A sleeve or case for a mobile device, such as a smartphone or tablet or other types of hand-held device or mobile smart device, has a sleeve part for at least partially enclosing the mobile device and an input device arranged in the sleeve part for controlling the mobile device which can be received in the sleeve part. The input device includes a movable control element and a magnetorheological brake. Any movement of the control element can be selectively damped by way of the magnetorheological brake.

A display control system using a knob includes an input part to receive a touch input signal for a display area, a memory to store a display control program according to the touch input signal, and a processor to execute the program, such that the processor moves a position of a knob to perform function control of an area of the display to which the touch input signal is applied.

A HUD calibration system is provided and includes a HUD, a reticle reference object, a target, and a control module. The HUD displays a virtual image including a first center feature and first features. The reticle reference object is physically fixed to a windshield of a vehicle. The target is physically disposed forward of the vehicle and includes a second center feature and second features. The control module: controls the HUD to display the virtual image superimposed over the target; perform a boresighting process to align a center of a cross-hair of the reticle reference object with the first and second center features and generate first reference values; perform an undistortion calibration process to rotate and undistort the virtual image relative to the target and generate second reference values; and adjust operation of the HUD based on the first and second reference values.

The invention relates to a rotary control device (1) for steering a vehicle comprising a user interface surface (3), in particular a knob, that is embodied to rotate with respect to a housing (5) of the device (1) around a rotational axis (7) of the device (1), further comprising a sensor unit (9) for monitoring the orientation and/or rotational movement of the user interface surface (3) with respect to the housing (5), a processing unit (11), and a communications interface (13) for transmitting control signals (Ts) according to an output (Op) from the processing unit (11), said output (Op) being generated by the processing unit (11) on the basis of sensor data (Ds) from the sensor unit (9).

An apparatus for operating a display type vehicle switch includes a controller that controls one or more symbols related to a function of a vehicle to be displayed on a display, the display that displays the one or more symbols, and a selection device that selects at least one of the one or more symbols displayed on the display.

A touch input device includes a touch unit to which a user can input a touch gesture, wherein the touch unit includes a gesture input unit positioned at a center of the touch unit and a swiping input unit inclined downward along an edge of the gesture input unit, and the gesture input unit and the swiping input unit receive separate touch signals.

A vehicle function operation apparatus according to one embodiment of the present invention includes a matching table configured to display an icon for each of various in-vehicle functions for each area, and a position variable knob dial electrically linked when coming into contact with the matching table to project a widget for each detailed function of the corresponding icon positioned on a contact area with the matching table.

A control system including a touch-sensitive surface and an actuator fixed to the touch-sensitive surface, the actuator having a control element rotatable relative to the touch-sensitive surface between at least two selection positions. The actuator has a first sensor element rotationally fixed to the control element and coupled to the touch-sensitive surface in all selection positions, and a second sensor element. The control element is translationally movable relative to the touch-sensitive surface between a selected position and a release position. The second sensor element is rotationally fixed to the element and uncoupled from the touch-sensitive surface in the selected position and coupled to the touch-sensitive surface in the release position.

A manipulation system capable of controlling various functions in a vehicle includes a detachable rotary manipulation system capable of corresponding to various manipulation environments using an electromagnet and a method of controlling the same. The method includes determining whether a rotary manipulation unit having a plurality of magnets disposed thereat has been attached based on a change in current of a plurality of electromagnetic coils disposed at an attachment unit and controlling whether to activate at least some of the plurality of electromagnetic coils based on at least one of the number of clicks per rotation corresponding to a function to be controlled or a manipulation system type of the rotary manipulation unit upon determining that the rotary manipulation unit has been attached.

A vehicle control system includes a controller configured to determine whether a vehicle is operating in an autonomous driving mode or in a manual driving mode; and a steering device for adjusting a position of a wheel of the vehicle when the vehicle is operating in the manual driving mode. The steering device includes a knob configured to rotate about a rotation axis; a shaft connected to the knob, the shaft rotating about the rotation axis together with the knob by a rotational force transmitted from the knob; and an elastic part coupled to the shaft. In particular, when the shaft rotates from a reference position by the rotational force, the elastic part is compressed, and when the rotational force is removed, the elastic part is relaxed to return the shaft to the reference position.