A lighting device includes a pedestal, a supporting column, a flexible touch panel, and a light source assembly. One end of the supporting column is connected to the pedestal, and the other end of the supporting column is connected to the light source assembly. The flexible touch panel is attached on an outside surface of the supporting column, the flexible touch panel is electrically connected with the light source assembly, and the flexible touch panel is operable to sense a touch action to control a luminous state of the light source assembly. The brightness, color temperature and the like of the luminous state of the light source assembly may be controlled by touching the flexible touch panel. The flexible touch panel is set on the supporting column for a user to touch and operate, which improves the user's operating experience.

The various implementations described herein include methods and systems for providing a force dimension to interface elements. In one aspect, a method includes (i) communicatively coupling a wearable device that includes electromyography (EMG) sensors with an activatable device that includes a mechanical user interface element; (ii) in accordance with an activation of the user interface element, obtaining data from the EMG sensors that corresponds to the activation; (iii) determining, based on the data from the EMG sensors, whether the activation includes an activation force that meets predefined criteria; (iv) in accordance with a determination that the activation force meets the predefined criteria, causing execution of a first function corresponding to the user interface element; and (v) in accordance with a determination that the activation force meets the predefined criteria, causing execution of a second function corresponding to the user interface element.

Described are virtual AR interfaces for generating a virtual rotational interface for the purpose of controlling connected IoT devices using the inertial measurement unit (IMU) of a portable electronic device. The IMU control application enables a user of a portable electronic device to activate a virtual rotational interface overlay on a display and adjust a feature of a connected IoT product by rotating a portable electronic device. The device IMU moves a slider on the virtual rotational interface. The IMU control application sends a control signal to the IoT product which executes an action in accordance with the slider position. The virtual rotational interface is presented on the display as a virtual object in an AR environment. The IMU control application detects the device orientation (in the physical environment) and in response presents a corresponding slider element on the virtual rotational interface (in the AR environment).

A remote control device may be configured to be mounted over the toggle actuator of a light switch and to control a load control device via wireless communication. The remote control device may include a base portion and a rotating portion supported by the base portion so as to be rotatable about the base portion. The remote control device may include a control circuit and a wireless communication circuit. The control circuit may be operably coupled to the rotating portion and to the wireless communication circuit. The control circuit may be configured to translate a force applied to the rotating portion of the remote control device into a control signal and to cause the communication circuit to transmit the control signal to the load control device.

In various embodiments, a smart home device is presented. The smart home device may include at least one sensor. The smart home device may include a speaker, a light, and a motion detection sensor that detects motion in an ambient environment of the smart home device. A processing system of the smart home device may be configured to select an illumination state based on a determined status. The processing system may cause the light to illuminate based on the selected illumination state. The processing system may determine a gesture has been performed in the ambient environment of the smart home device following the light being illuminated based on the selected illumination state. The processing system may output a detail of the status via the speaker corresponding to the illumination state in response to determining the gesture has been performed.

Hazardous or dangerous conditions may be monitored. A mode may be set to a state indicative of the condition being present. It may then be determined that the hazardous or dangerous condition has eased. An indication of the hazardous or dangerous condition easing may be output in response to the determination. Such an indication may be output as synthesized speech.

A controllable light source is provided that includes a load control circuit and an integrated lighting load. The controllable light source is configured to receive wirelessly communicated commands transmitted by a remote control device associated with the controllable light source, such as a rotary remote control device. The controllable light source may include an actuator for associating the controllable light source with the remote control device, such that the load control circuit is operable to adjust the intensity of the lighting load in response to wireless signals received from the remote control device. The controllable light source may support the actuator such that the actuator may be actuated when the controllable light source is installed in a fixture.

Enhancements to ornamental or holiday lighting are disclosed including remote control ornamental illumination with color pallet control whereby a user can vary the color/intensity/appearance of an individual bulb or entire light string by selecting the electronic address of the bulb and selecting its attribute. Further disclosures include: motion responsive lights which respond to sensed movement, gesture controlled lights, adjustable white color/white led sets, connectable multi-function lights, controller to sequence lights to music or other input source, rotating projection led light/tree top/table top unit, and remote controlled sequencing icicle lights and ornament lighting system.

Various arrangements are presented for controlling a night light feature of a hazard detector. A user interface application executed on a mobile device may output, a graphical interface that provides an option to enable a night light feature of the hazard detector. The application may transmit data indicative of the night light feature being enabled and of an associated user account to a computer server system. The computer server system may receive and store data indicative of the night light feature being enabled and of the user account. The hazard detector may receive from the computer server system data indicative of the night light feature of the hazard detector being enabled by the application. The hazard detector may enable the plurality of LEDs to provide illumination in response to the received data indicative of the night light feature of the hazard detector being enabled by the application.

Various systems and methods related to smart-home networking are presented. A low-power smart home device may be exclusively battery powered. The low-power smart home device may transmit data via a low-power communication protocol to a spokesman smart home device. The spokesman smart home device may receive the data transmitted via the low-power communication protocol. The spokesman smart home device may be a doorbell, a thermostat, a hazard detector, or a wall switch. The spokesman smart home device may connected to household wiring that provides power. The spokesman smart home device may translate the data from the low-power communication protocol to a relatively high-power communication protocol. The spokesman smart home device may transmit the data, via the relatively high-power communication protocol, to a cloud-based server system.