Abstract: Methods for a soft universal remote (SUR) controller are performed by systems and apparatuses. Audio/visual (A/V) devices may be controlled by hardware remote controllers that are not configured to control other devices of an audio/visual system. A SUR controller implemented by an A/V device provides consumable control signals to such other devices based on control signals from the A/V device remote controller. A SUR controller determines another device for which a received control function is directed, and transmits a generated consumable control signal for the control function of the received control signal is provided to the other device. User interfaces are provided by SUR controllers for the configuration of SUR controllers and remote controllers, and for control of other A/V devices via the user interfaces.

Abstract: Embodiments disclosed herein enable detection and improvement of the quality of the audio signal using a mobile device by determining the loss in the audio signal and enhancing audio by streaming the remainder portion of audio. Embodiments disclosed herein enable an improvement in the sound quality rendered by rendering devices by emitting an test audio signal from the source device, measuring the test audio signal using microphones, detecting variation in the frequency response, loudness and timing characteristics using impulse responses and correcting for them. Embodiments disclosed herein also compensate for the noise in the acoustic space by determining the reverberation and ambient noise levels and their frequency characteristics and changing the digital filters and volumes of the source signal to compensate for the varying noise levels.

Abstract: Methods, systems, and apparatuses are described for performing a calibration process for synchronizing audio signals with video signals. The calibration process may be performed between one or more devices of an entertainment system and a handheld device. Device(s) (e.g., a television and speaker(s)) of the entertainment system are configured to playback video signal(s) and audio signal(s), respectively. The handheld device is configured to determine an amount of synchronization error between the audio signal and the video signal, determine a synchronization correction value based on the determined amount, and provide the synchronization correction value to device(s) of the entertainment system. The device(s) may use the synchronization correction value to correct the delay between the video signal and the audio signal such that the video signal and the audio signal are synchronized.

Abstract: Methods, systems, and apparatuses are described for automatic identification and mapping of consumer electronic devices to ports on an HDMI switch. A device that is connected to an HDMI switch is identified based on data received over an HDMI connection, and ports on the HDMI switch are automatically mapped and configured. Methods, systems, and apparatuses are described for back-end database creation for automatic identification and mapping of consumer electronic devices to ports on an HDMI switch. The back-end database may be created by the based on video and audio signatures received from a consumer electronic device and based on remote control information and signatures.

Abstract: HDMI systems, devices, circuits, and apparatuses perform functions to allow extending the number of HDMI inputs for an HDMI device using cascaded HDMI extenders. HDMI extenders are mechanically coupled and decoupled to an HDMI device such as an HDMI switch or sink device. HDMI extenders include HDMI input ports to receive HDMI signals and include connectors to receive and transmit HDMI signals as well as non-HDMI signals for configuration and control of the HDMI extenders. One or more mechanically coupled HDMI extenders are configured by the HDMI device based on information received from HDMI source devices connected to the HDMI extenders and to the HDMI device. The HDMI extenders select between HDMI signals received from their input ports or HDMI signals received from their connectors, and provide the selected HDMI signals to the HDMI device. HDMI extenders are configured to be cascaded in any number to increase HDMI source availability.

Abstract: Disclosure is directed to managing more than one placeshifting transmission at a target device. The target device may be configured to receive a first video from a first placeshifting source and a second video from a second placeshifting source. The target device may additionally be configured to simultaneously output the first and second video on an output device, using various display screen configurations such as picture-in-picture, split screen, windows, and so. The first and second placeshifting sources may be content receivers having integrated placeshifting functions or may be content receivers provided in association with stand-alone placeshifting devices. A dual-tuner content receiver may also provide both the first and second placeshifting sources to the target device.

