A control device may have a plurality of buttons that may be backlit to multiple levels, such as first, second, and third adjacent buttons positioned in order, and first, second, and third LEDs positioned to illuminate a respective button. The control device may be configured to illuminate the first LED to a first LED illumination intensity to illuminate the respective button to a first surface illumination intensity; illuminate the third LED to a second LED illumination intensity to illuminate the respective button to a second surface illumination intensity; and illuminate the second LED to a third LED illumination intensity to illuminate the respective button to the second surface illumination intensity. The third LED illumination intensity may be less than the second LED illumination intensity, which may be less than the first LED illumination intensity, and the second surface illumination intensity may be less than the first surface illumination intensity.

The present disclosure relates to a proximity sensor capable of further alleviating crosstalk and an electronic device using the same.

A proximity sensor of the present disclosure includes: a substrate including a main surface; a light emitter and a light receiver disposed on the main surface; and a resin disposed on the main surface, enclosing the light emitter and the light receiver, and including a boundary surface spaced apart from the main surface; a first crosstalk alleviator disposed on the boundary surface and including a first inclined surface; and a second crosstalk alleviator disposed on the boundary surface and including a second inclined surface.

The invention concerns an inverter housing (15) with at least two housing parts (16, 17), which can be detachably connected to one another by way of fastening elements (19), with a connection area (21), and an operation area (20) provided on a housing part (16, 17). In accordance with the invention, an optoelectronic control unit (1) is provided for purposes of operation, with at least one reflection light sensor (2), with in each case a light source (3) and in each case a light detector (4), evaluation electronics (5), and with an operating panel (6) for purposes of operating the reflection light sensor (2) as a result of the approach of an object (7), wherein a light guide (8) is arranged connected to a housing part (17), the other housing part (16) has a mounting (25) for a circuit board (14), which contains the reflection light sensor (2) of the optoelectronic control unit (1), and a signal light source (9) for the emission of light in the visible wavelength range is arranged such that the light emitted by the signal light source (9) can be projected via the light guide (8) onto the operating panel (6), wherein the connection area (21) is arranged below the operation area (20).

An input device is provided which includes: a first light source which emits light to cause a first design to be displayed on a display region: a second light source which emits light to cause a second design different from the first design to be displayed on the display region; a switch which receives an input from a user; and a control circuit which, according to the input received by the switch, (i) controls displaying of a design on the display region, by controlling a lighting state of the first light source and a lighting state of the second light source, and (ii) outputs a control signal corresponding to the input received by the switch, to an external device.

A smart valve positioner is provided with a local user interface with non-mechanical touch buttons and a display inside a positioner housing under a housing cover for locally operating the valve positioner. The touch buttons are user-operable by touching the touch buttons when the housing cover is open. The housing cover is arranged to make the touch buttons user-operable from outside the housing by touching the housing cover, when the housing cover is closed.

An optoelectronic device has an asymmetric field overlap and is operable to measure proximity independently of object surface reflectivity. In some instances, the optoelectronic device includes a plurality of light-emitting assemblies and a light-sensitive assembly. In some instances, the optoelectronic devices include a plurality of light-sensitive assemblies and a light-emitting assembly. An asymmetric field overlap is attained in various implementations via various field-of-view axis, field-of-view angle, field-of-illumination axis, field-of-illumination angle, optical element and/or pitch configurations.

A control device may have a plurality of buttons that may be backlit to multiple levels, such as first, second, and third adjacent buttons positioned in order, and first, second, and third LEDs positioned to illuminate a respective button. The control device may be configured to illuminate the first LED to a first LED illumination intensity to illuminate the respective button to a first surface illumination intensity; illuminate the third LED to a second LED illumination intensity to illuminate the respective button to a second surface illumination intensity; and illuminate the second LED to a third LED illumination intensity to illuminate the respective button to the second surface illumination intensity. The third LED illumination intensity may be less than the second LED illumination intensity, which may be less than the first LED illumination intensity, and the second surface illumination intensity may be less than the first surface illumination intensity.

A control device may have a plurality of buttons that may be backlit to multiple levels, such as first, second, and third adjacent buttons positioned in order, and first, second, and third LEDs positioned to illuminate a respective button. The control device may be configured to illuminate the first LED to a first LED illumination intensity to illuminate the respective button to a first surface illumination intensity; illuminate the third LED to a second LED illumination intensity to illuminate the respective button to a second surface illumination intensity; and illuminate the second LED to a third LED illumination intensity to illuminate the respective button to the second surface illumination intensity. The third LED illumination intensity may be less than the second LED illumination intensity, which may be less than the first LED illumination intensity, and the second surface illumination intensity may be less than the first surface illumination intensity.

A switch system includes: a projection; a plurality of switches that are arranged on a side surface of the projection along a circumferential direction, each switch detecting touch to the side surface of the projection by an operator as on or off; and a determiner that acquires on/off states of the switches, and determines a rotational direction of an operator's finger along the circumferential direction of the projection based on a current on/off state currently acquired from each switch and a previous on/off state previously acquired from each switch.

In some examples, a first keyboard includes a plurality of light-sensing electrodes, where individual ones of the light-sensing electrodes correspond to individual keys of the first keyboard. The first keyboard includes a microprocessor electrically coupled to individual ones of the light-sensing electrodes. A second keyboard comprised of light-transmitting material may be placed on top of the first keyboard. The second keyboard may include a plurality of keys, with individual keys including a keycap having opaque material attached to a bottom surface and a scissors mechanism to lower the opaque material when a predetermined amount of pressure is applied to the keycap. The microprocessor is configured to perform operations including determining that the opaque material is obstructing light to a first particular light-sensing electrode of the plurality of light-sensing electrodes and sending a signal indicating a selection of a first key corresponding to the first particular light-sensing electrode.