A method of controlling the behavior of a latching relay includes receiving a configuration signal of either a first behavior signal or a second behavior signal, receiving a power status signal of either a powered or unpowered signal, receiving either a low-to-high or a high-to-low signal command signal, generating latching pulse in response to receiving a powered signal input as the power status signal and a low-to-high signal as the command signal, generating an unlatching pulse in response to receiving a powered signal input as the power status signal and a high-to-low signal as the command signal input, and generating an unlatching pulse in response to receiving the second behavior signal as the configuration signal and the unpowered signal as the power status signal.

A multifunction touch-switch system is provided. The multifunction touch-switch system is configured to control devices (for example LED lighting) by a touch switch. The multifunction touch-switch system may be configured to be waterproof and vibration resistant for use in a marine environment, for example aboard a marine vehicle. The multifunction touch-switch system may be configured to control multiple functions of multiple devices with a single touch sensor. In addition to a controller and a housing for the controller, the multifunction touch-switch system may also comprise an indicator light.

A capacitive proximity sensor assembly is provided that includes a first electrode, a second electrode, a first compliant dielectric layer disposed between the first and second electrodes, and a controller processing signals associated with the first and second electrodes and selectively reconfiguring operation of the first and second electrodes in different proximity sensor arrangements to provide a plurality of capacitive sensors. The capacitive proximity assembly may be selectively reconfigured into up to four capacitive sensors.

A door handle including a capacitance sensor configured to detect an operation body is provided. The capacitance sensor includes a substrate formed of an insulator and having a surface, at least one first sensor electrode disposed on the surface of the substrate, a plurality of second sensor electrodes disposed on the surface of the substrate, and a controller. The number of the plurality of second sensor electrodes is greater than the number of the at least one first sensor electrode. The controller applies a voltage to the plurality of second sensor electrodes and detects a coordinate position of the operation body, in a case where a capacitance between the operation body and the at least one first sensor electrode is greater than or equal to a predetermined value.

A capacitive proximity sensor assembly is provided that includes a first electrode, a second electrode, a first compliant dielectric layer disposed between the first and second electrodes, and a controller processing signals associated with the first and second electrodes and selectively reconfiguring operation of the first and second electrodes in different proximity sensor arrangements to provide a plurality of capacitive sensors. The capacitive proximity assembly may be selectively reconfigured into up to four capacitive sensors.

A method of controlling the behavior of a latching relay includes receiving a configuration signal of either a first behavior signal or a second behavior signal, receiving a power status signal of either a powered or unpowerered signal, receiving either a low-to-high or a high-to-low signal command signal, generating latching pulse in response to receiving a powered signal input as the power status signal and a low-to-high signal as the command signal, generating an unlatching pulse in response to receiving a powered signal input as the power status signal and a high-to-low signal as the command signal input, and generating an unlatching pulse in response to receiving the second behavior signal as the configuration signal and the unpowered signal as the power status signal.

An apparatus may include a touch sensor, a touch region of the touch sensor that is free of sense electrodes, a first peripheral region of the touch sensor and a second peripheral region of the touch senor and the touch region is located between the first peripheral region and the second peripheral region, a first sense electrode is located in the first peripheral region, a second sense electrode is located in the second peripheral region.

A motorized shade for covering an architectural opening that can be actuated by touching its shade material. The motorized shade comprises a shade material extending between an upper end and a lower end and a motor drive unit operably connected to the upper end of the shade material and comprising a motor and a motor control module adapted to control the motor to raise or lower the shade material. The shade material comprises at least partially comprises electrically conductive material. The motor control module comprises a capacitive touch sensor that is electrically connected to the upper end of the shade material via at least one electrical contact. The motor control module is adapted to detect a touch of the shade material via the capacitive touch sensor and in response control the motor to raise or lower the shade material.

A touch-based control device can include an exterior panel that includes a groove region and a surrounding region, one or more touch sensors for detecting touch inputs performed anywhere on a substantial portion of the exterior panel, and a sensing module comprising one or more processors to detect, via the one or more touch sensors, touch inputs performed by a user on the exterior panel. The sensing module can interpret the touch input based on at least one of (i) a region where the touch input occurred, or (ii) a type of the touch input, and control a connected device based on the interpreted touch input.

A control device having an exterior panel and a control module, where the control module includes a sensor layer, and the exterior panel overlays the sensor layer. The control module is configured to determine one or more characteristics of a touch input, and to select a scene based at least in part on the one or more determined characteristics of the touch input. The control module further controls an operational aspect of each device of the set in accordance with the selected scene.