A vehicle display control device including a housing that constitutes a body and is fixed to an instrument panel, an LCD cover whose outer circumference surface is disposed to be spaced apart from an inner circumference surface of the housing and that is accommodated in the housing, an LCD module that is accommodated in the LCD cover and covered by the LCD cover, a haptic actuator that is mounted on a rear of the LCD cover and transfers vibration to the LCD cover, and a support member that is disposed between the LCD cover and the housing.

A system may include a display driven using display driving circuitry to present an image via pixels. The display driving circuitry may include a sensor core compatible with one or more strain sensing circuits. The same sensor core may be used by a control system of the display to sense a stress applied to a strained region of a display using a current divider sensing circuit and/or a Wheatstone bridge sensing circuit.

A mechanism is provided for enhancing security access to a data processing system. Responsive to authenticating a first factor of the multi-factor authentication by matching a scanned fingerprint/thumbprint of a user to at least one previously scanned fingerprint/thumbprint in a set of previously scanned fingerprints/thumbprints, a determination is made as to whether a touch pressure level exerted by the user on a touch pressure sensor associated with the data processing system matches at least one previously stored touch pressure level in a set of previously stored touch pressure levels. Responsive to matching the touch pressure level exerted by the user to a previously stored touch pressure level in the set of previously stored touch pressure levels, a second factor of the multi-factor authentication is authenticated. Access is then granted for the user to the data processing system.

According to various embodiments, disclosed is an electronic device comprising at least one sensor, a display comprising a touch panel, at least one pressure sensor disposed in the upper or lower layer of the touch panel such that pressure applied to at least a part of a region of the display can be sensed, and at least one processor, the at least one processor configured to: sense whether the electronic device is in a submerged state by using the at least one sensor or the display, receive a user input with respect to the at least a part of a region of the display while the electronic device is sensed to be in the submerged state, acquire the pressure and the position of the user input by using the at least one pressure sensor, and process the user input on the basis of the acquired pressure and the acquired position.

An input device comprises a plurality of optical vibration sensors mounted in a common housing. Each optical vibration sensor comprises a diffractive optical element; a light source arranged to illuminate the diffractive optical element such that a first portion of light passes through the diffractive optical element and a second portion of light is reflected from the diffractive optical element; and a photo detector arranged to detect an interference pattern generated by said first and second portions of light. The optical vibration sensor is configured so that in use, after the first portion of light passes through the diffractive optical element, the first portion of light is reflected from a reflective surface onto the photo detector. The input device is placed in contact with a surface of a solid body, and an object is brought into physical contact with the surface of the solid body, thereby causing vibrations in the solid body. The vibrations are detected using two or more of the optical vibration sensors. The relative phase(s) of the vibrations are used to determine information regarding the point of contact of the object on the surface of the solid body.

A method includes displaying, by an electronic device, a graphical user interface (GUI) of a first application on a touchscreen of the electronic device, detecting, by the electronic device, a screenshot operation from a user, taking, by the electronic device, a screenshot of the GUI in response to the screenshot operation, displaying, on the touchscreen, a first preview image corresponding to an obtained first screenshot, detecting, by the electronic device, a first touch operation on the first preview image, updating the first preview image to a second preview image in response to the first touch operation, and displaying the second preview image on the touchscreen.

The present disclosure provides a display screen assembly and an electronic device. The display screen assembly includes a display layer, a pressure sensing layer and a cover plate, the display layer comprises a plurality of rows of pixel units and a plurality of rows of sub-pixels. The pressure sensing layer is disposed in adjacent pixel units or adjacent sub-pixels; the cover plate is covered on the display layer, the outer surface of the cover plate opposite to the pressure sensing layer forms a virtual key, and a surface of the cover plate corresponding to the pressure sensing layer forms a virtual key, and the pressure sensing layer can receive a pressure information by the virtual key of the cover plate.

A stimulus transmission device suppresses power consumption, and effectively transmits a physical stimulus to a user. The stimulus transmission device has a pressure receiving portion which receives pressure from part of a human body, an actuator which drives the pressure receiving portion, and a supporting portion which supports the actuator. The actuator does not move in conjunction with the supporting portion.

The present invention provides a sensing device and a keycap. The sensing device includes a sensing unit and a base unit. The sensing unit includes a first sensing unit surface having a binding area and a non-binding area, wherein the binding area and the non-binding area do not overlap with each other and correspond to each other in shape. The base unit includes a first base unit surface having a contact area and a non-contact area, wherein the contact area and the non-contact area do not overlap with each other and correspond to each other in shape. The sensing unit is attached to the contact area of the base unit by the binding area; and sides of the sensing unit and the base unit side are flush with each other. The sensing device can function as a keycap.

A touch panel system includes a touch panel including a drive electrode, a position detection electrode, and a pressing detection electrode, and a controller configured to impart a drive signal to the drive electrode and acquire signal values from each of the position detection electrode and the pressing detection electrode. The controller detects a position of an indicator on the basis of the signal values obtained from the position detection electrode and calculates a magnitude of pressing of the indicator on the basis of signal values in a pressing detection range corresponding to the detected position of the indicator among the signal values obtained from the pressing detection electrode.