An audio system for a headset includes a plurality of speakers and an audio controller. The plurality of speakers may be in a dipole configuration that cancel sound leakage into a local area of the headset. The controller filters audio content presented by the plurality of speakers to further mitigate leakage of audio content into the local area. The audio determines sound filters based on environmental conditions, such as ambient noise levels, as well as based on the audio content being presented.

A wireless earphone system (1) comprising a first earphone (2) and a second earphone (3). The first earphone (2) comprises a first earphone transceiver (6) of a first type and a second earphone transceiver (7) of a second type, and the second earphone (3) comprises a third earphone transceiver (7) of the first type. A first wireless link (5) can be established between the first earphone transceiver (6) and the third earphone transceiver (8), and a second wireless link (9) can be established between the second earphone transceiver (7) and an audio rendering transceiver (25) of the second type of an audio rendering device (4). The first earphone device (2) is adapted to send a link status signal (12) via the second wireless link (9) to the audio rendering device (4).

A hearing assistance system comprises an input unit for providing electric input sound signals u.sub.i, each representing sound signals U.sub.i from a multitude n.sub.u of sound sources S.sub.i, an electroencephalography (EEG) system for recording activity of the auditory system of the user's brain and providing a multitude n.sub.y of EEG signals y.sub.j, and a source selection processing unit receiving said electric input sound signals u.sub.i and said EEG signals y.sub.j, and in dependence thereof configured to provide a source selection signal Ŝ.sub.x indicative of the sound source S.sub.x that the user currently pays attention to using a selective algorithm that determines a sparse model to select the most relevant EEG electrodes and time intervals based on minimizing a cost function measuring the correlation between the individual sound sources and the EEG signals, and to determine the source selection signal Ŝ.sub.x based on the cost functions obtained for said multitude of sound sources.

A system includes a safety helmet and an earpiece, wherein the earpiece is configured to determine when a user of the earpiece is wearing the safety helmet. The earpiece may include a touch surface and at least one sensor associated with the touch surface and wherein the earpiece is configured to ignore input at the touch surface when the user of the earpiece is wearing the safety helmet. A method includes sensing by an earpiece that a user is wearing a helmet and deactivating sensors associated with a touch input area on the ear piece when the user is wearing the helmet. A method includes charging an earpiece using a battery of a helmet while a user is wearing the earpiece and the helmet. A method includes communicating data from one or more sensors of a helmet or one or more sensors of a motorcycle to an earpiece and providing audio output indicating of the data to a user through a speaker of the earpiece.

Disclosed by the present application are an earphone and a worn detection device thereof. The detection device comprises a sensing panel used for forming a battery encapsulated metal shell, a detection chip connected to an input end and the sensing panel and a control chip connected to an output end of the detection chip; a battery is arranged in an earphone handle of the earphone; the detection chip is used for detecting a sensing signal of the sensing panel and determining a wearing state of the earphone according to the sensing signal; and the control chip is used to adjust the working state of the earphone according to the wearing state. When a user wears the earphone, the earphone handle of the earphone contacts the skin of the user, a capacitance effect is formed between the sensing panel and the skin of the user, and a sensing signal is generated. The detection chip determines the wearing state of the earphone by means of the sensing signal, and the control chip adjusts the working state of the earphone according to the wearing state. The present application reuses the encapsulated metal shell as the sensing panel, which is conducive to the miniaturization of the earphone and the improvement of the sensitivity and reliability of detecting the wearing state.

An earpiece includes an earpiece housing, a processor disposed within the ear piece housing, at least one inertial sensor disposed within the earpiece housing, the at least one inertial sensor operatively connected to the processor, and a wireless transceiver disposed within the earpiece housing and operatively connected to the processor. The earpiece is configured to exchange inertial data with a vehicle having one or more inertial sensors. The vehicle may be a motorcycle, moped, scooter, bicycle, electric bicycle, personal transporter, hover board, or other type of vehicle.

An audio device includes a channel detection electrode and a jack detector configured to determine whether the channel detection electrode is in contact with a jack according to voltage variation of a detection node. The jack detector includes a first resistor coupled between the detection node and a first node to which a first voltage is supplied, a second resistor coupled between the detection node and the channel detection electrode, a third resistor coupled between the detection node and a second node, and a comparator configured to compare a voltage at the detection node with a reference voltage.

A method of utilizing wireless earpieces for hub communications in embodiments of the present invention may have one or more of the following steps: (a) activating the wireless earpieces, (b) connecting one or more devices to the wireless earpieces, (c) performing first biometric measurements of the user utilizing the wireless earpieces, (d) receiving second biometric measurements from the one or more devices, (e) determining if the one or more devices is located on the same user as the wireless earpieces by comparing the second biometric measurements to the first biometric measurements, (f) receiving a communication to be sent through the wireless earpieces from the one or more devices, and (g) sending the communication to reach a receiving party in response to the determination the second biometric measurements are similar to the first biometric measurements.

A system and method for implementing interactive media content is provided. Interactive media content is received for communication to a user through at least wireless earpieces. User biometrics are measured utilizing the wireless earpieces. A user condition associated with the user biometrics is determined. Branching patterns of the interactive media content are modified in response to the user condition. The interactive content may be a game or story.

A system includes a plurality of earpiece sets, each of the earpiece sets comprising a left earpiece and a right earpiece and a smart case. The smart case includes a case housing, a plurality of receptacle sets disposed within the case housing, wherein the receptacle sets are configured to hold the plurality of earpiece sets, a processor disposed within the case housing, and a transceiver disposed within the housing and operatively connected to the processor.