A touch control human-machine interface for use in controlling operation of a machine, said interface including: an interface housing; a cover plate disposed on an outer-surface of the housing, said cover plate having a first electrically-conductive portion configured for touch interaction by a user's finger; a circuit assembly disposed within the housing, said circuit assembly including a circuit board having a second electrically-conductive portion and a light illumination module operably-connected thereto; a spacer element disposed between and separating the first conductive portion from the second conductive portion such that the first conductive portion, the second conductive portion and the spacer element are configured to form a capacitor device that is operably-connected with the circuit assembly; said first electrically-conductive portion being configured for deformation by the user's finger so as to cause a change in capacitance across the capacitor device, and whereby responsive to said change in capacitance, the circuit assembly is configured for generating a control signal for controlling operation of the machine, and, for controlling the light illumination module to propagate a light emission from the circuit assembly through the housing and cover plate so as to be visible externally of the housing.

A switch to be attached to a panel having an opening in a surface includes: a stationary member to be attached to the panel; a movable member to be placed at a distance from the panel, the movable member having a manipulation surface separated from the panel in the opening with a gap intervening between the manipulation surface and the panel, the manipulation surface being exposed from the opening; and a vibration element disposed between the stationary member and the movable member, the vibration element vibrating the movable member.

Electronic control device (10) comprising: —an electronic circuit (11) having an operative face (11a) on which a plurality of LEDs (12) are mounted; —a frame (13) defining a plurality of first channels (14) which face the LEDs so as to guide their light radiation; —a composite screen (15) which covers the first channels (14) so as to be crossed by a light radiation coming from the LEDs (12) and guided by the first channels (14) towards the composite screen (15). The composite screen (15) comprises: —a diffuser layer (16) configured to homogenize a light radiation that crosses it; —an operative layer (17) having electronic tracks comprising touch-sensitive pads (18) and connection contacts (19). The electronic control device (10) further comprises at least one connector (20) which connects electrically the connection contacts (19) to the electronic circuit (11) in order to transmit to the latter electrical signals following touching, by a user, of at least one of said sensitive pads (18) on the composite screen (15).

A multi-state keyboard function row is provided. A plurality of representations can be formed on an insert of the multi-state keyboard function row. An assembly of the multi-state keyboard function row can be configured to cause either a first set of the representations or a second set of the representations to be visible to a user. A brightness of the representations may also be controlled based on a brightness of ambient light.

Left and right earphones are independently wireless such that the left and right earphones are not physically connected when worn by a user. Each earphone comprises a speaker, microphone and a body portion with an SOC. Each SOC comprises a wireless communication circuit and a processor. Each processor comprises a digital signal processor for noise cancellation.

An audio output device comprises a loudspeaker and, four stem control inputs substantially even spaced on the upper surface of a housing. The stem control inputs are each divided into four segments, each comprising a touch sensor and an illumination unit. Each stem control input is associated with a different stem in an audio track for playback via the loudspeaker. Touching the segments of each stem control input results in the touch being detected and a touch signal being output by the respective segment. In response to a touch signal, the associated illumination unit is togged on/off and a property of the associated stem is varied during playback by loudspeaker.

A vehicle smart garnish is provided. The vehicle smart garnish includes an upper casing formed with a plurality of symbols to which light is emitted, a capacitive touch sensor pad corresponding to at least one of the plurality of symbols and recognizing a touch, a holder casing in which the capacitive touch sensor pad is mounted and coupled from a rear of the upper casing, and a circuit board positioned behind the holder casing and on which a light emitting element emitting light is mounted and configured to detect a touch signal of the capacitive touch sensor pad, wherein the holder casing includes a light guide path for guiding the light emitted from the light emitting element to the plurality of symbols, and a light reflection layer is formed on a partition of the light guide path.

Left and right earphones are independently wireless such that the left and right earphones are not physically connected when worn by a user. Each earphone comprises a speaker, a body portion, and an earbud extending from the body portion. The body portion comprises a downwardly extending portion that extends straight downwardly when the earphone is worn by the user, a wireless communication circuit for receiving signals transmitted wirelessly to the earphone from a remote source, a microphone, a rechargeable battery, a memory and a processor. Each earphone is configured to receive from a remote computing device, and store in the memory, a firmware update.

An apparatus includes a processor, a transceiver connected to the processor, an integrated circuit connected to the processor, a first proximity sensor configured to provide a first sensor input to the integrated circuit, and a second proximity sensor configured to provide a second sensor input to the integrated circuit. When the integrated circuit determines that the first sensor input represents a first detection event, the processor sets a timer and when the timer expires before the integrated circuit determines that the second sensor input represents a second detection event, the processor sends a message through the transceiver.

Left and right earphones are independently wireless such that the left and right earphones are not physically connected when worn by a user. Each earphone comprises a speaker, a body portion, and an earbud extending from the body portion. The body portion comprises a downwardly extending portion that extends straight downwardly when the earphone is worn by the user, a wireless communication circuit for receiving signals transmitted wirelessly to the earphone from a remote source, a microphone, a rechargeable battery, a memory and a processor. Each earphone is configured to receive from a remote computing device, and store in the memory, a firmware update.