Abstract: Methods, systems and apparatuses are described for intelligent device integration. A device (e.g., an HDMI “smart” switch) with multiple communication interfaces (e.g., HDMI, LAN, BT, IR) may monitor communications for control signals from multiple controllers configured to control respective devices (e.g., HDMI source, sink and/or switch devices). A device LAN may couple HDMI source and sink devices and non-HDMI devices. LAN communications may be monitored for device and control information. Control signals from controllers may be used to control devices that the controllers and their control signals are not configured to control. Interpreted control decisions may be based on, for example, an interpreted control in the context of a detected configuration and/or state of devices. A device may, thereby, expand the utility of incompatible controllers (without reprogramming), integrate an environment of incompatible devices and controllers, and provide relief to end-users.

Abstract: Methods, systems, and apparatuses are described for automatic identification and mapping of consumer electronic devices to ports on an HDMI switch. A device that is connected to an HDMI switch is identified based on data received over an HDMI connection, and ports on the HDMI switch are automatically mapped and configured. Methods, systems, and apparatuses are described for back-end database creation for automatic identification and mapping of consumer electronic devices to ports on an HDMI switch. The back-end database may be created by the based on video and audio signatures received from a consumer electronic device and based on remote control information and signatures.

Abstract: Embodiments disclosed herein enable detection and improvement of the quality of the audio signal using a mobile device by determining the loss in the audio signal and enhancing audio by streaming the remainder portion of audio. Embodiments disclosed herein enable an improvement in the sound quality rendered by rendering devices by emitting an test audio signal from the source device, measuring the test audio signal using microphones, detecting variation in the frequency response, loudness and timing characteristics using impulse responses and correcting for them. Embodiments disclosed herein also compensate for the noise in the acoustic space by determining the reverberation and ambient noise levels and their frequency characteristics and changing the digital filters and volumes of the source signal to compensate for the varying noise levels.

Abstract: Embodiments disclosed herein enable detection and improvement of the quality of the audio signal using a mobile device by determining the loss in the audio signal and enhancing audio by streaming the remainder portion of audio. Embodiments disclosed herein enable an improvement in the sound quality rendered by rendering devices by emitting an test audio signal from the source device, measuring the test audio signal using microphones, detecting variation in the frequency response, loudness and timing characteristics using impulse responses and correcting for them. Embodiments disclosed herein also compensate for the noise in the acoustic space by determining the reverberation and ambient noise levels and their frequency characteristics and changing the digital filters and volumes of the source signal to compensate for the varying noise levels.

Abstract: Methods, systems, and apparatuses are described for automatic identification and mapping of consumer electronic devices to ports on an HDMI switch. A device that is connected to an HDMI switch is identified based on data received over an HDMI connection, and ports on the HDMI switch are automatically mapped and configured. Methods, systems, and apparatuses are described for back-end database creation for automatic identification and mapping of consumer electronic devices to ports on an HDMI switch. The back-end database may be created by the based on video and audio signatures received from a consumer electronic device and based on remote control information and signatures.

Abstract: Embodiment disclosed herein enable detection and improvement of the quality of the audio signal using a mobile device by determining the loss in the audio signal and enhancing audio by streaming the remainder portion of audio. Embodiments disclosed herein enable an improvement in the sound quality rendered by rendering devices by emitting an test audio signal from the source device, measuring the test audio signal using microphones, detecting variation in the frequency response, loudness and timing characteristics using impulse responses and correcting for them. Embodiments disclosed herein also compensate for the noise in the acoustic space by determining the reverberation and ambient noise levels and their frequency characteristics and changing the digital filters and volumes of the source signal to compensate for the varying noise levels.

Abstract: Embodiments disclosed herein enable detection and improvement of the quality of the audio signal using a mobile device by determining the loss in the audio signal and enhancing audio by streaming the remainder portion of audio. Embodiments disclosed herein enable an improvement in the sound quality rendered by rendering devices by emitting an test audio signal from the source device, measuring the test audio signal using microphones, detecting variation in the frequency response, loudness and timing characteristics using impulse responses and correcting for them. Embodiments disclosed herein also compensate for the noise in the acoustic space by determining the reverberation and ambient noise levels and their frequency characteristics and changing the digital filters and volumes of the source signal to compensate for the varying noise levels.

