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.

A mode of transportation, a user interface, and a method for operating a user interface are disclosed. The user interface includes a first display device, a second display device, and an evaluator. The method includes displaying a plurality of command buttons, which are allocated to a screen display on the first display device. On the second display device, the method includes automatically determining on the basis of an incoming signal that an ergonomic optimization of an arrangement of the associated command buttons is possible. The arrangement is automatically optimized in response to the determination.

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.

Provided herein is a vehicle instrument cluster consolidation system. The consolidated instrument cluster includes a vehicle based data processing system communicatively coupled with a display module. The display module can include multiple windows to display a plurality of menu items. The vehicle based data processing system communicatively can couple with the display module, input devices, and sliders to interact with the menu items provided within the multiple windows. The vehicle based data processing system can receive a motion input indicating a direction to relocate the plurality of menu items within the multiple windows. The vehicle based data processing system to, responsive to the motion input, relocate a first menu item from the center window to a second offset window and relocate a second menu item from a first offset window to the center window.

A lighting device for illuminating the vehicle interior of a motor vehicle is provided. The motor vehicle includes a plurality of light sources for illuminating the vehicle interior and a control device that can be used to actuate the plurality of light sources independently of one another. The motor vehicle further has an operator control device connected to the control device and includes segments and operator control elements that can be used to actuate the light sources independently of one another by a user. A display unit displays at least a partial image of the vehicle interior that can be illuminated or is illuminated by the controllable light sources.

An electronic apparatus disposed in a vehicle is provided. The electronic apparatus includes an input device including a body configured to be rotatable and pushable and a display disposed on the body; and a processor configured to acquire profile data of a user including preset information for function of the vehicle, control the display to display basic user interface (UI) corresponding to the function of the vehicle based on the acquired profile data of the user, and control a function of the vehicle corresponding to the basic UI in response to receiving an input on the input device.

A user interface capable of controlling various functions of a vehicle is disclosed. More particularly, an in-vehicle function control apparatus using a detachable knob and a method of controlling the same are disclosed. A method of controlling a vehicle function using a detachable knob includes an integrated operation unit detecting an attachment position of the detachable knob among a plurality of attachment positions in a vehicle, transmitting information on a result of the operation from the detachable knob to the integrated operation unit when an operation unit provided in the detachable knob is operated, and the integrated operation unit controlling a controlled function corresponding to the attachment position of the detachable knob based on the information on the result. The detachable knob is fixed at any one of the plurality of attachment positions using magnetic force.

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 user interface capable of controlling various functions in a vehicle is disclosed. The vehicle control method using a smart key includes an integrated operation unit detecting attachment of the smart key through a smart key detector disposed in a predetermined attachment area inside a vehicle, the integrated operation unit transmitting information on a controlled function corresponding to a vehicle state to the smart key, outputting a first user interface corresponding to the information on the controlled function on a first display of the smart key, transmitting information on a result of operation from the smart key to the integrated operation unit when an operation unit provided in the smart key is operated, and the integrated operation unit controlling the controlled function based on the information on the result. The smart key is fixed in the attachment area using magnetic force.

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.