A set top box receives from a remote control device one or more of a codeset identifier, data indicative of a brand and model for a consumer electronic device, and remote control diagnostic information. The set top box then causes information representative of the received codeset identifier, data indicative of a brand and model for a consumer electronic device, and remote control diagnostic information to be displayed in a display device associated with the set top box.

A set top box receives from a remote control device one or more of a codeset identifier, data indicative of a brand and model for a consumer electronic device, and remote control diagnostic information. The set top box then causes information representative of the received codeset identifier, data indicative of a brand and model for a consumer electronic device, and remote control diagnostic information to be displayed in a display device associated with the set top box.

The present invention relates to a control device for controlling an operation of an aerosol nebulizer system (30), said aerosol nebulizer system (30) comprising an aerosol generator (31) for nebulizing a liquid and a plurality of sensor units (38a, 38b, 38c, 38d, 38e), said control device (20) comprising: a communication unit (21), configured to establish a wireless communication connection and to perform data transmission with the aerosol nebulizer system (30), a sensor data control unit (22), configured to trigger a selection of sensor data related to the sensor units (38a, 38b, 38c, 38d, 38e) to be wirelessly transmitted to the control device (20).

The present invention relates to a control device for controlling an operation of an aerosol nebulizer system (30), said aerosol nebulizer system (30) comprising an aerosol generator (31) for nebulizing a liquid and a plurality of sensor units (38a, 38b, 38c, 38d, 38e), said control device (20) comprising: a communication unit (21), configured to establish a wireless communication connection and to perform data transmission with the aerosol nebulizer system (30), a sensor data control unit (22), configured to trigger a selection of sensor data related to the sensor units (38a, 38b, 38c, 38d, 38e) to be wirelessly transmitted to the control device (20).

An infrared output device is installed in a fixed apparatus whose position is fixed in a predetermined space. An input receiving device is configured to receive, through voice input, a control command to a first-type apparatus controllable by infrared ray. Upon the input receiving device receiving the control command, the infrared output device is configured to output infrared ray to the first-type apparatus.

An example electronic device includes a first communication unit, a second communication unit, and a processor for performing control such that the second communication unit operates in a scan state in which an undirected advertising packet can be received when a preset IR signal is received from a remote control device through the first communication unit, acquiring identification information of a target device from the undirected advertising packet when the undirected advertising packet is received from the remote control device in the scan state, and providing a user interface (UI) for guiding a Bluetooth connection with remote control device when the acquired identification information of a target device matches identification information of the electronic device.

An electric powertrain includes a sensor-controller interface, an inverter-controller electrically connected to the battery pack, and an electric machine connected to the inverter-controller and having a rotor with an angular position. The rotor powers a driven load at a torque and/or speed level controlled by the inverter-controller in response to position signals indicative of the angular position. A rotary position sensor is operatively connected to the rotor to generate and output the position signals. The sensor derives the position signals from unmodulated sine and cosine signals, and communicates the position signals and a binary sensor state of health (SOH) to the inverter-controller over the interface. The inverter-controller also decodes the position signals and the binary sensor SOH to generate decoded control data, and controls the torque and/or speed level using the decoded control data.

An electric powertrain includes a sensor-controller interface, an inverter-controller electrically connected to the battery pack, and an electric machine connected to the inverter-controller and having a rotor with an angular position. The rotor powers a driven load at a torque and/or speed level controlled by the inverter-controller in response to position signals indicative of the angular position. A rotary position sensor is operatively connected to the rotor to generate and output the position signals. The sensor derives the position signals from unmodulated sine and cosine signals, and communicates the position signals and a binary sensor state of health (SOH) to the inverter-controller over the interface. The inverter-controller also decodes the position signals and the binary sensor SOH to generate decoded control data, and controls the torque and/or speed level using the decoded control data.

An Audio/Video (A/V) receiving device includes a Radio Frequency (RF) receiving module configured to receive A/V data from an A/V transmitting device through a first frequency band, an infrared (IR) module configured to receive a power control signal from a remote control device, a wireless receiving module configured to communicate with a wireless transmitting module of the A/V transmitting device through a second frequency band, and a microcomputer configured to turn on power of the A/V receiving device according to the power control signal received from the remote control device and to transmit the power control signal to the wireless transmitting module through the wireless receiving module.

An Audio/Video (A/V) receiving device includes a Radio Frequency (RF) receiving module configured to receive A/V data from an A/V transmitting device through a first frequency band, an infrared (IR) module configured to receive a power control signal from a remote control device, a wireless receiving module configured to communicate with a wireless transmitting module of the A/V transmitting device through a second frequency band, and a microcomputer configured to turn on power of the A/V receiving device according to the power control signal received from the remote control device and to transmit the power control signal to the wireless transmitting module through the wireless receiving module.