Abstract: Embodiments disclosed herein enable detection and improvement of the quality of the audio signal using a mobile device by determining the loss in the audio signal and enhancing audio by streaming the remainder portion of audio. Embodiments disclosed herein enable an improvement in the sound quality rendered by rendering devices by emitting an test audio signal from the source device, measuring the test audio signal using microphones, detecting variation in the frequency response, loudness and timing characteristics using impulse responses and correcting for them. Embodiments disclosed herein also compensate for the noise in the acoustic space by determining the reverberation and ambient noise levels and their frequency characteristics and changing the digital filters and volumes of the source signal to compensate for the varying noise levels.

Abstract: Embodiments disclosed herein enable detection and improvement of the quality of the audio signal using a mobile device by determining the loss in the audio signal and enhancing audio by streaming the remainder portion of audio. Embodiments disclosed herein enable an improvement in the sound quality rendered by rendering devices by emitting an test audio signal from the source device, measuring the test audio signal using microphones, detecting variation in the frequency response, loudness and timing characteristics using impulse responses and correcting for them. Embodiments disclosed herein also compensate for the noise in the acoustic space by determining the reverberation and ambient noise levels and their frequency characteristics and changing the digital filters and volumes of the source signal to compensate for the varying noise levels.

Abstract: Methods, systems, and apparatuses are described for performing a calibration process for synchronizing audio signals with video signals. The calibration process may be performed between one or more devices of an entertainment system and a handheld device. Device(s) (e.g., a television and speaker(s)) of the entertainment system are configured to playback video signal(s) and audio signal(s), respectively. The handheld device is configured to determine an amount of synchronization error between the audio signal and the video signal, determine a synchronization correction value based on the determined amount, and provide the synchronization correction value to device(s) of the entertainment system. The device(s) may use the synchronization correction value to correct the delay between the video signal and the audio signal such that the video signal and the audio signal are synchronized.

Abstract: Methods, systems, and apparatuses are described for automatic identification and mapping of consumer electronic devices to ports on an HDMI switch. A device that is connected to an HDMI switch is identified based on data received over an HDMI connection, and ports on the HDMI switch are automatically mapped and configured. Methods, systems, and apparatuses are described for back-end database creation for automatic identification and mapping of consumer electronic devices to ports on an HDMI switch. The back-end database may be created by the based on video and audio signatures received from a consumer electronic device and based on remote control information and signatures.

Abstract: Embodiments described herein automatically detect a power state of an electronic device and perform a control scheme based thereon. For example, a control device determines that an electronic device is to be in a desired power state. A socket device coupled to the electronic device determines an amount of current or power being provided to the electronic device and transmits an indication of the amount of current or power or a determined power state to the control device. Based on the indication, the control device determines the current power state of the electronic device. If the control device determines that the current power state is not the desired power state, the control device transmits a signal to the electronic device, which causes it to transition to the desired power state.

Abstract: Methods, systems, and apparatuses are described for configuring television speakers. A television may be configured to operate as a center channel speaker for an audio system. Television speakers may be calibrated according to other speakers utilized by the audio system. The handling of HDMI commands by the television may modified such that the television speakers and the audio system speakers concurrently produce sound.

Abstract: Methods, systems, circuits, devices, and apparatuses are described for auto-detection and adaptive configuration of high-definition multimedia interface (HDMI) ports. Unique systems and circuits allow HDMI repeaters to automatically detect if an HDMI device that has been connected thereto, via an HDMI port, is an HDMI source (source mode) or an HDMI sink (sink mode). The unique systems and circuits may be adaptively configured to allow the HDMI port to function as an HDMI input or an HDMI output based on the automatic detection. Methods corresponding to the functions performed by the systems and apparatuses are provided, and computer readable storage media with computer program instructions encoded thereon for enabling processing devices to perform the methods are also provided.