The present invention provides a luminous scroll module applied to a mouse, including: a scroll, an inner wheel, and a luminous module. The inner wheel is arranged in a groove of the scroll, and the scroll is capable of rotating relative to the inner wheel. The luminous module is arranged in the inner wheel. A luminous unit of the luminous module is configured to emit a light beam, and the light beam passes through a light source opening of the inner wheel to the scroll.

An electronic device having a touch sensor, the electronic device can include a display panel including an active area and an encapsulating substrate covering the active area; a plurality of recesses in a surface of the encapsulating substrate; and a touchscreen including a lower metal layer disposed in the plurality of recesses, and a touch electrode layer electrically connected to a part of the lower metal layer and including touch driving electrodes and touch sensing electrodes separately arranged on the encapsulating substrate.

A mouse device and a computer control system thereof, comprising a mouse and an optical sensing module. The mouse has electrically connected press buttons, light-emitting component and mouse processing unit set with an initial setting command. The optical sensing module is disposed on the mouse and electrically connected to the mouse processing unit, and has a light source emitting unit generating a sensing signal, and a light source receiving unit. The mouse processing unit transmits the sensing signal to a host processing unit of a host computer. Thereby, the optical sensing module senses a user approaches the mouse or generation of gestures to generate the sensing signal. The mouse processing unit drives the light-emitting component to generate an initial light source. The host processing unit generates an advanced control signal to drive the light-emitting component, an operation unit and peripheral devices to generate advanced actions of an advanced setting command.

A vehicle display device includes a first display unit disposed in a first portion of a vehicle and including a first display panel to display a first image and a first power supply to supply a first power supply voltage to the first display panel, the first power supply configured to detect an abnormality of a signal output to the first display panel to generate a first shut-down control signal; a second display unit disposed in a second portion of the vehicle and including a second display panel to display a second image and a second power supply to supply a second power supply voltage to the second display panel, the second power supply configured to detect an abnormality of a signal output to the second display panel to generate a second shut-down control signal; a third display unit disposed in a third portion of the vehicle and configured to display a third image or at least one of the first and second images; and a controller to receive first image data corresponding to the first image, second image data corresponding to the second image, and third image data corresponding to the third image to provide the received first image data, the received second image data, and the received third image data to the first display unit, the second display unit, and the third display unit, respectively. The controller is configured to supply the first image data to the third display unit in response to the first shut-down control signal, and to supply the second image data to the third display unit in response to the second shut-down control signal.

A tactile presentation device 10 comprises: a substrate 13; a plurality of wirings 11 extending on the substrate 13; a first insulating layer 14 formed on the substrate 13 and covering the wirings 11; a plurality of electrodes 12 disposed on the first insulating layer 14; a second insulating layer 15 covering the electrodes 12; and a drive circuit selectively applying a voltage signal to the electrodes 12 through the wirings 11, based on a control signal input from the outside. Each of the wirings 11 is electrically connected to one of the electrodes 12 via a through hole opened in the first insulating layer 14. At least one of the electrodes 12 presents tactile sense to a user who touches the second insulating layer 15 over the electrode 12 while the voltage signal is being applied. Each of the wirings 11 is partly covered with at least one of the electrodes 12.

A multi-display device is adapted to be dockable or otherwise associatable with an additional device. In accordance with one exemplary embodiment, the multi-display device is dockable with a smartpad. The exemplary smartpad can include a screen, a touch sensitive display, a configurable area, a gesture capture region(s) and a camera. The smartpad can also include a port adapted to receive the device. The exemplary smartpad is able to cooperate with the device such that information displayable on the device is also displayable on the smartpad. Furthermore, any one or more of the functions on the device are extendable to the smartpad, with the smartpad capable of acting as an input/output interface or extension of the smartpad. Therefore, for example, information from one or more of the displays on the multi-screen device is displayable on the smartpad.

A multi-display device is adapted to be dockable or otherwise associatable with an additional device. In accordance with one exemplary embodiment, the multi-display device is dockable with a smartpad. The exemplary smartpad can include a screen, a touch sensitive display, a configurable area, a gesture capture region(s) and a camera. The smartpad can also include a port adapted to receive the device. The exemplary smartpad is able to cooperate with the device such that information displayable on the device is also displayable on the smartpad. Furthermore, any one or more of the functions on the device are extendable to the smartpad, with the smartpad capable of acting as an input/output interface or extension of the smartpad. Therefore, for example, information from one or more of the displays on the multi-screen device is displayable on the smartpad.

According to one embodiment, a lateral-electric-field liquid crystal display device includes a light-emitting display layer including OLEDs and a driving circuit controlling light emission of the OLEDs, a moisture impermeable film provided to be laminated on the light-emitting display layer to prevent infiltration of moisture into the light-emitting display layer, an optical substrate provided separately from the moisture impermeable film and subjecting light from the light-emitting display region to optical processing, a first touch electrode group serving as one electrode group of touch electrodes and provided on a back surface of the optical substrate, and an extraction electrode group formed to be laminated on the moisture impermeable film, the extraction electrode group and the optical substrate have an overlapping part in plan view, and electrodes of the first touch electrode group being electrically connected to electrodes of the extraction electrode group in the overlapping part.

The invention relates to a processing system. The processing system includes a determination module configured to make a determination that a low ground mass condition associated with an input device exists in an initial combination signal obtained from a sensor module using initial sensor settings. Based on the determination, adjusted sensor settings are determined, and an adjusted combination signal is obtained, using the adjusted sensor settings and, using the adjusted combination signal, object information for one or more input objects in a sensing region of the input device is obtained. The sensor module is configured to generate, using a first sensor electrode, a second sensor electrode, and the adjusted sensor settings, the adjusted combination signal. The adjusted combination signal includes effects of a transcapacitive coupling between the first sensor electrode and the second sensor electrode and effects of an absolute capacitive coupling between the second sensor electrode and the input object.

An apparatus for creating movement in a virtual reality for a user includes a computer includes a virtual reality headset in communication with the computer that is worn on the head of the user so the user sees the virtual reality shown by the headset and produced by the computer in the headset. The apparatus includes a foot controller in communication with the computer against which the user moves at least one of his feet to create control signals with the foot to cause movement in the virtual reality. A method for creating movement in a virtual reality for a user having the steps of the user seeing the virtual reality shown by a virtual headset and produced by a computer in the headset, a virtual reality headset in communication with the computer that is worn on the head of the user. There is the step of the user moving at least one of his feet against a foot controller to create control signals with the foot to cause movement in the virtual reality by the computer, the foot controller in communication with the computer. A computer software program for creating movement in a virtual reality for a user.