A light-emitting keyboard includes a bracket, at least one keycap, a circuit layer and a composite light-emitting layer. The at least one keycap is disposed on the bracket and connected to the bracket via a support assembly. The circuit layer is disposed between the keycap and the bracket. The composite light-emitting layer is disposed under the bracket, and includes a substrate, a conductive layer, a reflective layer and at least one light source. The conductive layer is disposed on the substrate and includes a circuit and patterned structures. The reflective layer is conformally disposed on the conductive layer. The at least one light source is located under the at least one keycap and electrically connected to the circuit, and light emitted from the light source is transmitted upwardly to the keycap.

A backlight control system includes a keyboard device and a computing device. The keyboard device includes a fixed light sheet, at least one movable light sheet, a light guide module and a key module. The computing device includes a processing unit. The movable light sheet is detachably and electrically connected with the fixed circuit board. The fixed light sheet projects a first light beam to plural keys of the key module through the light guide module. In a special scenario mode, the processing unit drives the movable light sheet to project a second light beam to at least one special key of the key module.

Keyboards and other electronic input devices have a key or keys with glyphs that are invisible to an unaided human eye in a first condition, such as when an underlying display attached to the key is not emitting light. The glyphs are visible through the key or keys when the display emits light. A one-way visibility layer or structure obscures the visibility of the display when viewed from above, but when the display emits light, the light penetrates through the one-way visibility layer, such as by passing through an array of microperforations in the key, and is visible to an onlooker.

A light-emitting keyboard includes a bracket, a keycap, a circuit layer, a composite light-emitting layer and a spacing layer. The bracket has an opening. The keycap is disposed on the bracket and connected to the bracket via a support assembly. The circuit layer is disposed between the keycap and the bracket. The composite light-emitting layer is disposed under the bracket, and includes a substrate, a circuit disposed on the substrate and a light source located under the keycap and electrically connected to the circuit, wherein light emitted from the light source is transmitted upwardly to the keycap. The spacing layer is disposed between the composite light-emitting layer and the bracket, wherein the spacing layer includes a hole corresponding to the opening of the bracket, and the light source is located in the hole of the spacing layer.

A light guide plate and a backlight module adapted to an illuminated keyboard are provided. The light guide plate includes a single-key light guide region. The single-key light guide region corresponds to a single key. Four diagonal regions of the single-key light guide region has a plurality of microstructures. The area sum of the plurality of microstructures is smaller than the area sum of the four diagonal regions of the single-key light guide region. Through the area control of a plurality of microstructures, the plurality of microstructures of a plurality of keys guide the light to make the brightness of each of the keys is even.

A control device for controlling an electrical load may include a slider knob, a plurality of light sources, a diffuser, and a control circuit. The slider knob may be configured to move in a vertical direction along an elongated slot located in a bezel of the control device. The diffuser may be located along the elongated slot and be configured to be illuminated by the plurality of light sources to indicate the amount of power delivered to the electrical load. The control circuit may be configured to control the amount of power delivered to the electrical load in response movement of the slider knob along the elongated slot, and to illuminate at least a portion of the diffuser to indicate the amount of power delivered to the electrical load. In response to receiving a message to control the electrical load by a remote device, the control circuit may be configured to illuminate the diffuser to indicate the amount of power delivered to the electrical load such that the illuminated portion of the diffuser does not align with the location of the slider knob.

The invention relates to a vehicle control panel (15) that comprises:—at least one clickable key (20) to which is assigned at least one function, said key (20) being configured to move at least between an inactive position and an active position in which said function is activated;—a screen (25) for displaying the current function of the key (20). The function is automatically assigned to the key (20) depending on a current parameter of the vehicle equipped with said control panel (15) or on a current context-related parameter.

A printer includes: a body defining a media enclosure configured to receive a media supply; an indicator assembly supported by an outer wall of the body, the indicator assembly including a plurality of substantially contiguous illumination surfaces illuminated by respective ones of a set of lights supported within the body; a controller supported by the body, the controller configured to: (i) obtain an operational status of the printer, (ii) retrieve, from a mapping repository, a set of notification control parameters corresponding to the operational status, and (iii) control the set of lights according to the notification control parameters.

A back light module is applied to a lighting keyboard with a plurality of keyswitches and includes a lighting unit, a light guide plate, a light penetrating membrane, a light calibration layer and an adhering component. The light guide plate has an opening used to accommodate the lighting unit. The light penetrating membrane is disposed on the light guide plate. The light calibration layer is disposed on the light penetrating membrane and has a second contour. The adhering component is disposed between the light guide plate and the light penetrating membrane, and has a first contour greater than the second contour. The adhering component includes a front region, a rear region and a hollow region. The front region is covered by the light calibration layer. The rear region is partly covered or not covered by the light calibration layer. The hollow region corresponds to and is larger than the opening.

A system that incorporates teachings of the present disclosure may include, for example, an accessory having a plurality of tactile-sensitive buttons, a plurality of light sources, wherein each light source emits a controllable spectrum of light through a corresponding one of the plurality of tactile-sensitive buttons, and a controller coupled to the plurality of tactile-sensitive buttons, and the plurality of light sources. The controller can be operable to detect tactile contact of each of the plurality of tactile-sensitive buttons, receive status information associated with a video game, and adjust the spectrum of light emitted by at least a portion of the plurality of light sources according to the status information to indicate one or more aspects of the video game. Additional embodiments are disclosed.