An input device for generating improved haptic feedback. The input device includes a housing and an input component that defines a control surface and is movably supported on the housing with at least two degrees of freedom and associated mechanical natural frequencies. The input device is designed to assign a switching or controlling function to an operator touching or pressing the control surface, where the input device further has mechanical restoring means for restoring the input component into a rest position and an electromechanical actuator, where the actuator is designed to drive the input component along the at least two degrees of freedom and optionally decelerate the input component, counteracting the restoring force caused by the mechanical restoring means, in order to generate haptic feedback characterized in that the mechanical natural frequencies of the at least two degrees of freedom have a maximum deviation of less than 100 Hz.

A remote control device may control electrical loads and/or load control devices of a load control system without accessing electrical wiring. The remote control device may include a control unit and a base for the control unit. The base may include a frame and a mounting tab that attaches to the paddle actuator of a mechanical switch. The mounting tab may be monolithic with the frame. Alternatively, the base may include a resilient attachment member that extends from the frame and is captively retained by the mounting tab. The frame and the attachment member may be configured such that the attachment member is held in a fixed in position by the frame, or such that the attachment member is translatable relative to the frame. The base may include one or more alignment members. The base may cause a rear surface of the frame to be biased against the mechanical switch.

The present invention relates to a switching element (10) for a control device, in particular of a domestic appliance. The switching element (10) comprises a rotatable and shiftable rim element (14) being rotatable around and shiftable along the same axis. The switching element (10) comprises a stator element (20). The rim element (14) is rotatably and shiftably coupled to the stator element (20). The switching element (10) comprises a micro switch (16) including a stationary part and a movable part (30). The stationary part of the micro switch (16) is coupled to the stator element (20), while the movable part (30) of the micro switch (16) is rotatable around and shiftable along the same axis and coupled to the rim element (14). The micro switch (16) includes an encoder for indicating a rotation left or right and a shifting of the movable part (30) of said micro switch (16). The switching element (10) comprises at least one sensor antenna (18) forming a part of a capacitive touch sensor.

A switch apparatus adapted to be disposed on a wall surface includes a box, a heat generating element, a cover, a switch element, and a first heat dissipation structure. The box has an opening and is adapted to be embedded into the wall surface. The heat generating element is disposed inside the box. The cover is assembled to the box and covers the opening. The cover has a front surface and a rear surface opposite to each other. The rear surface faces toward the box, and the front surface is adapted to be exposed from the wall surface. The switch element is disposed on the front surface. The first heat dissipation structure includes first and second sections connected with each other. The first section is connected with the cover and exposed from the front surface, and the second section extends into the box and contacts the heat generating element.

An input device is characterized in that in a first stroke region in which an operation panel is pushed during a touch operation, a first reaction force that occurs by pushing the operation panel is generated by the first elastic portion. In a second stroke region including a stroke longer than in the first stroke region and a stroke for performing a push operation, a second reaction force that occurs by pushing the operation panel is a resultant force generated by a first elastic portion and the push switch. In the vicinity of a boundary between the first stroke region and the second stroke region, the amount of change in the first reaction force with respect to a stroke length is less than the amount of change in the second reaction force with respect to a stroke length.

A light switch adapter with slight modification to an existing wall light switch turns the existing wall light switch into a smart device by replacing the existing screws with elongated screws. To further secure the adaptation, each of the elongated screw may contain an adapter screw head or fastener or knobbed protrusion that firmly couples the light switch adapter through an opening of the rear side of the light switch adapter. In another embodiment, the opening contains or shaped as a circlip or a C-clip that allows the adapter screw head snap into the opening securely.

An electronic device according to an embodiment of the present disclosure may include: a housing including a first plate and a second plate, wherein the first plate includes an opening; a display panel at least partially exposed through the opening and including a touch sensor; a first support member coupled to the display panel and a portion of the first plate along at least part of one side of the opening; and a switch device configured to be actuated according to a depression of the display panel, the depression caused by a downward force exerted on an upper portion of the display panel. Other various embodiments are also possible.

A remote control device may control electrical loads and/or load control devices of a load control system without accessing electrical wiring. The remote control device may be configured to be mounted over an installed mechanical switch having a paddle actuator and may include a base and a control unit that is configured to be removably attached to the base. The base may include a frame, a clamp arm, a screw, and/or a sleeve. The clamp arm may be configured to secure the base to a protruding portion of the paddle actuator. The clamp arm may be attached to the frame at a pivot joint. The clamp arm may be configured to pivot about the pivot joint. The pivot joint may be located proximate to an endpoint or a midpoint of the frame.

A remote control device may control electrical loads and/or load control devices of a load control system without accessing electrical wiring. The remote control device may include a control unit and a base for the control unit. The base may include a frame and a mounting tab that attaches to the paddle actuator of a mechanical switch. The mounting tab may be monolithic with the frame. Alternatively, the base may include a resilient attachment member that extends from the frame and is captively retained by the mounting tab. The frame and the attachment member may be configured such that the attachment member is held in a fixed in position by the frame, or such that the attachment member is translatable relative to the frame. The base may include one or more alignment members. The base may cause a rear surface of the frame to be biased against the mechanical switch.

A touch sensing device is disclosed. The touch sensing device includes one or more multifunctional nodes each of which represents a single touch pixel. Each multifunctional node includes a touch sensor with one or more integrated I/O mechanisms. The touch sensor and integrated PO mechanisms share the same communication lines and I/O pins of a controller during operation of the touch sensing device.