A load control system may include devices for performing communications for controlling an amount of power provided to an electrical load. The devices may include load control devices that may communicate by transmitting digital messages. A user device having an adjustable wireless communication range may be used for discovering devices, configuring devices, and/or diagnosing devices in the load control system. The user device may detect whether devices are within an established wireless communication range of one another for performing communications. The user device may detect digital messages transmitted from a device and/or digital messages received at a device to determine whether the digital messages are correctly communicated in the load control system. The user device may provide an indication to a user indicating whether a digital message is correctly transmitted or received by a device in the load control system.

Systems and methods for localizing portable devices are illustrated. One embodiment includes a method for locating a portable device in a network that includes several reference devices. The method measures characteristics of signals transmitted via signal paths between reference devices and a portable device, normalizes the measurements to estimate characteristics of the signal paths, and estimates the likelihood that the portable device is in a particular location. Systems and methods for training prediction models include a method that includes steps for receiving context data for a portable device in a system, wherein the context data includes localization data that describes a location of the portable device, identifying a predicted stationary device based on the context data using a prediction model, identifying a target stationary device from the several stationary devices, training the prediction model based on based on the predicted stationary device and the received input.

A flight attendant calling device of a passenger aircraft includes at least one calling device control element assigned to a seat of the passenger aircraft for calling flight attendant staff on board the passenger aircraft by a passenger assigned to the seat, a calling device processor configured to create a configuration profile of the at least one calling device control element based on passenger preferences of the passenger of the passenger aircraft assigned to the seat, and a control element configurator, which is coupled to the calling device processor, and which is configured to set up a visual and/or haptic appearance as well as a flight attendant calling functionality of the at least one calling device control element based on the configuration profile received from the calling device processor.

Techniques for suggesting accessory devices controlled by an application executing on a mobile device are disclosed. A method includes measuring one or more sensor values using one or more sensors of a mobile device and the one or more sensor values are determined from one or more signals emitted by a first one or more accessory devices. An area of a physical space for the first one or more accessory devices can be determined based on the one or more sensor values. A second one or more accessory devices associated with the same area as the first one or more accessory devices can be suggested to a user.

A system (1) for controlling a lighting system (11) is configured to receive user input representing a request to activate a query mode and transmit a command to the lighting system. The command instructs the lighting system to temporarily disable control of a lighting device (31-35) by a light control device (21-23). The system is further configured to receive control information from the lighting system. The control information describes a user interaction with the light control device and/or describes a function corresponding to the user interaction. The system is also configured to render audio and/or visual information describing the function corresponding to the user interaction to the user, e.g. on a display (9), and transmit a further command to the lighting system. The further command instructs the lighting system to enable control of the lighting device by the light control device.

Context-sensitive remote controls for use with electronic devices (e.g., eyewear device). The electronic device is configured to perform activities (e.g., email, painting, navigation, gaming). The context-sensitive remote control includes a display having a display area, a display driver coupled to the display, and a transceiver. The remote control additionally includes memory that stores controller layout configurations for display in the display area of the display by the display driver. A processor in the context-sensitive remote control is configured to establish, via the transceiver, communication with an electronic device, detect an activity currently being performed by the electronic device, select one of the controller layout configurations responsive to the detected activity, and present, via the display driver, the selected controller layout configuration in the display area of the display.

Techniques for suggesting accessory devices controlled by an application executing on a mobile device are disclosed. A method includes measuring one or more sensor values using one or more sensors of a mobile device and the one or more sensor values are determined from one or more signals emitted by a first one or more accessory devices. An area of a physical space for the first one or more accessory devices can be determined based on the one or more sensor values. A second one or more accessory devices associated with the same area as the first one or more accessory devices can be suggested to a user.

Disclosed is a display apparatus capable of receiving a remote control signal from a remote controller for a different apparatus and outputting a converted remote control signal and a control method thereof, the display apparatus including: a display configured to display an image; a communicator comprising communication circuitry; a signal receiver configured to receive a remote control signal from among a plurality of remote controllers respectively corresponding to a plurality of external apparatuses; and a controller configured to perform a function corresponding to an image displayed on the display in response to a command included in the received remote control signal, or to control the communicator to transmit the command to an external apparatus selected corresponding to the image displayed on the display from among the plurality of external apparatuses. Thus, the display apparatus receives a remote control signal from a remote controller for controlling an external apparatus, and uses the received remote control signal to directly perform a function or transmit a command to an apparatus desired to be controlled by a user, thereby allowing the user to easily use the remote controller.

Systems and methods for localizing portable devices are illustrated. One embodiment includes a method for locating a portable device in a network that includes several reference devices. The method measures characteristics of signals transmitted via signal paths between reference devices and a portable device, normalizes the measurements to estimate characteristics of the signal paths, and estimates the likelihood that the portable device is in a particular location. Systems and methods for training prediction models include a method that includes steps for receiving context data for a portable device in a system, wherein the context data includes localization data that describes a location of the portable device, identifying a predicted stationary device based on the context data using a prediction model, identifying a target stationary device from the several stationary devices, training the prediction model based on based on the predicted stationary device and the received input.

According to one configuration, a remote controller device wirelessly controls a remote media system. The remote controller device includes multiple selectable control buttons, multiple optical sources, and controller hardware. Each optical source individually back-illuminates a respective selectable control button of the multiple selectable buttons. The controller hardware selectively activates different groupings of the multiple optical sources depending upon a current operational mode of the remote media system. For example, a respective user of the remote controller device selects a particular button of the remote controller device corresponding to the first operational mode. The remote controller device, in turn, transmits a wireless signal to the remote media system to control the remote media system to the first operational mode. Rather than illuminating all buttons, the remote controller device then back-illuminates only a relevant group of multiple selectable control buttons applicable to the first operational mode.