Abstract: In some implementations, a mobile computing device may participate in the calibration of an output signal of a media device. This calibration process includes storing device-specific calibration data which is related to properties of a light sensor of the mobile device. The mobile device then detects of properties of light emitted by the display device during a presentation to obtain sensor values related to light emitted by the display device during the presentation. The calibration process may also ensure that the mobile device is proximate to the display device prior to obtaining the sensor values. The collected sensor values are adjusted using device-specific calibration data stored to the mobile device to normalize the sensor values relative to a baseline. These normalized sensor values are sent to the media device for use in adjusting the output signal based on the normalized sensor values.

Abstract: For example, a wireless communication device may be configured to transmit a reservation frame to reserve a wireless communication medium for a Transmit Opportunity (TxOP). For example, the TxOP may be configured to cover a first reserved duration and a second reserved duration. For example, the first reserved duration may be configured for at least one self-transmission of the STA, and the second reserved duration may be configured for communication of at least one non-self-transmission by the STA. For example, the wireless communication device may be configured to transmit the at least one self-transmission during the first duration. For example, the self-transmission may be configured for transmission from a transmitter of the STA to a receiver of the STA.

Abstract: Described herein is an apparatus having at least two antennas to communicate over multiple communication channels. The apparatus can further include processing circuitry coupled to the at least two antennas to measure isolation in the communication channels while the communication channels are operating in a radar mode to select a channel having highest isolation among the communication channels. The processing circuitry can further perform radar detection over the channel having highest isolation. Other systems and methods are described.

Abstract: In some implementations, a mobile computing device may participate in the calibration of an output signal of a media device. This calibration process includes storing device-specific calibration data which is related to properties of a light sensor of the mobile device. The mobile device then detects of properties of light emitted by the display device during a presentation to obtain sensor values related to light emitted by the display device during the presentation. The calibration process may also ensure that the mobile device is proximate to the display device prior to obtaining the sensor values. The collected sensor values are adjusted using device-specific calibration data stored to the mobile device to normalize the sensor values relative to a baseline. These normalized sensor values are sent to the media device for use in adjusting the output signal based on the normalized sensor values.

Abstract: In some implementations, a mobile computing device may participate in the calibration of an output signal of a media device. This calibration process includes storing device-specific calibration data which is related to properties of a light sensor of the mobile device. The mobile device then detects of properties of light emitted by the display device during a presentation to obtain sensor values related to light emitted by the display device during the presentation. The calibration process may also ensure that the mobile device is proximate to the display device prior to obtaining the sensor values. The collected sensor values are adjusted using device-specific calibration data stored to the mobile device to normalize the sensor values relative to a baseline. These normalized sensor values are sent to the media device for use in adjusting the output signal based on the normalized sensor values.

Abstract: In some implementations, a mobile computing device may participate in the calibration of an output signal of a media device. This calibration process includes storing device-specific calibration data which is related to properties of a light sensor of the mobile device. The mobile device then detects of properties of light emitted by the display device during a presentation to obtain sensor values related to light emitted by the display device during the presentation. The calibration process may also ensure that the mobile device is proximate to the display device prior to obtaining the sensor values. The collected sensor values are adjusted using device-specific calibration data stored to the mobile device to normalize the sensor values relative to a baseline. These normalized sensor values are sent to the media device for use in adjusting the output signal based on the normalized sensor values.

Abstract: In some implementations, a mobile computing device may participate in the calibration of an output signal of a media device. This calibration process includes storing device-specific calibration data which is related to properties of a light sensor of the mobile device. The mobile device then detects of properties of light emitted by the display device during a presentation to obtain sensor values related to light emitted by the display device during the presentation. The calibration process may also ensure that the mobile device is proximate to the display device prior to obtaining the sensor values. The collected sensor values are adjusted using device-specific calibration data stored to the mobile device to normalize the sensor values relative to a baseline. These normalized sensor values are sent to the media device for use in adjusting the output signal based on the normalized sensor values.

Abstract: A method and system for the dynamic extension (e.g. subclassing) of objects to enable visual styling of on-screen elements is disclosed herein. The present invention allows designers and developers alike to conceive, implement, and modify native mobile interfaces effortlessly and in real time through a familiar CSS-based syntax. The technique of dynamic subclassing for the purpose of styling greatly simplifies the development process by no longer requiring the developer to directly configure visual element's properties or to subclass objects in code.

Abstract: A method and system for the dynamic extension (e.g. subclassing) of objects to enable visual styling of on-screen elements is disclosed herein. The present invention allows designers and developers alike to conceive, implement, and modify native mobile interfaces effortlessly and in real time through a familiar CSS-based syntax. The technique of dynamic subclassing for the purpose of styling greatly simplifies the development process by no longer requiring the developer to directly configure visual element's properties or to subclass objects in code.