Disclosed herein are system, apparatus, article of manufacture, method and/or computer program product embodiments, and/or combinations and sub-combinations thereof, for identifying electronic devices in a room using a spread code. In some embodiments, a first electronic device receives a spread spectrum signal from a second electronic device over an audio data channel. The first electronic device determines a time of receipt of the spread spectrum signal based on despreading. The first electronic device calculates a distance between the first electronic device and the second electronic device based on the time of receipt and a time of transmission. The first electronic device determines the second electronic device is not in the room with the first electronic device based on the calculated distance.

A system configured to improve user localization used to determine a listening position and/or user orientation for a device map. Multiple devices may generate audio data representing user speech and the system may use the audio data to determine a first spatial likelihood function (SLF) based on angle measurements, determine a second SLF based on timing information, and determine a location of the user based on a combination of the two SLFs. The SLFs represent the environment using a grid comprising a plurality of grid cells, and each grid cell has a value indicating a likelihood that the grid cell corresponds to the location of the user. An individual device may generate a portion of the angle measurements based on multi-channel audio data generated using multiple microphones of the device, while the system may generate the timing information based on single-channel audio data received from each of the multiple devices.

A system and method for multichannel audio interception and redirection for ANDROID-based devices, comprising an audio redirector software module that detects available hardware capabilities, configures and reports audio channel capabilities based on the detected hardware capabilities, de-multiplexes received audio, and provides de-multiplexed audio channels to both a sound processing framework and external audio rendering hardware.

Aspects of a multi-orientation playback device including at least one microphone array are discussed. A method may include determining an orientation of the playback device which includes at least one microphone array and determining at least one microphone training response for the playback device from a plurality of microphone training responses based on the orientation of the playback device. The at least one microphone array can detect a sound input, and the location information of a source of the sound input can be determined based on the at least one microphone training response and the detected sound input. Based on the location information of the source, the directional focus of the at least one microphone array can be adjusted, and the sound input can be captured based on the adjusted directional focus.

An automated process for equalizing an audio system and an apparatus for implementing the process. An audio system includes a microphone unit, for receiving the sound waves radiated from a plurality of speakers, acoustic measuring circuitry, for calculating frequency response measurements; a memory, for storing characteristic data of the loudspeaker units and further for storing the frequency response measurements; and equalization calculation circuitry, for calculating an equalization pattern responsive to the digital data and responsive to the characteristic data of the plurality of loudspeaker units. Also described is an automated equalizing system including a acoustic measuring circuitry including a microphone for measuring frequency response at a plurality of locations; a memory, for storing the frequency responses at the plurality of locations; and equalization calculation circuitry, for calculating, from the frequency responses, an optimized equalization pattern.

A speaker assembly broadly comprising a housing, an input circuit, and a number of speakers. The housing includes a lower section configured to be positioned at least partially below a ground surface and an upper section extending upwards from the lower section. The input circuit receives audio signals from a sound system or other controller and actively or passively sends the audio signals to the speakers. The speakers include a low-range speaker positioned in the lower section of the housing and a relatively higher-range speaker positioned in the upper section. The speaker assembly is configured to be spaced from other speaker assemblies within a listening area with each speaker assembly generating low frequency soundwaves and relatively higher-frequency soundwaves. This reduces or eliminates out-of-phase crossover frequency wave cancellation effects within the listening area.

An electronic device is disclosed. The electronic device may include a first speaker configured to output a first audio signal, a second speaker configured to output a second audio signal, a communicator configured to communicate with a peripheral device, and a processor configured to receive information related to a time at which the first audio signal is received and a time at which the second audio signal is received from the peripheral device which receives the first audio signal and the second audio signal and to determine a distance to and a direction of the peripheral device with reference to the electronic device based on the received information.

A networked speaker system communicates using Li-Fi. The LEDs implementing the Li-Fi may also have modes in which they are used to map the walls of a room in which the speakers are located, detect the locations of speakers in the room, and detect and classify listeners in the room. Based on this, waveform analysis may be applied to input audio to establish equalization and delays that are optimal for the room geometry, speaker locations, and listener locations.

Apparatus and associated methods relate to a wireless receiver module, and a plurality of transmitter modules, the receiver module configured to convert a wireless protocol signal to an audio baseband signal, each transmitter module operable to receive the audio baseband signal, and adapted to convert the audio baseband signal to a unique wireless protocol signal for transmission over an independent communication channel to a respective wireless audio output device. In an illustrative example, a wireless repeater hub (WRH) may pair a master transceiver (within the WRH) with a master audio source. The master transceiver may demodulate the audio information, and send it to a plurality of slave transceivers. Each slave transceiver within the WRH is paired to a respective individual audio transducer. Various embodiments may facilitate a wireless music data-stream from a personal electronic device (PED) to be played on multiple wireless audio transducers via unique and distinct wireless channels.

Provided is a control method of a user terminal apparatus and device, for speaker location detection and level control using a magnetic field. The method includes receiving reference magnetic field information generated by at least one speaker, in response to a magnetic field being generated based on the reference magnetic field information by the at least one speaker, detecting the magnetic field generated by the at least one speaker, acquiring location information of the at least one speaker using the detected magnetic field information and the reference magnetic field information, and transmitting the location information of each of the at least one speaker to a source apparatus.