A load control device may be configured to provide a user interface for controlling the intensity and/or color of one or more lighting loads. The user interface may include separate actuation members for setting the intensity and/or color of the lighting loads. The user interface may include one actuation member configured to operate in an intensity and/or color control mode. The control mode of the actuation member may be set via a button, a lever, a rotary switch, a rotary knob, etc. The user interface may include a touch sensitive element capable of sensing a user's touch and translate the touch into a control signal. Feedback may be provided on the user interface to indicate the type of control being adjusted and/or amount of control being applied to the lighting loads.

Voice responsive in-wall devices are provided. In one example implementation, a power switch includes a housing mountable on or at least partially within a surface. The housing can have a front panel. The power switch can include an interface element disposed on the front panel and operable to receive a user input. The power switch can include a power interrupter operable to control power delivery to the powered load based at least in part on interaction with the interface element. The power switch can include one or more microphones operable to obtain audio input. The power switch can include one or more speakers configured to provide audio output. The power switch can include a communications interface operable to communicate data associated with the audio input over a communication link.

Voice responsive in-wall devices are provided. In one example implementation, a power switch includes a housing mountable on or at least partially within a surface. The housing can have a front panel. The power switch can include an interface element disposed on the front panel and operable to receive a user input. The power switch can include a power interrupter operable to control power delivery to the powered load based at least in part on interaction with the interface element. The power switch can include one or more microphones operable to obtain audio input. The power switch can include one or more speakers configured to provide audio output. The power switch can include a communications interface operable to communicate data associated with the audio input over a communication link.

A switch including a waterproof and light leak prevention structure is disclosed. The switch according to an embodiment of the present invention is a switch including a light emitting member and a push switch on a mount, and includes a switch including a cover plate provided on the mount and configured to cover the light emitting member and the push switch, and the cover plate comprises includes a rubber dome disposed at a position corresponding to the push switch, a light emitting member cover configured to cover the light emitting member at a predetermined distance from an upper surface of the light emitting member, and a light leak prevention protrusion configured to surround a periphery of the light emitting member and to extend upward up to a predetermined height.

The present invention discloses a method using a bismuth based alloy as power-off element, comprising: a bismuth based alloy is used as the power-off element and a melting point of the bismuth based alloy is between 100 C. to 380 C.; when the power-off element is in an environment below the melting point, two conductive elements are mutually contacted and capable of conducting currents, whereas the power-off element is only receptive of the currents but does not serve as a medium for conducting the currents; when a working temperature of a switch or the socket is close to or exceeds the melting point, the power-off element loses rigidity and enables the two conductive elements to be separated from each other, thereby forming an electrically disconnected state.

Voice responsive in-wall devices are provided. In one example implementation, a power switch includes a housing mountable on or at least partially within a surface. The housing can have a front panel. The power switch can include an interface element disposed on the front panel and operable to receive a user input. The power switch can include a power interrupter operable to control power delivery to the powered load based at least in part on interaction with the interface element. The power switch can include one or more microphones operable to obtain audio input. The power switch can include one or more speakers configured to provide audio output. The power switch can include a communications interface operable to communicate data associated with the audio input over a communication link.

Voice responsive in-wall devices are provided. In one example implementation, a power switch includes a housing mountable on or at least partially within a surface. The housing can have a front panel. The power switch can include an interface element disposed on the front panel and operable to receive a user input. The power switch can include a power interrupter operable to control power delivery to the powered load based at least in part on interaction with the interface element. The power switch can include one or more microphones operable to obtain audio input. The power switch can include one or more speakers configured to provide audio output. The power switch can include a communications interface operable to communicate data associated with the audio input over a communication link.

A load control device may be configured to provide a user interface for controlling the intensity and/or color of one or more lighting loads. The user interface may include separate actuation members for setting the intensity and/or color of the lighting loads. The user interface may include one actuation member configured to operate in an intensity and/or color control mode. The control mode of the actuation member may be set via a button, a lever, a rotary switch, a rotary knob, etc. The user interface may include a touch sensitive element capable of sensing a user's touch and translate the touch into a control signal. Feedback may be provided on the user interface to indicate the type of control being adjusted and/or amount of control being applied to the lighting loads.

A rocker switch (3) includes a housing (1), a button (2), a rocker (3), a dynamic contact plate (4), and a first terminal (51) and a second terminal (52) installed in the housing (1). The button (2) is hinged with the housing (1); the top of the rocker (3) is connected to the bottom of the button (2); the rocker (3) and the button (2) are linked with each other; the bottom side of the dynamic contact plate (4) presses the second terminal (52); the rocker (3) is provided for turning the dynamic contact plate (4) to rotate; and an end of the dynamic contact plate (4) is provided for connecting the first terminal (51). This rocker switch (3) of this invention overcomes the problem of unable to miniaturize the switch.

A wiring device and method that control an amount of power delivered to a load, which maintain function even if a line connection and a load connection are reverse wired. Designed circuitry comprising steering diodes in both a line and a load wire direct a power source to an AC/DC power supply. The wiring device comprises a housing, a line terminal nominally designated for receiving electrical power from a power source, a load terminal nominally designated to feed electricity to a load, a neutral terminal, a line wire electrically connected to the line terminal, a load wire electrically connected to the load terminal, and a means for controlling an amount of power delivered to the load. Embodiments of the present invention include automated universal lighting controls, dimers, timers, and wired lighting devices.