A vehicle door handle is provided that includes a deployable handle body located on a door, keypad contacts on an outer side of the handle body, an actuator configured to deploy the handle to a deployed position, a plurality of proximity sensors located on the handle body and generating activation fields, and a controller processing signals generated by the sensors to determine an input command for controlling the actuator and to determine a keypad input. The controller may sense ice on the handle and determine ice thickness and may control the actuator to break the ice based on the ice thickness.

A vehicle door handle is provided that includes a deployable handle body located on a door, keypad contacts on an outer side of the handle body, an actuator configured to deploy the handle to a deployed position, a plurality of proximity sensors located on the handle body and generating activation fields, and a controller processing signals generated by the sensors to determine an input command for controlling the actuator and to determine a keypad input. The controller may sense ice on the handle and determine ice thickness and may control the actuator to break the ice based on the ice thickness.

The present invention provides a touch switch unit, including a touch knob 400 on which a touch by a user is performed, a board 200 spaced apart from the touch knob, and a touch electrode body 500 interposed between the board and the touch knob 400, for sensing a change in an electrical signal according to a touch on the touch knob, wherein the touch electrode body 500 includes a touch body 510 fixed on one surface of the board 200 between the touch knob and the board and a touch sensing electrode 520 having at least part extended to an area adjacent to the touch knob and an area adjacent to the board and formed on the touch body 510 through insert injection and having at least another part formed on the board 200 and a vehicle lighting device including the touch switch unit.

An actuator is connected to an operating element of a manual user interface and outputs a haptic feedback signal to the user via the operating element. The operating element includes a sensor that detects a sensor signal generated by a manual input of the user as a reaction to the emitted feedback signal. The user's reaction time is determined. If the reaction time is shorter than a predetermined limit value, future haptic feedback signals are adjusted in such a way that their haptically perceptible intensity is reduced, and if the reaction time is greater than the predetermined limit value, future haptic feedback signals are changed in such a way that their haptically perceptible intensity is increased.

An actuator is connected to an operating element of a manual user interface and outputs a haptic feedback signal to the user via the operating element. The operating element includes a sensor that detects a sensor signal generated by a manual input of the user as a reaction to the emitted feedback signal. The user's reaction time is determined. If the reaction time is shorter than a predetermined limit value, future haptic feedback signals are adjusted in such a way that their haptically perceptible intensity is reduced, and if the reaction time is greater than the predetermined limit value, future haptic feedback signals are changed in such a way that their haptically perceptible intensity is increased.

The present invention provides a touch switch unit, including a touch knob 400 on which a touch by a user is performed, a board 200 spaced apart from the touch knob, and a touch electrode body 500 interposed between the board and the touch knob 400, for sensing a change in an electrical signal according to a touch on the touch knob, wherein the touch electrode body 500 includes a touch body 510 fixed on one surface of the board 200 between the touch knob and the board and a touch sensing electrode 520 having at least part extended to an area adjacent to the touch knob and an area adjacent to the board and formed on the touch body 510 through insert injection and having at least another part formed on the board 200 and a vehicle lighting device including the touch switch unit.

A proximity switch assembly and method for detecting activation of a proximity switch assembly and providing feedback is provided. The assembly includes a plurality of proximity switches each comprising a proximity sensor providing a sense activation field. The assembly also includes control circuitry processing a signal associated with the activation field of each proximity sensor and detecting a finger located between two proximity switches. The assembly further includes a feedback device generating a feedback when the finger is detected between the two proximity switches. In addition, the assembly may detect speed of movement of a finger interfacing with the proximity switches and vary the feedback based on the detected speed.