensor, selectively activating a subset of the illumination units adjacent to a detected object, and controlling a plurality of vehicle functions in response to outputs of the sensor.

A terminal is provided to recognize a touch input and a gesture input intended by a user. A vehicle includes the terminal configured to display buttons to be selected by a user, and receive a touch input as user input. An image input receives an image of the user for receiving a gesture input as the user input and a controller divides an area of the terminal into a first area and a second area. The controller determines a button selected by the user among buttons displayed in the first area based on the touch signal output by the touch input, and determines a button selected by the user among buttons displayed in the second area based on a finger image and an eye image in the image.

Telematics systems and methods are described for generating interactive animated guided user interfaces (GUIs). A telematics cloud platform is configured to receive vehicular telematics data from a telematics device onboard a vehicle. A GUI value compression component determines, based on the vehicular telematics data, a plurality of GUI position values and a plurality of corresponding GUI time values. A geospatial animation app receives the plurality of GUI position values and the plurality of corresponding GUI time values. The geospatial animation app implements an interactive animated GUI that renders a plurality of geospatial graphics or graphical routes on a geographic area map via a display device. The geospatial graphics or graphical routes are rendered to have different visual forms based on differences between respective GUI position values and corresponding GUI time values.

Provided is a soft upper trim of a vehicle door, in which an upper substrate, foam, and a transparent skin are laminated, and particularly, to a soft upper trim for switch assembly of a vehicle door, in which a switch, which is configured to preserve continuity of a transparent skin and display lock and unlock symbols on the transparent skin, is easily assembled to an upper substrate, and a method of manufacturing the same.

A vehicle keypad device is provided that includes a touchscreen having an array of proximity sensors located on an exterior of a vehicle, a keypad display displaying virtual input icons proximate the proximity sensors, and a controller for dynamically adjusting size of the displayed virtual input icons based on a touch event.